Image displaying system and information processing apparatus

BACKGROUND OF THE INVENTION

1. Field of the Invention

In general, the present invention relates to an image displaying system for displaying an image signal by modifying a display attribute of the image signal. In particular, the present invention relates to an effective technology applied to an image displaying system for displaying an image signal, such as text data and dynamic-image data output by an information processing apparatus, on a display screen of an image displaying apparatus, whereby the contrast of the image signal is modified in accordance with the type of the data to be displayed.

2. Description of the Related Art

In recent years, the performance of computers, and in particular, the performance of personal computers (PCs) has exhibited rapid progress, becoming capable of handling not only static images but also dynamic images. In addition, multimedia services such as video on demand (VOD), which allows the user to watch a desired program at any convenient time; an electronic encyclopedia using a CD-ROM; and the generation of dynamic images using a DVD (digital video (or versatile) disk) are becoming popular.

In such a multimedia service, dynamic-image data (such as a television image) may be displayed on a display screen of an image displaying apparatus for displaying computer text and graphics. The display screen of a CRT (cathode ray tube) display unit or an LCD (liquid-crystal display) unit, which is connected to a computer and used as an image displaying apparatus for displaying an image signal output by the computer, has good precision, but in general has its display contrast set at a low value in comparison with a television receiver.

For example, let us compare the value of the peak contrast of a television receiver with that of an image displaying apparatus. The value of the peak contrast of a television receiver is normally at least 300 cd/m

2

. On the other hand, the value of the peak contrast of an image displaying apparatus for displaying an image based on an image signal output by a computer is about 150 cd/m

2

, a low value which is about half that of the peak contrast of a television receiver.

Such a contrast value is good in that it does not cause fatigue to the eyes of the user who spends a long period of time on the composition of a text or work such as CAD (Computer Aided Design) by using a computer. For displaying a dynamic image described above, however, the contrast value of the screen of the image displaying apparatus provides an appearance inferior to a television receiver, becoming a negative factor in the image display.

In order to solve the problem described above, an image displaying apparatus has been proposed, which has an additional switching means for manually increasing the display contrast of the entire image displaying apparatus employed in the conventional computer over the entire display screen (for example, in a case of displaying a dynamic image thereon).

The conventional control of display brightness, an item of adjustment like the one described above, includes adjustment of contrast, adjustment of brightness, and control of the amplitudes of a variety of color image signals, such as the red, blue, and green color signals. The adjustment of contrast, the adjustment of brightness, and the control of amplitudes can all be controlled for the entire display screen. However, the control of contrast on only part of the display screen for a dynamic-image portion or the like has not been prescribed.

In addition, window-luminance adjusting systems capable of individually adjusting the luminance of a specified window are disclosed in Japanese Patent Laid-open Nos. Sho 61-248083, Sho 63-158587, Hei 4-220691, Hei 7225575 and Hei 8-251503. In each of these window-luminance adjusting systems, however, the distribution of functions between the image displaying apparatus and the information processing apparatus for generating an image signal is not clarified.

SUMMARY OF THE INVENTION

When displaying a computer image as a window on the conventional image displaying apparatus, as is the general practice with the contemporary computer, dynamic images are displayed only on some windows of the display screen while the remaining windows are used for doing work such as composition of a text. Since the contrast of the entire display screen is controlled, even in such a case, the entire display screen becomes bright. As a result, in a state where a dynamic image is displayed while the user is doing work such as composition of a text, the amount of fatigue caused to the eyes of the user may increase.

In order to solve the problems described above, the present invention provides a technology that clarifies the distribution of functions among the image displaying apparatus, the information processing apparatus, and an operating system controlling the operations of the information processing apparatus. The present invention is capable of displaying data with a display attribute varying from area to area on the display screen of the image displaying apparatus.

In an image displaying system wherein an image signal is transmitted from an information processing apparatus to an image displaying apparatus to be displayed on the image displaying apparatus, the invention generates area-attribute information for modifying a display attribute of a specific area on a display screen of the image displaying apparatus. The area-attribute information generated in the information processing apparatus is transmitted from the information processing apparatus to the image displaying apparatus through a communication means. The display attribute of the specific area on the display screen of the image displaying apparatus is modified in accordance with the area-attribute information received by the image displaying apparatus, and the data is displayed on the display screen.

In the image displaying system described above, display attributes for special-type data, such as dynamic-image data, and for a special display element, such as an active window, are prepared in advance. Area-attribute information is generated, which comprises area information indicating a specific area on a display screen of the image displaying apparatus in which the data is to be displayed, and information on the display attributes prepared in advance is generated.

Then, a specific-area-display-attribute changing means changes a display attribute of data to be displayed in a specific area indicated by the area information of the generated area-attribute information, and the data is displayed in the specific area of the display screen of the image displaying apparatus.

As described above, according to the image displaying system provided by the present invention, area-attribute information is generated by the information processing apparatus for data to be displayed on the image displaying apparatus, and the data is displayed in a specific area of the display screen of the image displaying apparatus indicated by the area-attribute information by modifying a display attribute of the specific area in accordance with the area-attribute information.

As a result, in the image displaying system, the distribution of functions among the image displaying apparatus, the information processing apparatus, and an operating system controlling the operations of the information processing apparatus is clarified. In addition, the image displaying system is capable of displaying data with a display attribute varying from area to area on the display screen of the image displaying apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a diagram schematically showing a configuration of an image displaying system implemented by a first embodiment of the invention;

FIG. 2

is a diagram showing an outline of processing carried out by the image displaying system implemented by the first embodiment;

FIG. 3

is a diagram showing a preferred implementation of an information processing apparatus provided by the first embodiment;

FIG. 4

is a diagram schematically showing the configuration of the image displaying system implemented by the first embodiment, wherein DDC controllers are employed;

FIG. 5

is a diagram showing an outline of processing carried out by the image displaying system implemented by the first embodiment wherein DDC controllers are employed;

FIG. 6

is a diagram showing a preferred implementation of the information processing apparatus employing a DDC controller as implemented by the first embodiment;

FIG. 7

is a diagram showing an example of a memory space in the first embodiment;

FIG. 8

is a diagram showing an example of processing to generate area-attribute information carried out by an application program in the first embodiment;

FIG. 9

is a diagram schematically showing area information of a single display area in the first embodiment;

FIG. 10

is a diagram schematically showing area information of a plurality of display areas in the first embodiment;

FIG. 11

is a diagram schematically showing preferred area information of an area having a shape other than a rectangle in the first embodiment;

FIGS.

12

(

a

) and

12

(

b

) are diagrams schematically showing typical area information of a plurality of display areas which overlap each other in the first embodiment;

FIG. 13

is a diagram schematically showing graphical information of a three-dimensional display area, and display areas each having any arbitrary shape in the first embodiment;

FIG. 14

is a flowchart showing a procedure of initialization processing carried out by the operating system in the first embodiment;

FIG. 15

is a flowchart showing a procedure carried out by the application program to modify a display attribute in the first embodiment;

FIG. 16

is a flowchart showing a procedure carried out in the first embodiment to change a display attribute using attribute information stored along with dynamic-image data;

FIGS.

17

(

a

) to

17

(

c

) are diagrams showing examples of storage media each for storing dynamic-image attribute information along with dynamic-image files in the first embodiment;

FIG. 18

is a flowchart showing a procedure of processing to modify a display attribute in the event of a specific trigger in the first embodiment;

FIG. 19

is a diagram schematically showing processing to generate area-attribute information carried out by the operating system in the first embodiment;

FIG. 20

is a diagram schematically showing formats of data packets of the USB interface in the first embodiment;

FIG. 21

is a diagram schematically showing formats of transmission of the image-displaying-apparatus information in the first embodiment;

FIG. 22

is a diagram schematically showing a signal transmission format conforming to the DDC protocol used in the first embodiment;

FIG. 23

is a diagram showing a preferred implementation of an image displaying apparatus provided by the first embodiment;

FIGS.

24

(

a

) to

24

(

b

) are diagrams schematically showing different formats of area-attribute information used in the first embodiment;

FIGS.

25

(

a

) and

25

(

b

) are timing charts each schematically showing a relation between the levels of the timing signal Key and the image signal in the first embodiment;

FIG. 26

is a diagram schematically showing the configuration of the image displaying system implemented by a second embodiment of the invention;

FIG. 27

is a diagram showing an outline of processing carried out by the image displaying system implemented as the second embodiment;

FIG. 28

is a flowchart showing a procedure of initialization processing carried out by the operating system in the second embodiment;

FIG. 29

is a flowchart showing a procedure of processing carried out by an application program to modify a display attribute in the second embodiment;

FIGS.

30

(

a

) and

30

(

b

) are diagrams schematically showing the color-information control register, the area start-position registers, and the area end-position registers employed in the second embodiment;

FIG. 31

is a diagram showing the internal configuration of the display controller employed in the second embodiment;

FIG. 32

is a diagram showing the internal configuration of the color-information controller employed in the second embodiment;

FIG. 33

is a diagram showing the internal configuration of a pallet employed in the second embodiment;

FIG. 34

is a diagram showing the internal configuration of a comparator employed in the second embodiment;

FIG. 35

is a timing chart of operations of the color-information controller employed in the second embodiment;

FIG. 36

is a diagram showing a preferred implementation of the image displaying apparatus provided by the second embodiment;

FIG. 37

is a diagram schematically showing the configuration of the image displaying system implemented by a third embodiment of the invention;

FIG. 38

is a diagram showing an outline of processing carried out by the image displaying system implemented by the third embodiment;

FIG. 39

is a flowchart showing a procedure of processing carried out by an application program to modify a display attribute in the third embodiment;

FIG. 40

is a diagram schematically showing the plane system of the layout of the data to be displayed and attribute data stored in a display memory unit in the third embodiment;

FIG. 41

is a diagram schematically showing the packed-pixel system of the layout of the data to be displayed and attribute data stored in a display memory unit in the third embodiment;

FIG. 42

is a diagram showing the internal configuration of a display controller employed by the third embodiment;

FIG. 43

is a diagram showing the internal configuration of the color-information controller employed in the third embodiment;

FIG. 44

is an operational timing chart of the color-information controller employed in the third embodiment;

FIG. 45

is a diagram schematically showing the configuration of an image displaying system implemented by a fourth embodiment of the invention;

FIG. 46

is a diagram showing an outline of processing carried out by the image displaying system implemented by the fourth embodiment;

FIG. 47

is a flowchart showing a procedure of initialization processing carried out by the operating system in the fourth embodiment;

FIG. 48

is a diagram showing the internal configuration of a display controller provided by the fourth embodiment;

FIG. 49

is a diagram showing the internal configuration of the color-information controller employed in the fourth embodiment;

FIG. 50

is timing charts showing operations of the color-information controller employed in the fourth embodiment;

FIG. 51

is a diagram showing a preferred implementation of the image displaying apparatus provided by the fourth embodiment;

FIG. 52

is a diagram schematically showing the configuration of an image displaying system implemented by a fifth embodiment of the invention;

FIG. 53

is a diagram showing an outline of processing carried out by the image displaying system implemented by the fifth embodiment;

FIG. 54

is a diagram showing the internal configuration of the display controller provided by the fifth embodiment;

FIG. 55

is a diagram showing the internal configuration of the color-information controller employed in the fifth embodiment;

FIG. 56

is a timing chart showing operations of the color-information controller provided by the fifth embodiment; and

FIG. 57

is a diagram showing a preferred implementation of an image displaying apparatus provided by the fifth embodiment for transmitting image information.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention will become more apparent from a study of the following detailed description, with reference to the accompanying diagrams.

First Embodiment

The following is a description of an image displaying system implemented by a first embodiment of the invention. In this first embodiment, a display attribute of a specific display area can be changed in accordance with area-attribute information transmitted from an information processing apparatus to an image displaying apparatus on which the specific area is displayed.

FIG. 1

is a diagram that shows a configuration of the image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system comprises an information processing apparatus

100

and an image displaying apparatus

110

. The information processing apparatus

100

receives information concerning the image displaying apparatus

110

from the image displaying apparatus

110

, and transmits an image signal and information concerning area attributes to the image displaying apparatus

110

. The image displaying apparatus

110

displays the image signal on a specific area of a display screen by modifying the display attribute of the specific area on the display screen in accordance with the area-attribute information received from the information processing apparatus.

The information processing apparatus

100

comprises a CPU

101

and a main memory unit

102

. The CPU

101

is a processor for carrying out total control of the information processing apparatus

100

. More specifically, the CPU

101

controls the information processing apparatus

100

by actually interpreting and executing application programs, an operating system, and a group of programs such as a USB (Universal Serial Bus) device driver and an image displaying device driver, which are loaded into the main memory unit

102

.

In addition, the information processing apparatus

100

also includes an HDD (Hard Disk Drive)

103

, which is a storage device for storing software such as the application programs, the operating system, a GUI (Graphical User Interface) program, an API (Application Program Interface) program, the USB device driver and the image displaying device driver. The information processing apparatus

100

is also provided with a DVD

104

, which is another storage device for storing text data and display data of static and dynamic images to be displayed on the image displaying apparatus

110

.

Further, the information processing apparatus

100

also has a display controller

105

and a display memory unit

106

. The display controller

105

controls write operations for writing data to be displayed on the image displaying apparatus

110

into the display memory unit

106

, and controls read operations for reading out the data from the display memory unit

106

as an image signal to be transmitted to the image displaying apparatus

110

.

Finally, the information processing apparatus

100

of the present embodiment is also provided with a USB controller

107

, which is a communication means for transmitting an inquiry signal to the image displaying apparatus

110

and receiving a report signal, a response to the inquiry signal, from the image displaying apparatus

110

. The inquiry signal is used for making an inquiry about the ability of the image displaying apparatus

110

to display an image on a specific area on the screen thereof by changing a display attribute of the specific area in accordance with USB standards. In other words, the inquiry signal asks whether the image displaying apparatus

110

can accommodate multiple images at once, one of which has a changing display attribute that modifies the actual display of the image in a specific area of the display screen while the other image or images on the display screen are not so modified. The USB controller

107

is also used for supplying the image displaying apparatus

110

with the information on area attributes for changing the display attribute of the specific area on the display screen of the image displaying apparatus

110

.

On the other hand, the image displaying apparatus

110

comprises a CPU

111

and a ROM unit

112

. The CPU

111

is a processor for controlling the image displaying apparatus

110

as a whole by interpretation and execution of a control program stored in a storage area of the ROM

112

. It should be noted that the control program itself is not shown in the figure.

The ROM

112

employed in the image displaying apparatus

110

stores information in the image displaying apparatus

110

. Such information indicates whether or not the image displaying apparatus

110

has a specific-area-display-attribute changing means

113

, that is, whether or not the image displaying apparatus

110

has the capability of displaying an image on a specific area on the screen thereof by changing a display attribute of the specific area. The specific-area-display-attribute changing means

113

changes the display attribute of a specific area on an image displaying device

114

employed in the image displaying apparatus

110

.

In addition, the image displaying apparatus

110

also employs a USB controller

115

, which serves as a counterpart of the USB controller

107

employed in the information processing apparatus

100

. More specifically, the USB controller

115

receives an inquiry signal from the information processing apparatus

100

and transmits a report signal, in response to the inquiry signal, to the information processing apparatus

100

. The inquiry signal is used for making an inquiry about the ability of the image displaying apparatus

110

to display an image on a specific area on the screen thereof by changing a display attribute of the specific area in accordance with USB standards.

FIG. 2

is a diagram showing an outline of processing carried out by the image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system has an application program

200

, an operating system

210

, a USB device driver

230

, and an image displaying device driver

240

in the information processing apparatus

100

, in addition to image-displaying-apparatus information

260

in the image displaying apparatus

110

.

The application program

200

in the information processing apparatus

100

comprises a GUI, which includes a portion that is visible to the operator who operates the information processing apparatus

100

, and which also serves as an interface with the operating system

210

.

The operating system

210

in the information processing apparatus

100

is a basic program serving as the nucleus of the image displaying system. More specifically, the operating system

210

connects the application program

200

with program members that directly control hardware, such as the USB device driver

230

and the image displaying device driver

240

.

The image displaying device driver

240

in the information processing apparatus

100

is positioned between the operating system

210

and hardware members such as the device controller

105

and the display memory unit

106

. More specifically, the image displaying device driver

240

is a program which implements a draw instruction issued by the operating system

210

by reading out and writing information from and into internal registers of the display controller

105

and the display memory unit

106

. It should be noted that the internal registers themselves are not shown in the figure.

The application program

200

in the information processing apparatus

100

is provided with an area-attribute-information generating means

201

. When there is detected a need to change a display attribute of a specific area on the display screen of the image displaying apparatus

110

, area-attribute information

250

for changing the display attribute of the specific area on the display screen of the image displaying apparatus

110

is generated in the application program

200

and passed to the operating system

210

by the area-attribute-information generating means

201

.

The operating system

210

in the information processing apparatus

100

comprises a display-attribute-change control means

211

, an area-attribute-information generating means

212

, and an area-attribute-information acquiring means

213

. The display-attribute-change control means

211

controls the entire display-attribute-change processing of the information processing apparatus

100

by making an inquiry about an ability of the image displaying apparatus

110

to display an image on a specific area on the display screen thereof by changing a display attribute of the specific area and receiving a response to the inquiry. The area-attribute-information generating means

212

generates area-attribute information

251

in the operating system

210

when there is detected a need to change a display attribute of a specific area on the display screen of the image displaying apparatus

110

. The area-attribute-information acquiring means

213

acquires the area-attribute information

250

generated by the area-attribute-information generating means

201

of the application program

200

.

In addition, the USB device driver

230

and the image displaying device driver

240

are included in the operating system

210

. The USB device driver

230

converts the area-attribute information

251

and image-displaying-apparatus information

262

into USB data packets and vice versa in accordance with USB standards, and exchanges area-attribute information

252

and image-displaying-apparatus information

261

between the information processing apparatus

100

and the image displaying apparatus

110

. The image displaying device driver

240

stores data to be displayed in the display-memory unit

106

.

The USB controller

107

is controlled by the USB device driver

230

so that an inquiry about an ability of the image displaying apparatus

110

to display an image on a specific area on the display screen thereof by changing a display attribute of the specific area is transmitted from the USB controller

107

to the image displaying apparatus

110

. The report indicating such a capability in response to the inquiry is received by the USB controller

107

. Controlled by the USB device driver

230

, the USB controller

107

also carries out processing to transmit the area-attribute information

251

passed from the display-attribute-change control means

211

.

Receiving the area-attribute information

251

passed from the display-attribute-change control means

211

, the USB device driver

230

assembles a packet comprising the contents of the area-attribute information

251

in a format matching a USB protocol, and transfers the packet to the USB controller

107

. The USB controller

107

converts the packet transferred thereto into an electrical signal, transmitting the signal conveying the information to the image displaying apparatus

110

connected to the USB controller

107

.

The USB controller

115

employed in the image displaying apparatus

110

connected to the USB controller

107

receives the packet destined therefor, extracting area information and attribute information from the area-attribute information

252

. The display attribute of a specific area on the display screen of the image displaying apparatus

110

is then changed by a specific-area-display-attribute changing means

113

.

FIG. 3

is a diagram showing a preferred implementation of the information processing apparatus

100

provided by the present embodiment. As shown in the figure, in the information processing apparatus

100

, a CPU

101

, a secondary cache memory unit

305

, and a memory controller

302

for controlling access to the main memory unit

102

are connected to a host bus

301

, including control line

1

, address line

2

, and data line

3

. A bus controller

307

for controlling access to the HDD

103

and the DVD

104

, the display controller

105

, and the USB controller

107

are connected to a system bus

306

. Finally, a system ROM

312

and an I/O controller

318

are connected to an I/O bus

310

.

The memory controller

302

controls the secondary cache memory unit

305

via cache control line

4

, tag control line

5

, and tag address line

6

. The memory controller

302

further controls access to the main memory unit

102

through a memory bus

303

, over which addresses are transmitted on address line

7

, control signals on control line

8

, and data on data line

9

, and also controls connection between the host bus

301

and the system bus

306

. The bus controller

307

controls connection between the system bus

306

and the I/O bus

310

, and also controls the HDD

103

and the DVD

104

.

The system bus

306

is a bus to which high-speed devices and high-speed controllers are connected via control line

10

and address/data line

11

thereof. In the implementation shown in

FIG. 3

, the system bus

306

is implemented by a PCI (Peripheral Component Interface) bus, wherein data and an address are multiplexed. It should be noted that the system bus

306

can also be implemented by a bus wherein the address and data buses are separated from each other as is the case with the host bus

301

. Low/medium-speed devices and low/medium-speed controllers are connected from the system bus

306

to the I/O bus

310

through the bus controller

307

.

Connected to the system bus

306

, the display controller

105

controls write operations for writing display data from the CPU

101

into the display memory unit

106

, and display operations for displaying the display data stored in the display memory unit

106

on a CRT display unit

322

or a liquid-crystal display unit

323

, either of which serves as the image displaying apparatus

110

.

Connected to the USB controller

107

are a USB-oriented keyboard

313

, a mouse

314

, a serial port

316

, a parallel port

317

, and the CRT display unit

322

or the liquid-crystal display unit

323

.

Like the display controller

105

, the USB controller

107

is connected to the system bus

306

in the information processing apparatus

100

as shown in FIG.

3

. The USB controller

107

is used for controlling output units and input units such as the keyboard

313

and the mouse

314

. In the image displaying system implemented by the present embodiment, the output unit controlled by the USB controller

107

is the CRT display unit

322

or the liquid-crystal display unit

323

.

A packet assembled by the USB bus driver

230

to contain the contents of the area-attribute information

251

is transferred from the CPU

101

to the system bus

306

by way of the memory controller

302

before being supplied to the USB controller

107

. The packet received by the USB controller

107

is then output to the CRT display unit

322

or the liquid-crystal display unit

323

.

It should be noted that the display controller

105

and the USB controller

107

can be connected to one image displaying apparatus

110

or to a plurality of image displaying apparatus, which are implemented by CRT display units

322

and/or liquid-crystal display units

323

.

The system ROM

312

connected to the I/O bus

310

is used for storing software and data such as an IPL (Initial Program Loader) executed at power-on, a BIOS (Basic Input/Output System), a display control program, and display fonts. The I/O controller

318

controls access to an FDD

319

.

The communication means for exchanging the area-attribute information

252

and the image-displaying-apparatus information

261

between the information processing apparatus

100

and the image displaying apparatus

110

can be implemented by a non-USB device such as a DDC (Display Data Channel, a trademark) controller.

FIG. 4

is a diagram showing the configuration of an image displaying system implemented by the present embodiment, wherein DDC controllers are employed. As shown in the figure, a DDC controller

401

is provided in the information processing apparatus

100

for receiving image-displaying-apparatus information from the image displaying apparatus

110

, and for transmitting an image signal and area-attribute information to the image displaying apparatus

110

. A DDC controller

411

is provided in the image displaying apparatus

110

for receiving the image signal and the area-attribute information from the information processing apparatus

100

, and for displaying an image on a specific area on the display screen of the image displaying apparatus

110

by changing a display attribute of the specific area.

The CPU

101

employed in the information processing apparatus

100

is a processor for controlling the entire information processing apparatus

100

. More specifically, the CPU

101

controls the information processing apparatus

100

as a whole by actually interpreting and executing an application program

200

, an operating system

210

, and a group of programs such as a DDC device driver and an image displaying device driver

240

which are loaded into the main memory unit

102

.

In addition, the information processing apparatus

100

also includes an HDD

103

for storing software such as the application program

200

, the operating system

210

, a GUI program, an API program, the DDC device driver, and the image displaying device driver

240

. The information processing apparatus

100

is also provided with a DVD

104

for storing text as well as display data of static and dynamic images to be displayed on the image displaying apparatus

110

.

Further, the information processing apparatus

100

has a display controller

105

and a display memory unit

106

. The display controller

105

controls write operations for writing data to be displayed on the image displaying apparatus

110

into the display memory unit

106

, and controls read operations for reading out the data from the display memory unit

106

as an image signal to be transmitted to the image displaying apparatus

110

.

The DDC controller

401

transmits an inquiry signal to the image displaying apparatus

110

and receives a report signal, in response to the inquiry signal, from the image displaying apparatus

110

. The inquiry signal is used for making an inquiry about the ability of the image displaying apparatus

110

to display an image on a specific area on the screen thereof by changing a display attribute of the specific area in accordance with DDC standards. The DDC controller

401

is also used for supplying the image displaying apparatus

110

with information on area attributes for changing a display attribute of a specific area on the display screen of the image displaying apparatus

110

.

On the other hand, the image displaying apparatus

110

comprises a CPU

111

and a ROM unit

112

. The CPU

111

is a processor for controlling the image displaying apparatus

110

as a whole by interpretation and execution of a control program stored in a storage area of the ROM unit

112

. It should be noted that the control program itself is not shown in the figure.

The ROM unit

112

employed in the image displaying apparatus

110

is a recording medium for storing information on the image displaying apparatus

110

. Such information indicates whether or not the image displaying apparatus

110

has a specific-area-display-attribute changing means

113

, that is, indicates whether or not the image displaying apparatus

110

has a capability of displaying an image on a specific area on the screen thereof by changing a display attribute of the specific area. The specific-area-display-attribute changing means

113

is a means for changing a display attribute of a specific area on an image displaying device

114

employed in the image displaying apparatus

110

.

In addition, the image displaying apparatus

110

also employs a DDC controller

411

, a communication means serving as a counterpart of the DDC controller

401

employed in the information processing apparatus

100

. More specifically, the DDC controller

411

receives an inquiry signal from the information processing apparatus

100

and transmits a report signal, a response to the inquiry signal, to the information processing apparatus

100

. The inquiry signal is used for making an inquiry about the ability of the image displaying apparatus

110

to display an image on a specific area on the screen thereof by changing a display attribute of the specific area in accordance with DDC standards.

In the interface which conforms to the DDC standards, bi-directional data and clock lines are used. A source that transmits data carries out a multi-master operation to generate a clock signal. In addition, in the DDC interface, the data and clock lines are implemented by wires in the same cable as an image-signal line between the information processing apparatus

100

and the image displaying apparatus

110

.

FIG. 5

is a diagram showing an outline of processing carried out by the image displaying system implemented by the present embodiment, in which DDC controllers are employed. As shown in the figure, the image displaying system has an application program

200

, an operating system

210

, a DDC device driver

501

, and an image displaying device driver

240

in the information processing apparatus

100

.

The application program

200

in the information processing apparatus

100

comprises a GUI, which includes a portion that is visible to the operator who operates the information processing apparatus

100

, and which also serves as an interface with the operating system

210

.

The operating system

210

in the information processing apparatus

100

is a basic program serving as the nucleus of the image displaying system. More specifically, the operating system

210

connects the application program

200

with program members that directly control hardware, such as the DDC device driver

501

and the image displaying device driver

240

.

The image displaying device driver

240

in the information processing apparatus

100

is positioned between the operating system

210

and hardware members such as the device controller

105

and the display memory unit

106

. More specifically, the image displaying device driver

240

is a program which implements a draw instruction issued by the operating system

210

by reading out and writing information from and into internal registers of the display controller

105

and the display memory unit

106

. It should be noted that the internal registers themselves are not shown in the figure.

The operating system

210

converts the DDC-signal transmission format of the area-attribute information

251

to that of the image-displaying-apparatus information

260

and vice versa in accordance with DDC standards. The operating system

210

is provided with the DDC device driver

501

for transmitting area-attribute information

252

from the information processing apparatus

100

to the image displaying apparatus

110

and image-displaying-apparatus information

261

from the image displaying apparatus

110

to the information processing apparatus

100

.

The DDC controller

401

is controlled by the DDC device driver

501

to transmit an inquiry to the image displaying apparatus

110

about an ability of the image displaying apparatus

110

to display an image on a specific area on the display screen thereof by changing a display attribute of the specific area. In response to the inquiry, the DDC controller

401

receives a report from the image displaying apparatus

110

indicating the capability of the image displaying apparatus

110

to display such an image on a specific area on its display screen. Controlled by the DDC device driver

501

, the DDC controller

401

also carries out processing to transmit the area-attribute information

251

passed from a display-attribute-change control means

211

.

After receiving the area-attribute information

251

passed from the display-attribute-change control means

211

, the DDC device driver

501

assembles data comprising the contents of the area-attribute information

251

in a format matching a DDC protocol and transfers the data to the DDC controller

401

. The DDC controller

401

converts the data transferred thereto into an electrical signal, and transmits the signal conveying the information to the image displaying apparatus

110

connected to the DDC controller

401

.

The image displaying apparatus

110

receives the data from the DDC controller

401

, and extracts area information and attribute information from the area-attribute information

252

. The display attribute of the specific area is then changed by a specific-area-display-attribute changing means

113

.

FIG. 6

is a diagram showing a preferred embodiment of the information processing apparatus

100

employing a DDC controller as implemented by the present embodiment. As shown in the figure, the information processing apparatus

100

employs a DDC controller

401

connected to a system bus

306

. Connected to the DDC controller

401

are a DDC oriented keyboard

313

, a mouse

314

, a serial port

316

, a parallel port

317

and the CRT display unit

322

or the liquid-crystal display unit

323

.

Like the display controller

105

, the DDC controller

401

is connected to the system bus

306

in the information processing apparatus

100

as shown in FIG.

6

. The DDC controller

401

is used for controlling output units and input units such as the keyboard

313

and the mouse

314

. In the image displaying system implemented by the present embodiment, the output unit controlled by the DDC controller

401

is the CRT display unit

322

or the liquid-crystal display unit

323

, either of which may serve as the image displaying apparatus

110

.

A packet assembled by the DDC device driver

501

to comprise the contents of the area-attribute information

251

is transferred from the CPU

101

to the system bus

306

by way of the memory controller

302

before being supplied to the DDC controller

401

. The packet received by the DDC controller

401

is then output to the CRT display unit

322

or the liquid-crystal display unit

323

.

As described above, in the image displaying system implemented by the present embodiment, the communication means for exchanging the area-attribute information

252

and the image-displaying-apparatus information

261

between the information processing apparatus

100

and the image displaying apparatus

110

can be implemented by a non-USB device such as a DDC controller. In the following description, mainly, cases in which a USB device is employed are explained.

A BIOS program stored in a system ROM

312

, as well as software such as the operating system

210

, the GUI program, the API program, the USB device driver

230

, and the image displaying device driver

240

stored in the HDD

103

, are loaded into the main memory unit

102

at power on, remaining in the main memory unit

102

as resident programs thereafter.

FIG. 7

is a diagram showing an example of a memory space in the present embodiment. As shown in the figure, a memory space from OOOOOH to

9

FFFFH is allocated to the main memory unit

102

and a memory space from COOOOH to EFFFFH is extended space allocated as a specific memory (for example, a display control program area in the system ROM

312

) and to the main memory unit

102

etc. A memory space FOOOOH to FFFFFH is a system memory space allocated to a BIOS area in the system ROM

312

.

The lowest 1M memory space in the 4G memory space is allocated as an image space that includes the main memory space from OOOOOH to

9

FFFFH and the system memory space from FOOOOH to FFFFFH described above. A memory space from AOOOOH to BFFFFH is a display memory space allocated to the display memory unit

106

.

The following is description of the area-attribute information

250

which is generated by the application program

200

or the operating system

210

of the image displaying system when a display attribute of a specific area is changed.

When the information processing apparatus operates to display data with attribute information set in advance, the area-attribute-information generating means

201

or the area-attribute-information generating means

212

generates area-attribute information

250

, which is used for modifying a display attribute of the specific area in which the data is to be displayed.

The area-attribute information

250

generated by the area-attribute-information generating means

201

or the area-attribute-information generating means

212

comprises area information specifying the location of the specific area for displaying the data, and attribute information specifying a display attribute at which the data is to be displayed. The attribute information of the area-attribute information

250

includes the contrast, the brightness, the chromaticity and the γ characteristic. The attribute information is set for each type of data to be displayed and for each specific unit such as a display element.

For example, the data types for which the attribute information is set include text data, static-image data, and dynamic-image data. As an alternative, attribute information may also be set for each display element, such as a window, a box, a cursor, a button, and an icon. As another alternative, attribute information may also be set for an arbitrary unit specified by the user, such as a string of specific characters, a graphic, or a portion or a specific display area of a display element.

In addition, the attribute information of the area-attribute information

250

is set in advance as a run-time parameter of the application program

200

for displaying specific data, such as dynamic-image data. As an alternative, the attribute information can also be set typically for each window in a database to be referenced by the operating system

210

which displays a screen element, such as a window for a dynamic image.

Further, the attribute information can also be set for a specific state of data to be displayed, such as an active-window state resulting from connection of an input/output unit to a specific window, or a state resulting after the lapse of a specific period of time since the last input operation.

In the event of a need to modify a display attribute of a specific area on the display screen, accompanying specific processing for data to be displayed with attribute information set in advance as described above, the area-attribute-information generating means

201

or the area-attribute-information generating means

212

generates area-attribute information

250

, which is used for modifying the display attribute of the specific area in which the data is to be displayed.

A display attribute of a specific area on a display screen of the image displaying apparatus

110

needs to be modified in the event of the start or the end of processing to display data with attribute information set as described above, in the event of an operation to move or copy an area with a modified display attribute for displaying data with attribute information set as described above, in the event of an operation to enlarge or shrink such an area with a modified display attribute, in the event of a change in overlapping state occurring in such an area with a modified display attribute, and in the event of execution of an operation to generate a state of a modified display attribute, by way of nonlimiting example.

The area-attribute-information generating means

201

of the application program

200

generates area-attribute information

250

in the event of any of the aforementioned occurrences happening to data to be displayed under the control of the application program

200

.

FIG. 8

is a diagram showing an example of processing that is performed by the application program

200

to generate area-attribute information, according to the present embodiment. As shown in the figure, the application program

200

generates a text display

811

and a dynamic-image display

812

which has a higher contrast than that of the text display

811

, on a display window

810

of the application program

200

.

In order to display dynamic-image data having a high contrast on the text display

811

, the area-attribute-information generating means

201

of the application program

200

generates area-attribute information

250

comprising area information indicating the location of a display area on which the dynamic-image data is to appear, and attribute information indicating the contrast of the dynamic-image data.

Preferably, the area-attribute-information generating means

201

first acquires attribute information indicating the contrast value used in displaying the dynamic-image data by referencing a parameter set in advance in the application program

200

.

Then, the area-attribute-information generating means

201

acquires the area information of the dynamic-image display

812

on which the dynamic-image data is to be displayed. Even though it is possible to provide the display area for displaying the dynamic-image data from another source, in this example, the application program

200

itself sets the display area and displays the dynamic-image data in the display area. Thus, a display area set in advance is acquired as area information, a display attribute of which is to be modified.

The application program

200

then transfers the area-attribute information

250

to the image displaying apparatus

110

through the operating system

210

. The specific-area-display-attribute changing means

113

of the image displaying apparatus

110

sets the display attribute of the dynamic-image display

812

at a high contrast and displays the dynamic-image data.

The following is description of some possible expression formats for the area information of the area-attribute information

250

generated as described above.

FIG. 9

is a diagram that shows typical area information of a single display area in the present embodiment. As shown in the figure, the area information of a single display area illustrates a relation between a window A, displayed on the image displaying apparatus

110

by changing a display attribute of the window A, and input synchronization signals. In general, in an image signal output by the information processing apparatus

100

, an image display is started at a point lagging the trailing edges of a horizontal synchronization-signal pulse and a vertical synchronization-signal pulse by predetermined periods of time known as back-porch periods. In the case of the example shown in the figure, the start point lags the trailing edges of a horizontal synchronization-signal pulse and a vertical synchronization-signal pulse by periods THFP and TVFP, respectively. The display periods, that is, THD and TVD shown in the figure, are determined by the display resolution.

In the case of an image signal conforming to VGA (Video Graphic Adapter) standards, for example, the horizontal width is 640 dots and the vertical height is 480 lines. Therefore, the maximum values on the coordinate axes (X, Y) of the display screen shown in

FIG. 9

are (640 dots, 480 lines), where one dot is the period of the clock signal (that is, the so-called “dot clock”), used in the information processing apparatus

100

for generating the image signal.

It is thus clear from the above description that, in order to obtain accurate information on the start position (x

0

, y

0

) and the end position (x

1

, y

1

) of the rectangular window A in the image displaying apparatus

110

, it is necessary for the information processing apparatus

100

to transfer at least information on the horizontal and vertical back-porch periods, information on the display resolution, the frequency of the period of the dot clock, and coordinates of the start and end positions of the window, to the image displaying apparatus

110

.

So far, transmission of absolute area information of the rectangular window A has been described. Similarly, the position of the window A can also be specified by the start position (x

0

, y

0

), the number of dots in the window period in the horizontal direction, and the number of lines in the window period in the vertical direction.

As another alternative, the area information of the window can also be specified by taking the intersection of lines passing through the trailing edges of the horizontal synchronization-signal pulse and the vertical synchronization-signal pulse as a reference origin (

0

,

0

) of a two-dimensional X-Y coordinate system. Then, the start position of the window A can be expressed in terms of dots and lines from the origin (

0

,

0

) to the start position. Other information can then be specified in the same way.

Instead of expressing information in terms of dots and lines as described above, ratios with respect to one horizontal scanning period and one vertical scanning period can also be used. For example, the width of the window can be expressed by a range from a start position corresponding to x

1

% of one horizontal scanning period to an end point corresponding to x

2

% of one horizontal scanning period, with the trailing period of the horizontal synchronization-signal pulse taken as a reference. Similarly, the height of the window can be expressed by a range from a start position corresponding to y

1

% of one vertical scanning period to an end point corresponding to y

2

% of one vertical scanning period, with the trailing period of the vertical synchronization-signal pulse taken as a reference. By expressing area information on the window in terms of ratios with respect to one horizontal scanning period and one vertical scanning period, it becomes no longer necessary in particular to know information on the frequency or the period of the dot clock in the image displaying apparatus

110

.

FIG. 9

is a diagram showing window-area information used for locating a single display area, a display attribute of which is to be modified. It should be noted, however, that display attributes of a plurality of windows can also be modified.

FIG. 10

is a diagram showing typical area information of a plurality of display areas in the present embodiment. As shown in the figure, the area information of a plurality of display areas is used to illustrate an example of changing the display attributes of windows A and B which do not overlap each other. In this case, by transfer-ring area information of the window B to the image displaying apparatus

110

in addition to the area information of the window A shown in

FIG. 9

, display attributes of both display areas can be modified.

In this way, with regard to area information of a plurality of windows which do not overlap each other in the image displaying system implemented by the present embodiment, area information of the additional windows is just prescribed. To be more specific, by merely providing the image displaying apparatus

110

with as many pieces of area information as there are windows that require a change in display attribute, display attributes of a plurality of windows can be modified.

FIG. 11

is a diagram showing typical area information of an area having a shape other than a rectangle in the present embodiment. As shown in the figure, the area information of an area having a shape other than a rectangle is used to illustrate how to prescribe area information when changing the display attribute of a window area having a such a shape. The area information in this case is described as follows.

First, information on salient points of the polygonal area like a window B is prescribed. More specifically, coordinates of the n salient points of an n-angle polygon are prescribed. That is to say, in the case of the window B shown in the figure, the information on the salient points of the polygonal area is constituted by coordinates (x

1

, y

1

), (x

2

, y

2

), ---, (xm, ym), for m points.

In the case of an ellipse or an elliptical area like a window C, information on the coordinates of its center (x

0

, y

0

), the horizontal-direction radius xc, and the vertical-direction radius yc is prescribed. In addition, shape information which indicates what shape the area information is associated with is also prescribed prior to the prescription of the area information.

FIG. 12

is a diagram that shows typical area information of a plurality of display areas which overlap each other in the present embodiment. As shown in the figure, the area information of a plurality of display areas is used to illustrate how to change the display attributes of a plurality of windows which overlap each other. As will be described later, it is possible to change the display attributes of a plurality of windows which overlap each other.

FIG.

12

(

a

) is a diagram showing a case in which a window B is displayed at a position closer to the viewer than a window A. FIG.

12

(

b

) is a diagram showing a case in which a portion of the window B is concealed behind the window A. For the sake of simplifying the explanation, the following describes a problem of how to properly display the window B on a screen with a display attribute thereof changed to one different from that of the corresponding display attribute of the window A, which is assumed to be a window with ordinary display attributes.

In the case of the windows A and B shown in FIG.

12

(

a

), the processing described earlier for the rectangular window can be applied since the entire information of the window B is visible. In the case of the windows A and B shown in FIG.

12

(

b

), on the other hand, the window B can be displayed properly by treating information on the display area of the window B as information on a polygonal shape (

FIG. 11

) or by dividing the display area of the window B into a plurality of rectangular shapes.

When prescribing the area information as polygonal information, coordinate information of each of the black circles shown in FIG.

12

(

b

) is generated. When prescribing the area information as information on a plurality of rectangular windows, on the other hand, area information is generated by dividing the visible display area of the window B typically into an upper rectangular window sub-area and a lower rectangular window sub-area as shown in FIG.

12

(

b

). It should be noted that such division is no more than an example. The visible display area of the window B can be divided in other ways.

If the window A shown in FIG.

12

(

a

) is also a window with a display attribute thereof to be changed as is the case with the window B, the window A can be displayed properly by prescribing information on the display area of the window A as a partially concealed area in the same way as the window B shown in FIG.

12

(

b

) is treated. As an alternative to the techniques to treat a display area as a partially concealed area, information on a relation between a concealed sub-area and a concealing sub-area on the display screen of the image displaying apparatus

110

can further be added to the area information of each window, to form three-dimensional area information for each window. That is to say, Z-axis information in a direction perpendicular to the two-dimensional X-Y coordinate system of the area information described so far is added to make area information of each window three dimensional.

When three-dimensional area information is received by the image displaying apparatus

110

, the specific-area-display-attribute changing means

113

employed in the image displaying apparatus

110

identifies a relation among concealed and concealing windows, changing the display attribute of the area of the window at the uppermost layer.

The following is a description of various kinds of information transferred from the information processing apparatus

100

to the image displaying apparatus

110

in the image displaying system implemented by the present embodiment.

TABLE 1

Contents

Image-signal

Video dot clock frequency

information

Total number of horizontally arranged dots

Total number of vertically arranged lines

(dots)

Number of dots in a horizontal back-porch

period

Number of dots in a vertical back-porch period

Number of horizontal-display dots

Number of vertical-display lines

TABLE 2

Contents

Area

Level 0: No window

information

Level 1: A single rectangular window

and its level

Window start-position information (x0, y0) and

window end-position information (x1, y1)

Level 2: A plurality of pieces of Level-1

information

Number of display windows: n

Start-position information (x0, y0) and end-

position information (x1, y1) of window W1

Start-position information (x0, y0) and end-

position information (x1, y1) of window W2

.

.

.

Start-position information (x0, y0) and end-

position information (x1, y1) of window Wn

Level 3: A single deformed-shape window

Circular window information m = 2

Circle-center information = (x0, y0)

X-axis and Y-axis radii = (xc, yc)

Polygonal-shape information ≧ 3 (m is the

number of salient points)

Information on salient points

(x1, y1) . . . (xm, ym)

Level 4: A plurality of deformed windows

The number of display windows: n

Window number (Number of salient points,

x-y coordinates)

W1 (Number of points: m, (x0, y0), (x1, y1),

. . . (xm, ym))

W2 (Number of points: m, (x0, y0), (x1, y1),

. . . (xm, ym))

.

.

.

Wn (Number of points: m, (x0, y0), (x1, y1),

. . . (xm, ym))

Level 5:

Three-dimensional version of Level 1

(x0, y0, z0), (x1, y1, z1)

Level 6:

Three-dimensional version of Level 2

Level 7:

Three-dimensional version of Level 3

TABLE 3

Contents

Attribute

Relevant-level switching

Information

Display attribute change control on/off

Entire screen attribute change/window attribute

change switching

Entire screen contrast control

Number of controlled-contrast windows

Specification of the numbers of windows to be

controlled

Window portion contrast control

Entire screen brightness control

Window portion brightness control

ABL control system switch

ABL control level specification

Entire screen chromaticity control

Window portion chromaticity control

Window portion R/G/B gain control

Entire screen γ value setting

Window portion γ value setting

Display attribute change portion edge trimming

on/off

Edge trimming color setting

Display attribute change portion

enlargement/shrinking

Table 1 is a table of typical image signal information transferred to the image displaying apparatus

110

for modifying display attributes prior to the area information. Table 2 is a table of typical area information required for modifying display attributes. Relevant tables shown in Table 2 are parameters each indicating the number, the shape and the overlapping state of a window. For example, Level 1 shown in the table represents area information of a single rectangular window indicating the start and end points of the window. Level 2 in the same table indicates a plurality of pieces of Level-1 information.

Table 3 is a table of typical attribute information transferred from the information processing apparatus

100

to the image displaying apparatus

110

after area information. The table includes information on display attributes such as contrast and brightness of a specific area specified by area information transferred from the information processing apparatus

100

to the image displaying apparatus

110

prior to the attribute information.

The “relevant-level switching” shown in Table 3 is switching information for determining what level an image is to be displayed by the image displaying apparatus

110

whenever a level shown in Table 2 is applicable. The “display attribute change control on/off” is information on whether or not the display attribute change control is allowed in the image displaying apparatus

110

.

The “entire screen attribute change/window attribute change switching” is switching information for determining whether the display attribute of the entire display screen appearing on the image displaying apparatus

110

or the display attribute of only an area indicated by the area information is to be changed. Using this information, either the display attribute of the entire display screen appearing on the image displaying apparatus

110

or the display attribute of only an area indicated by the area information is changed.

The “entire screen contrast control” is control information for controlling the contrast of the entire display screen of the image displaying apparatus

110

. The “number of controlled-contrast windows” is information on how many display areas indicated by area information will be subject to contrast control.

The “specification of the numbers of windows to be controlled” is numbers assigned to display areas (windows) which have changeable attribute information in case there are a plurality of such display areas. The “specification of the numbers of windows to be controlled” is thus specification information for clarifying objects to be controlled. The “window portion contrast control” is contrast control information of a specified display area.

The “entire screen brightness control” is the brightness control information for the entire screen, while the “window portion brightness control” is the brightness control information for a specified display area.

The “ABL (Average Brightness Level) control system switching” is switching information for selecting whether the average luminance of the entire display screen or the average luminance of display areas except a specific display area is to be made fixed. The “ABL control level specification” is information for specifying a maximum luminance level of a portion subject to luminance control by a selected ABL control system. A “maximum luminance level” is a level at which the beam current is suppressed so as not to exceed a specification value of the CRT display unit

322

.

The “entire screen chromaticity control” is information on setting the chromaticity (a white color containing some red or blue color) of a white-color display of the entire screen. The “window portion chromaticity control” is information on setting the chromaticity of a specific display area.

The “window portion R/G/B gain control” is video gain control information of RGB colors of a specific display area. The “entire screen r value setting” is information for correcting the γ characteristics (the video voltage amplitude and display luminance characteristics) of the entire display screen, while the “window portion γ value setting” is information for correcting the γ characteristics of a characteristic area.

The “display attribute change portion edge trimming on/off” is switching information for determining whether or not edge trimming is to be carried out for a specific area, the display attribute of which is to be changed. The “edge trimming color setting” is information which is used for setting an edge-trimming color when the edge trimming described above is carried out. The “display attribute change portion enlargement/shrinking” is control information on whether a portion with a display attribute thereof changed is to be enlarged or shrunk.

It should be noted that the pieces of control information shown in Table 3 do not have to be all transferred to the image displaying apparatus

110

. That is to say, only required pieces of control information are transferred from the information processing apparatus

100

to the image displaying apparatus

110

.

In addition, in the image displaying system implemented by the present embodiment, a display attribute can be set for a three-dimensional display area and a display area having any arbitrary shape such as a cursor, as follows.

FIG. 13

is a diagram showing, graphical information of display areas having various, arbitrary shapes, including one display area having a three-dimensional shape, in the present embodiment. As shown in the figure, the graphical information is constituted by a cube

1303

that reflects light emitted by both an arrow-shaped cursor

1301

and a light source

1302

. When changing a display attribute of a display area having an arbitrary shape such as the cursor

1301

, area information comprising a bit pattern showing the shape thereof and a start address are generated.

In the case of the cube

1303

, the display attributes vary from plane to plane. In addition, if the display attributes of even the same plane of the cube

1303

vary in dependence upon the distance to the light source

1302

, area-attribute information

250

can be generated by setting not only the area information for each plane of the cube

1303

, but also by setting the display attributes of each plane which vary depending upon the coordinates of the position on the plane.

It should be noted that the area-attribute information

250

of an arbitrary shape such as the cursor

1301

and of a three-dimensional shape such as the cube

1303

can be expressed by developing attribute information for each picture element of display data stored in the display memory unit

106

, as will be described later.

The following is a description of segments of the processing carried out by the application program

200

and the operating system

210

in the image displaying system implemented by the present embodiment, when a display attribute of a specific area is changed.

FIG. 14

is a flowchart showing a procedure of initialization processing carried out by the operating system

210

in the present embodiment. The initialization processing carried out by the operating system

210

is preparatory to modifying a display attribute carried out by the operating system

210

, as shown in the figure. The initialization begins with a step

1401

at which the power supply of the information processing apparatus

100

is turned on. As the power supply is turned on, in processing carried out at a step

1411

, the USB device driver

230

initializes the USB controller

107

.

The flow then proceeds to a step

1402

at which the display-attribute-change control means

211

of the operating system

210

makes an inquiry to the image displaying apparatus through the USB driver

230

, into the ability of the image displaying apparatus

110

to modify a display attribute. The inquiry concerns, among other things, whether a specific-area-display-attribute changing means

113

is provided in the image displaying apparatus

110

, so as to display an image in a specific area on the display screen by modifying a display attribute of the specific area.

Receiving the inquiry, the USB driver

230

creates a packet containing the inquiry, and sends the inquiry packet to the image displaying apparatus

110

by way of the USB controller

107

as an inquiry signal in processing carried out at a step

1412

.

The image displaying apparatus

110

receives the inquiry signal transmitted by the information processing apparatus

100

by way of the USB controller

115

, creating a packet containing image-displaying-apparatus information

261

to indicate that a specific-area-display-attribute changing means

113

is provided in the image displaying apparatus

110

. The packet is sent to the information processing apparatus

100

by way of the USB controller

115

as a report signal in response to the inquiry packet.

The information processing apparatus

100

receives the report signal transmitted by the image displaying apparatus

110

, which report signal indicates whether a specific-area-display-attribute changing means

113

is provided in the image displaying apparatus

110

, by way of the USB controller

107

. In the processing carried out at the step

1412

, the USB device driver

230

of the information processing apparatus

100

receives the image-displaying-apparatus information

261

transmitted by the image displaying apparatus

110

by way of the USB controller

107

, passing on the image-displaying-apparatus information

261

to the display-attribute-change control means

211

as image-displaying-apparatus information

262

.

In processing carried out at a step

1403

, the display-attribute-change control means

211

references the image-displaying-apparatus information

262

received in the processing carried out at the step

1402

to find out whether or not the image displaying apparatus

110

is capable of modifying a display attribute of a specific area on its display screen. If the image displaying apparatus

110

is found to have such a capability, the flow goes on to a step

1404

at which an attribute change flag is set to indicate that a display attribute of a specific area on the display screen of the image displaying apparatus

110

can be changed.

If, on the other hand, the result of the examination of the image displaying-apparatus information

262

carried out in the processing of the step

1403

indicates that the image displaying apparatus

110

is not capable of modifying a display attribute of a specific area on its display screen, or if no image-displaying-apparatus information

262

is transmitted from the image displaying apparatus

110

, a display attribute of a specific area is considered to be unchangeable and the initialization processing is ended without setting the attribute change flag cited above.

An example of the image-displaying-apparatus information

260

acquired in the processing carried out at the step

1402

is shown in Table 4.

Contents

Information on

Relevant level

the image

Peak luminance

displaying

Average luminance

apparatus

Window-controllable items

(Initial

(Contrast, brightness, ABL, chromaticity, γ,

values)

RGB level)

Standard set value (entire screen)

Standard set value (window)

Recommended display resolution

Input video signal amplitude

The “relevant level” in Table 4 is the level shown in Table 2 that is associated with information required for modifying display attributes. The “peak luminance” is the maximum luminance level that can be displayed on the image displaying apparatus

110

. The “average luminance” is the luminance level of a white display on the entire display screen of the image displaying apparatus

110

.

The “window-controllable item” is a changeable item of the attribute information shown in Table 3. Examples of a window-controllable item are the contrast indicating the amplitude level of an image signal, the brightness indicating the direct-current level of an image signal, the ABL (Average Brightness Level) indicating the average value of the current waveform of an electron gun limited by a limiter, the chromaticity, the γ characteristic, and the RGB level, to name a few. These window-controllable items are all controllable.

The “standard set values (entire screen)” are default values of controllable items for the entire screen shown in Table 3. The “standard set values (window)” are default values of controllable items for a specific area shown in Table 3.

The “recommended display resolution” is a recommended display resolution that allows a display attribute to be changed effectively. An example of the recommended display resolution is 1,024 dots×768 lines. The “input video signal amplitude” is the amplitude of the input video signal that allows a display attribute to be changed effectively. An example of the input video signal amplitude is 0.7 V.

The following is description of processing carried out by the application program

200

to modify a display attribute so as to reproduce dynamic-image data at a high contrast, in a case in which the image displaying apparatus

110

is determined to be an apparatus capable of modifying a display attribute of a specific area on a display screen thereof.

FIG. 15

is a flowchart showing a processing procedure carried out by the application program

200

to modify a display attribute in the present embodiment. The procedure is a series of operations which are carried out by the application program

200

to modify a display attribute so as to display a window for reproducing dynamic-image data at a high contrast, as shown in the figure.

The flowchart begins with a step

1501

at which the user invokes the application program

200

for reproducing dynamic-image data. The flow then goes on to a step

1502

at which the application program

200

makes an inquiry about a list of files in a storage (such as the DVD

104

) for storing dynamic-image data to the operating system

210

.

In response to the inquiry, the operating system

210

references files on the DVD

104

through a file system driver and a DVD interface in order to open a file menu in processing carried out at a step

1511

.

As the list of files storing dynamic-image data is displayed, the user selects a file storing dynamic-image data from the list of files which are displayed in response to the inquiry made in the processing carried out at the step

1502

.

The flow then goes on to a step

1503

at which the application program

200

issues a draw instruction to the operating system

210

, to display a window for displaying a dynamic image corresponding to the selected dynamic-image data. At the request made by the application program

200

, the operating system

210

requests the image displaying device driver

240

to display the window for displaying the dynamic image by using area information specified in the draw instruction in processing carried out at a step

1512

. As a result, the window for displaying the dynamic image is displayed on the image displaying apparatus

110

by way of the display controller

105

.

The flow then proceeds to a step

1504

at which the area-attribute-information generating means

201

of the application program

200

issues a contrast-increasing instruction to the operating system

210

, requesting the operating system

210

to increase the contrast of the window in which the dynamic image is to be displayed. More specifically, the area-attribute-information generating means

201

transfers, to the image displaying apparatus

110

via the operating system

210

, the area-attribute information

250

comprising area information specified when displaying the window for displaying the dynamic image and attribute information showing a contrast value of the dynamic data specified in advance as a run-time parameter, in order to increase the contrast of the window in which the dynamic image is to be displayed.

At a step

1513

, the display-attribute-change control means

211

of the operating system

210

receives the contrast-increasing instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. Receiving the instruction, the area-attribute-information acquiring means

213

references the attribute change flag set at initialization and, if the image displaying apparatus

110

is capable of changing a display attribute of a specific area on its display screen, area-attribute information

251

is supplied to the USB device driver

230

, making a request to increase the contrast of the window in which the dynamic image is to be displayed.

At the request described above, the USB device driver

230

assembles an instruction packet containing the area-attribute information

251

to increase the contrast of the window in which the dynamic image is to be displayed, in conformity with a USB protocol, sending the packet to the USB controller

107

at a step

1521

.

The USB controller

107

converts the instruction packet supplied thereto into an electrical signal and outputs the electrical signal conveying the area-attribute information

252

to the image displaying apparatus

110

connected to the USB controller

107

. The image displaying apparatus

110

receives the instruction packet through the USB controller

115

, extracting area information and contrast information from the area-attribute information

252

. The contrast of the specified window containing the dynamic image is then changed accordingly.

The flow then continues to processing of a step

1505

at which the application program

200

reads out dynamic-image data from the selected dynamic-image file through the file system driver and the DVD interface, transferring the dynamic-image data to the main memory unit

102

. The dynamic-image data transferred to the main memory unit

102

is then sent to the image displaying apparatus

110

by way of the image displaying device driver

240

and the device controller

105

to be reproduced on the specified window, the display attribute of which has been changed to a high contrast value for dynamic-image data.

The flow then goes on to a step

1506

at which the application program

200

examines whether the dynamic-image data have all been reproduced. If any dynamic-image data remains to be reproduced, the flow returns to step

1505

. If the dynamic-image data have all been reproduced, on the other hand, the flow proceeds to a step

1507

.

At the step

1507

, the area-attribute-information generating means

201

of the application program

200

generates area-attribute information

250

for returning to the default value the display attribute of the window containing the dynamic image, issuing a default-contrast restoring instruction to the operating system

210

.

At a step

1514

, the display-attribute-change control means

211

of the operating system

210

receives the default-contrast restoring instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. Receiving the instruction, area-attribute information

251

for restoring the display attribute to the default contrast is supplied to the USB device driver

230

, making a request to the USB device driver

230

to carry out restoration of the display attribute to the default value (that is, to restore the display attribute of the window containing the dynamic image to the default contrast).

At the request described above, the USB device driver

230

assembles an instruction packet containing the area-attribute information

251

to restore the display attribute of the window having the dynamic image to the default contrast in conformity with the USB protocol, sending the instruction packet to the USB controller

107

in order to restore the contrast of the specified window to the default value at a step

1522

.

The flow then goes on to a step

1508

at which the application program

200

sends an instruction to the operating system

210

to close the window displaying the dynamic image. Receiving the instruction, the operating system

210

deletes the window displaying the dynamic image at a step

1515

. As the window for displaying a dynamic image is deleted, the application program

200

terminates the processing to reproduce the dynamic-image data.

As described above, the attribute information showing the contrast value of the dynamic-image data is set in advance as a run-time parameter of the application program

200

. It should be noted that the attribute information can also be stored in the DVD

104

for storing data to be displayed along with the data to be displayed, such as the dynamic-image data. In this case, in an operation to display such data, the attribute information which is stored along with the data to be displayed is read out from the storage and used for modifying the display attribute of the specific area on the display screen of the image displaying apparatus

110

.

FIG. 16

is a flowchart showing the processing procedure carried out in the present embodiment to change a display attribute using attribute information stored along with dynamic-image data. The procedure is a series of operations carried out by the application program

200

for changing the display attribute so as to set a window for displaying a dynamic image corresponding to dynamic-image data at a high contrast, to reproduce the dynamic-image data as shown in the figure.

The procedure begins with a step

1501

at which the user invokes the application program

200

. The flow then goes on to a step

1502

at which the application program

200

makes an inquiry to the operating system

210

about a list of files in a storage such as the DVD

104

, which contain dynamic-image data.

In response to the inquiry, the operating system

210

references files on the DVD

104

through a file system driver and a DVD interface in order to open a menu, at a step

1511

.

As the list of files containing dynamic-image data are displayed, the user selects one of the files from the list.

After a file for storing dynamic-image data has been selected, the flow goes on to a step

1601

at which the application program

200

makes a file-read request to the operating system

210

, requesting the operating system

210

to read out a contrast value, the attribute information of the dynamic-image data in the selected file.

At the request described above, the flow goes on to a step

1602

at which the operating system

210

reads out a contrast value, the attribute information set in advance in the selected file for storing the desired dynamic-image data, and passes the contrast value to the application program

200

.

The flow then goes on to a step

1503

at which the application program

200

issues a draw instruction to the operating system

210

to display a window for displaying a dynamic image corresponding to the selected dynamic-image data. At the request made by the application program

200

, the operating system

210

requests the image displaying device driver

240

to display the window by using area information specified in the draw instruction at a step

1512

. As a result, the window for displaying the dynamic image is displayed on the image displaying apparatus

110

by way of the display controller

105

.

The flow then proceeds to a step

1504

at which the area-attribute-information generating means

201

of the application program

200

issues a contrast-increasing instruction to the operating system

210

, requesting the operating system

210

to increase the contrast of the window in which the dynamic image is to be displayed. More specifically, the area-attribute-information generating means

201

transfers area-attribute information

250

comprising area information specified when displaying the window, and attribute information showing a contrast value of the dynamic data specified in advance as a run-time parameter, to the image displaying apparatus

110

through the operating system

210

, in order to increase the contrast of the window in which the dynamic image is to be displayed.

At a step

1513

, the display-attribute-change control means

211

of the operating system

210

receives the contrast increasing instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. Receiving the instruction, the area-attribute-information acquiring means

213

references the attribute change flag set at initialization and, if the image displaying apparatus

110

is an apparatus capable of changing a display attribute of a specific area on a display screen thereof, area-attribute information

251

is supplied to the USB device driver

230

, making a request to increase the contrast of the specified window.

At the request described above, the USB device driver

230

assembles an instruction packet containing the area-attribute information

251

to increase the contrast of the window in conformity with a USB protocol, sending the packet to the USB controller

107

in processing carried out at a step

1521

.

The USB controller

107

converts the instruction packet supplied thereto into an electrical signal and outputs the electrical signal conveying area-attribute information

252

to the image displaying apparatus

110

connected to the USB controller

107

. The image displaying apparatus

110

receives the instruction packet through the USB controller

115

, extracting area information and contrast information from the area-attribute information

252

. The contrast of the specified window is then changed accordingly.

At the subsequent steps, the application program

200

reproduces the dynamic-image data stored in the selected file on the dynamic-data window, the display attribute of which has been changed to a high contrast value for dynamic-image data, in the same way as the processing described by referring to FIG.

15

.

FIGS.

17

(

a

)-

17

(

c

) show examples of storage media each for storing dynamic-image attribute information along with dynamic-image files in the present embodiment. Each of FIGS.

17

(

a

)-

17

(

c

) show the DVD

104

for storing dynamic-image attribute information along with dynamic-image files, wherein a plurality of dynamic-image files

1701

to

1703

for storing dynamic data are stored along with attribute information for the dynamic-image data contained in the dynamic-image files

1701

to

1703

.

The attribute information stored in the storage medium along with data to be displayed can be dynamic-image attribute information

1700

common to the dynamic-image files

1701

to

1703

as shown in FIG.

17

(

a

), or pieces of dynamic-image attribute information

1711

to

1713

included in the dynamic-image files

1701

to

1703

, respectively, which are created for different titles of dynamic-image data as shown in FIG.

17

(

b

).

The attribute information can be stored in the storage medium as a file, or simply recorded in the storage medium as numbers.

As an alternative, the pieces of dynamic-image data

1701

to

1703

are stored in the storage medium as scene data

1731

to

1736

, specific units, as shown in FIG.

17

(

c

). Pieces of dynamic-image attribute information

1721

and

1726

are then set for the pieces of scene data

1731

to

1736

, respectively. In this case, when the scene data is reproduced, the display attribute of the scene data is changed in accordance with the dynamic-information attribute information associated with the scene data.

As described above, attribute information is set for each specific unit composing data to be displayed and, by changing the display attribute for each specific unit of the data to be displayed in accordance with the set attribute information, a display attribute set for each piece of data by the user and aimed at a specific display effect can be reproduced with a high degree of fidelity.

FIG. 18

is a flowchart showing a processing procedure for modifying a display attribute in the event of a specific trigger in the present embodiment. The procedure is a series of operations carried out by the operating system

210

to modify a display attribute of a window for displaying data at an increased contrast in the event of a specific trigger, as shown in the figure.

In the event of a specific trigger, the display-attribute-change control means

211

of the operating system

210

obtains information on the cause of the trigger at a step

1801

.

The flow then goes on to a step

1802

at which the display-attribute-change control means

211

forms a judgment as to whether the trigger causes a movement of a window for displaying data at an increased contrast. If the trigger causes a movement of a window for displaying data at an increased contrast, the flow goes on to a step

1805

at which the area-attribute-information generating means

212

generates area-attribute information

251

using post-movement area information, making a request to the USB device driver

230

to reset the contrast value of the window.

At the request, the USB device driver

230

assembles an instruction packet containing the area-attribute information

251

to reset the contrast value of the window in conformity with a USB protocol, sending the packet to the USB controller

107

at a step

1811

.

If the outcome of the judgment formed at the step

1802

indicates that the trigger does not cause a movement of a window for displaying data at an increased contrast, on the other hand, the flow proceeds to a step

1803

at which the display-attribute-change control means

211

forms a judgment as to whether the trigger causes the size of a window for displaying data at an increased contrast to be changed.

If the outcome of the judgment formed in the processing carried out at the step

1803

is YES, the flow goes on to the step

1805

described earlier. Otherwise, the flow continues to a subsequent step. At each of the subsequent steps, the display-attribute-change control means

211

forms a judgment as to whether the trigger is relevant to a window for displaying data at an increased contrast. Similarly, if the outcome of the judgment is YES, the flow goes on to the step

1805

described earlier. Otherwise, the flow continues to a subsequent step. If the outcome of the judgment formed at the last step is NO, the processing is terminated.

As described above, the display attribute of the display screen of the image displaying apparatus

110

can always be updated in accordance with the area-attribute information

250

, allowing data to be properly displayed in a window of the display screen.

FIG. 19

is a diagram showing processing carried out by the operating system

210

to generate area-attribute information in the present embodiment. In the processing to generate area-attribute information carried out by the operating system

210

shown in the figure, as an example, data is displayed on an active window display screen

1901

at a contrast higher than those of window display screens

1902

and

1903

, on the display screen

800

of the image displaying apparatus

210

.

The operating system

210

receives a window drawing instruction including area information from the application program

200

, displaying a window on a display screen of the image displaying apparatus

110

or a window on a display screen inside the operating system

210

for notifying the user of. information. The area information at that time is a value determined in the operating system

210

.

A plurality of these windows can be displayed. When newly displaying a window, the window frames already existing at the uppermost layer of the display screen (the layer closest to the viewer) are made to be visually the same as other windows, while the new window frame is made to be different from the others; for example the color of the window frames already existing at the uppermost layer can be made to be the same as the lower-layer frames, while the color of the new window is different. As a result, the newly displayed window can be identified with ease as an active window needing the user's attention at the present time.

After a new window display screen

1901

has been displayed, a click of the mouse

314

to designate the already-existing window display screen

1901

as an active window is detected by the display-attribute-change control means

211

of the operating system

210

as a trigger. In the event of such a trigger, the area-attribute-information generating means

212

generates area-attribute information

251

comprising attribute information of the active window and area information indicating a location where the active window is displayed. That is, when the window display screen

1901

is made an active window by a click of the mouse

314

, the area-attribute-information generating means

212

of the operating system

210

references a database for storing a variety of set values for windows, acquiring contrast information used as attribute information set in advance for the active window.

Then, the area-attribute-information generating means

212

acquires area information showing a display area for displaying the active window display screen

1901

. The display area of the window display screen

1901

is controlled by the operating system

210

itself, and is acquired as area information on a controlled area, subject to a change of a display attribute.

The area-attribute-information generating means

212

of the operating system

210

passes the acquired area-attribute information

251

to the display-attribute-change control means

211

. As the display-attribute-change control means

211

sends the acquired area-attribute information

251

to the image displaying apparatus

110

by way of the USB device driver

230

, the image displaying apparatus

110

displays the window display screen

1901

by requesting the specific-area-display-attribute changing means

113

to modify the contrast of the window display screen

1901

to a value indicated by the area-attribute information

252

.

FIG. 20

is a diagram showing formats of data packets of the USB interface in the present embodiment. More specifically, the figure shows the contents of each USB-interface data packet which is exchanged between the information processing apparatus

100

and the image displaying apparatus

110

by using the USB interface as a communication interface, and used by the information processing apparatus

100

for controlling the image displaying apparatus

110

.

A set-up token packet

2001

is transmitted from the information processing apparatus

100

to the image displaying apparatus

110

for informing the image displaying apparatus

110

that communication is started. A data packet

2002

is transmitted from the information processing apparatus

100

to the image displaying apparatus

110

, following the set-up token packet

2001

, for indicating the kind of information that is to be exchanged and the amount of the transmission to be transmitted after this packet.

Receiving the set-up token packet

2001

and the data packet

2002

, the image displaying apparatus

110

returns a handshake packet

2003

to the information processing apparatus

100

as a response to the set-up token packet

2001

and the data packet

2002

.

After that, the information processing apparatus

100

outputs an output token packet

2004

, requesting the image displaying apparatus

110

to carry out predetermined data setting. A data packet

2005

contains four bytes of data indicating the data setting to be carried out and how much data will be involved in the data setting.

When the output token packet

2004

and the data packet

2005

are received by the image displaying apparatus

110

normally, the image displaying apparatus

110

returns a handshake packet

2006

to the information processing apparatus

100

.

A data packet data portion

2007

shows in detail the four bytes of data contained in the data packet

2005

. The first byte is a fixed ID number, and the second byte is an operation code showing what control or adjustment is to be carried out. The third and fourth bytes are an actual set value for the control or adjustment specified by the operation code.

Typical standard operation codes for controlling or adjusting the image displaying apparatus

110

through the USB interface are shown in Table 5.

TABLE 5

USB op

VCP command name

Function

code

Brightness

Brightness control

10H

Contrast

Contrast control

12H

Red Video Gain

Red gain control

16H

Green Video Gain

Green gain control

18H

Blue Video Gain

Blue gain control

1AH

Focus

Spot size adjustment

1CH

Horizontal Position

Horizontal position

20H

control

Horizontal Size

Horizontal size control

22H

Horizontal Pincushion

Side pin distortion

24H

adjustment

Horizontal Pincushion

Side pin distortion

26H

Balance

left-right adjustment

Horizontal Misconvergence

Horizontal-direction

28H

misconvergence adjustment

Horizontal Linearity

Horizontal linearity

2AH

adjustment

Horizontal Linearity

Horizontal linearity

2CH

Balance

left-right adjustment

Vertical Position

Vertical position control

30H

Vertial Size

Vertical size control

32H

Vertical Pincushion

Vertical pin distortion

34H

adjustment

Vertical Pincushion

Vertical pin distortion

36H

Balance

up/down adjustment

Vertical Misconvergence

Vertical-direction

38H

misconvergence adjustment

Vertical Linearity

Vertical linearity

3AH

adjustment

Vertical Linearity Balance

Vertical linearity up/down

3CH

adjustment

Parallelogon Distortion

Parallelogon distortion

40H

adjustment

Trapezoidal Distortion

Trapezoidal distortion

42H

adjustment

Tilt

Rotation adjustment

44H

Top Corner Distortion

Top corner distortion

46H

Control

adjustment

Top Corner Distortion

Top corner distortion

48H

Balance

balance adjustment

Bottom Corner Distortion

Bottom corner distortion

4AH

Control

balance adjustment

Bottom Corner Distortion

Bottom corner distortion

4CH

Balance

balance adjustment

Horizontal Moiré

Horizontal Moiré adjustment

56H

Vertical Moiré

Vertical Moiré adjustment

58H

Input Level Select

Input signal level

5EH

selection

Input Source Select

Input signal selection

60H

The image displaying apparatus

110

does not have to be provided with capabilities for all of the functions listed in Table 5. It will be sufficient to provide facilities for required functions only. Since one byte is allocated to the operation code, hexadecimal codes 00H to FFH can be used.

Codes which are not used yet in Table 5 are reserved for future expansions. By assigning a variety of controllable and adjustable items for the purpose of changing the display attributes shown in Tables 1 to 3, it is possible to modify a variety of display attributes by using the USB interface. By utilizing unused codes described above, it is possible to prevent communication errors and incorrect display controls in the function of communication with an information processing apparatus

100

that has no display-attribute changing function, even if area-attribute information

250

is output to an image displaying apparatus

110

having such functions as a standard.

For example, operation codes 00H to 60H shown in Table 5 are provided for the USB interface. Thus, an operation code 62H can be assigned for contrast control of a specific area on the display screen of the image displaying apparatus

110

as an extension code.

As another example, an operation code 64H can be assigned for changing information on the start position of an area, while an operation code 66H can be assigned for changing information on the end position of the area. In this way, the additional extension operation codes allow the area information to be updated in the image displaying apparatus

110

by using the USB interface.

An extension operation code can also be provided for carrying out the contrast control and the control to change area information at the same time. As an alternative, by defining a new Set_Report_Request field for updating area information in the data packet

2002

following the set-up token packet

2001

, data showing area information can be transmitted as is by using the data packet

2005

following the next output token packet

2004

. In this case, however, a lot of data cannot be transmitted by using one data packet

2005

. To solve this problem, the data is transmitted by using a plurality of data packets

2005

.

FIG. 21

shows transmission formats of the image-displaying-apparatus information

260

in the present embodiment. As shown in the figure, the image-displaying-apparatus information

260

is transmitted from the image displaying apparatus

110

to the information processing apparatus

100

in a USB packet when the latter makes a request for the image-displaying-apparatus information

260

to the former.

The set-up token packet

2101

, the data packet

2102

, and the handshake packet

2103

shown in

FIG. 21

are the same as packets

2001

,

2002

, and

2003

shown in FIG.

20

. More specifically, the information processing apparatus

100

calls a peripheral apparatus specified by an address code in an ADDR field in the set-up token packet

2101

, and a request made by the information processing apparatus

100

to the called peripheral apparatus is specifically described in the DATA field of the next data packet

2102

.

When the packets described above are received by the peripheral apparatus, that is, the image displaying apparatus

110

in this case, the image displaying apparatus

110

returns a handshake packet

2103

to the information processing apparatus

100

.

In the case of a data packet

2102

requesting the image displaying apparatus

110

to send the image displaying-apparatus information

260

thereof to the information processing apparatus

100

, an input token packet

2104

is issued by the information processing apparatus

100

to the image displaying apparatus

110

, to be followed by the desired image-displaying-apparatus

260

in a data packet

2105

transmitted by the image displaying apparatus

110

to the information processing apparatus

100

. If the USB transmission is successful, a handshake packet

2106

is transmitted by the information processing apparatus

100

to the image displaying apparatus

110

.

The image-displaying-apparatus information

260

shown in Table 4 is acquired by the information processing apparatus

100

by issuing an input token packet

2104

when the USB interface is initialized. At that time, a request to acquire image-displaying-apparatus information (a Get_Descriptor request prescribed in the USB standards) is sent by the information processing apparatus

100

to the image displaying apparatus

110

by using the data packet

2102

following the set-up token packet

2101

, and various kinds of information shown in Table 4 are sent by the image displaying apparatus

110

to the information displaying apparatus

100

by using the data packet

2105

following the input token packet

2104

.

At that time, since the maximum amount of information included in the data packet

2105

issued by the image displaying apparatus

110

is eight bytes, the image-displaying-apparatus information

260

is transmitted by using some data packets

2105

. In this case, a handshake packet

2106

is issued for each data packet

2105

.

In addition, in the image displaying system implemented by the present embodiment, when communication conforming to the DDC standards is carried out between the information processing apparatus

100

and the image displaying apparatus

110

, the following signal transmission format is used.

FIG. 22

is a diagram showing a signal transmission format conforming to the DDC protocol used in the present embodiment. The DDC signal transmission format shown in the figure is a standard signal transmission format used when transmitting information in conformity with DDC standards. The first byte is the address of the destination to which the information is transmitted, an address assigned to peripheral equipment connected to the information processing apparatus

100

. The next byte is the address of the apparatus sending the information, and the third byte represents the amount of information being transmitted.

The fourth byte is a command describing the information being transmitted. An operation code following the command is information on actual control, etc. The byte following the operation code represents an adjustment amount, and the last byte contains a check sum for error checking of the transmitted data.

By using the signal transmission format described above, for example, the contrast of a specific area on a display screen of the image displaying apparatus

110

can be controlled. In this case, the command is an instruction transmitted to the image displaying apparatus

110

by the information processing apparatus

100

to control the image displaying apparatus

110

. The operation code following the command is completely identical with the code used in the case of the USB protocol (that is, a code shown in Table 5). As a result, a request or a command for the image displaying apparatus can be issued in the same way, even if the type of interface changes.

The following is a description of the image displaying apparatus

110

employed in the image displaying system, wherein a dynamic image B (for example, a television image signal) is displayed over an image A by increasing the contrast of the image B in accordance with area-attribute information

252

transmitted to the image displaying apparatus

110

from the information processing apparatus

100

.

FIG. 23

is a diagram showing a preferred implementation of an image displaying apparatus

110

provided by the present embodiment. As shown in the figure, the image displaying apparatus

110

comprises amplitude control means

2301

for changing the amplitude of an image signal, direct-current-level control means

2302

for controlling the direct-current level of the image signal, an adder

2303

, variable power supplies

2304

to

2306

, a switch

2307

, data latches

2310

to

2312

for setting the voltages of the variable power supplies

2304

to

2306

, respectively, address decoders

2320

to

2322

for determining whether data is to be latched in the data latches

2310

to

2312

, respectively, and a circuit for generating a timing signal KEY for actuating the switch

2307

.

The circuit for generating the timing signal KEY comprises a vertical start counter

2330

for determining a start address of the image B in the vertical direction, a vertical end counter

2331

for determining an end address of the image B in the vertical direction, a horizontal start counter

2332

for determining a start address of the image B in the horizontal direction, a horizontal end counter

2333

for determining an end address of the image B in the horizontal direction, AND gates

2340

to

2342

, data latches

2313

to

2316

for setting address values in the vertical start counter

2330

, the vertical end counter

2331

, the horizontal start counter

2332

, and the horizontal end counter

2333

, respectively, and address decoders

2323

to

2326

.

The data latch

2310

is used for storing data of the direct-current level of an image signal VIDEO

1

supplied by the information processing apparatus

100

. The direct-current level determines the brightness of the entire display screen. The data latch

2311

is used for storing amplitude data of the image signal VIDEO

1

for determining the contrast of the entire display screen. The data latch

2312

is used for storing amplitude data for determining the contrast of an area for displaying the image B. The data latch

2313

is used for storing the vertical start address of the image B. The data latch

2314

is used for storing the vertical end address of the image B. The data latch

2315

is used for storing the horizontal start address of the image B. The data latch

2316

is used for storing the horizontal end address of the image B.

FIG. 24

is a diagram showing different formats of the area-attribute information

252

used in the present embodiment. As shown in the figure, the area-attribute information

252

comprises area information which is transmitted from the information processing apparatus

100

and stored in the latches described above, and contrast levels showing contrast values which represent attribute information. To be more specific, FIG.

24

(

a

) shows a contrast level along with start and end addresses, FIG.

24

(

b

) shows a contrast level, a start address, and horizontal and vertical widths, and FIG.

24

(

c

) shows a contrast level, an end address, and horizontal and vertical widths.

In the specific-area-display-attribute changing means

113

shown in

FIG. 23

, the circuit is designed by assuming that the received area-attribute information

252

comprises a contrast level along with start and end addresses as shown in FIG.

24

(

a

). If the received area-attribute information

252

has another format like the ones shown in FIGS.

24

(

b

) and

24

(

c

), the circuit for generating the timing signal KEY needs to be modified to conform to the format.

It should be noted that data of the direct-current level of the image signal VIDEO

1

for determining the brightness of the entire display screen, data of the amplitude of the image signal VIDEO

1

for determining the contrast of the entire display screen, and addresses are stored as initial data in the ROM

112

to be read out by the CPU

111

. The initial data can be changed by the CPU

111

in accordance with operations carried out by the user.

In the specific-area-display-attribute changing means

113

shown in

FIG. 23

, the data latch

2310

and the address decoder

2320

are associated with each other to form a pair. Similarly, the data latch

2311

and the address decoder

2321

are associated with each other to form a pair, and so on. Pieces of data to be stored in the data latches

2310

to

2316

and addresses to be decoded by the address decoders

2320

to

2326

are supplied by the CPU

111

. Addresses are decoded by the address decoders

2320

to

2326

to find out whether the addresses match those of the associated respective data latches

2310

to

2316

. If the addresses match those of the associated respective data latches

2310

to

2316

, the data latches

2310

to

2316

latch the respective pieces of data supplied thereto.

Assume, for example, that data of direct-current levels for determining the brightness of the entire display screen is supplied by the CPU

111

. An address supplied by the CPU

111

at the same time is decoded by the address decoder

2320

to determine whether the data is indeed data for the data latch

2310

. If the data is judged to be data for the data latch

2310

, a latch pulse generated by the address decoder

2320

is used for latching the data into the data latch

2310

.

Pieces of data in the data latches

2313

and

2314

are preset in the vertical start counter

2330

and the vertical end counter

2331

, respectively, with timing determined by a vertical synchronization signal VSYNC. Similarly, pieces of data in the data latches

2315

and

2316

are preset in the horizontal start counter

2332

and the horizontal end counter

2333

, respectively, with timing determined by a horizontal synchronization signal HSYNC.

Thereafter, the vertical start counter

2330

and the vertical end counter

2331

each count pulses of the horizontal synchronization signal HSYNC as a counter clock signal, whereas the horizontal start counter

2332

and the horizontal end counter

2333

each count pulses of a dot clock signal DOTCK as a counter clock signal. It should be noted that the dot clock signal DOTCK can be generated by multiplying the frequency of the horizontal synchronization signal HSYNC using a PLL technique, as shown in FIG.

23

.

The vertical start counter

2330

and the horizontal start counter

2332

output “0” till the contents reach the latch data preset therein, outputting “1” after the contents have reached the preset latch data. On the other hand, the vertical end counter

2331

and the horizontal end counter

2333

output “1” till the contents reach the latch data preset therein, outputting “0” after the contents have reached the preset latch data.

The outputs of the vertical start counter

2330

and the vertical end counter

2331

are supplied to the AND gate

2341

to produce the logical product thereof. Similarly, the outputs of the horizontal start counter

2332

and the horizontal end counter

2333

are supplied to the AND gate

2341

to produce the logical product thereof. The outputs of the AND gates

2341

and

2342

are supplied to the AND gate

2340

to generate the timing signal KEY, showing the area of the image B as the logical product thereof.

FIGS.

25

(

a

) and

25

(

b

) are timing charts showing a relation between the levels of the timing signal KEY and the image signal in the present embodiment. To be more specific, FIG.

25

(

a

) is a timing chart showing a relation between the levels of the timing signal KEY and the image signal during a horizontal scanning period, and FIG.

25

(

b

) is a timing chart showing a relation between the levels of the timing signal KEY and the image signal during a vertical scanning period. The hatched portion of the image signal VIDEO

1

corresponds to the image B. The timing signal KEY is “0” (that is, reset at a low level) at all times except during this hatched period, where it is set at “1” (a high level).

Referring back to

FIG. 23

, as shown in the figure, the switch

2307

is controlled by this timing signal KEY. Since the timing signal is normally “0”, the switch

2307

is set on a contact q. As the timing signal KEY is set to “1”, however, the switch

2307

is set to a contact q which is connected to the variable power supply

2306

.

A voltage output by the switch

2307

is supplied to the adder

2303

. This output voltage is added to a voltage output by the variable power supply

2304

. Since the timing signal KEY is “0” except during the period of the image signal VIDEO

1

corresponding to the image B, however, the adder

2303

passes on the output voltage of the variable power supply

2304

as is. In the period of the image signal VIDEO

1

corresponding to the image B, the sum of the voltages output by the variable power supplies

2304

and

2306

is output by the adder

2303

.

Here, the voltage output by the variable power supply

2306

has a value corresponding to the data latched in the data latch

2312

, whereas the voltage output by the variable power supply

2304

has a value corresponding to the data latched in the data latch

2311

.

The voltage output by the adder

2303

is supplied to the amplitude control means

2301

as a control voltage. The amplitude control means

2301

controls the amplitude of the image signal VIDEO

1

in accordance with the control voltage supplied thereto. As described above, since the level of the control voltage is high during the period of the image signal VIDEO

1

corresponding to the image B, the amplitude of the image signal VIDEO

1

is amplified even more by the amplitude control means

2301

during this period. The direct-current-level control means

2302

further sets the direct-current level of the image signal VIDEO

1

output by the amplitude control means

2301

at a value corresponding to a voltage output by the variable power supply

2305

, to produce an image signal VIDEO

2

, which also has an amplitude in this period amplified to a level higher than those in other periods.

In this way, by properly setting the voltages output by the variable power supplies

2304

and

2306

, the contrast levels of the portion of the image B of the image signal VIDEO

1

and those of the other portions can be set at arbitrary values independent of each other. For example, let an image A be a static text image while the image B is a dynamic television image. In this case, by increasing the contrast of the television image while relatively suppressing that of the text image, the television image can be made bright and beautiful and, at the same time, the text image can be made easy to read.

As described above, according to the image displaying system implemented by the present embodiment, area-attribute information

250

for changing a display attribute of a specific area on a display screen of the image displaying apparatus

110

is generated by the information processing apparatus

100

and transferred to the image displaying apparatus

110

where an image is displayed on the specific area of the display screen thereof by changing a display attribute of the specific area. As a result, the image displaying system can keep up with processing to change a display attribute of the specific area by merely modifying a program in the information processing apparatus

110

.

Second Embodiment

The following is a description of an image displaying system implemented by a second embodiment of the invention, wherein data to be displayed in a specific area on a display screen of an image displaying apparatus and attribute data for the specific area are transferred from an information processing apparatus to the image displaying apparatus, and the display attribute of the specific area is changed in accordance with the attribute data in the image displaying apparatus.

FIG. 26

is a diagram showing a configuration of an image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system comprises an information processing apparatus

100

having a display controller

105

that includes an area judging means

2600

. The area judging means forms a judgment as to whether data to be displayed exists in a specific area, a display attribute of which is to be changed, on a display screen of an image displaying apparatus

110

, which has a display-attribute changing means

2601

for changing a display attribute of an image signal for the specific area. The image displaying apparatus

110

is connected to the information processing apparatus

100

.

In the image displaying system implemented by the present embodiment, after the area judging means

2600

forms a judgment as to whether data to be displayed exists in the specific area whose display attribute is to be changed, the information processing apparatus

100

transmits an image signal to the image displaying apparatus

110

. Then, after the display-attribute changing means

2601

of the image displaying apparatus

110

changes the display attribute of the specific area, the image is displayed.

The CPU

101

employed in the information processing apparatus

100

is a processor for controlling the entire information processing apparatus

100

. More specifically, the CPU

101

controls the information processing apparatus

100

as a whole by actually interpreting and executing an application program

200

, an operating system

210

, and a group of programs such as a USB device driver

230

and an image displaying device driver

240

which are loaded into the main memory unit

102

.

In addition, the information processing apparatus

100

also includes an HDD

103

for storing software such as the application program

200

, the operating system

210

, a GUI program, an API program, the USB device driver

230

, and the image displaying device driver

240

. The information processing apparatus

100

is also provided with a DVD

104

for storing texts as well as display data of static and dynamic images to be displayed on the image displaying apparatus

110

.

The display controller

105

controls a write operation for writing data to be displayed on the image displaying apparatus

110

into the display memory unit

106

, and controls a read operation for reading out the data from the display memory unit

106

as an image signal to be transmitted to the image displaying apparatus

110

. Further, the display controller

105

has a plurality of registers in which area-attribute information

251

used for changing the display attribute of the specific area is set. The display controller

105

also transfers area-attribute information for changing the display attribute of the specific area generated from the area-attribute information

251

to the image displaying apparatus

110

.

Finally, the information processing apparatus

100

is also provided with a USB controller

107

for transmitting an inquiry signal to the image displaying apparatus

110

, and receiving a report signal in response to the inquiry signal from the image displaying apparatus

110

.

The image displaying apparatus

110

comprises a CPU

111

and a ROM

112

. The CPU

111

is a processor for controlling the image displaying apparatus

110

as a whole by interpretation and execution of a control program stored in a storage area of the ROM

112

. The control program itself is not shown in the figure.

The ROM

112

employed in the image displaying apparatus

110

stores information indicating whether the image displaying apparatus

110

has a display-attribute changing means

2601

. That is, the ROM

112

indicates whether the image displaying apparatus

110

has a capability of displaying an image on a specific area on the screen thereof by changing the display attribute of the specific area. The display-attribute changing means

2601

changes a display attribute in the image signal input to the image displaying apparatus

110

in accordance with an attribute control signal.

In addition, the image displaying apparatus

110

also employs a USB controller

115

, which serves as a counterpart of the USB controller

107

employed in the information processing apparatus

100

. More specifically, the USB controller

115

receives the inquiry signal from the information processing apparatus

100

, and transmits the report signal in response to the inquiry signal to the information processing apparatus

100

. The inquiry signal is used for making an inquiry about the ability of the image displaying apparatus

110

to display an image on the specific area on the screen thereof by changing the display attribute of the specific area in accordance with USB standards.

FIG. 27

is a diagram showing an outline of the processing carried out by the image displaying system implemented by the present embodiment. As shown in the figure, the area judging means

2600

and the display-attribute changing means

2601

correspond to the specific-area-display-attribute changing means

113

.

The application program

200

in the information processing apparatus

100

comprises a GUI, which is visible to the operator who operates the information processing apparatus

100

, and which serves as an interface with the operating system

210

.

The operating system

210

in the information processing apparatus

100

is a basic program serving as the nucleus of the image displaying system. More specifically, the operating system

210

connects the application program

200

with program members directly controlling hardware, such as the USB device driver

230

and the image displaying device driver

240

.

The image displaying device driver

240

in the information processing apparatus

100

is positioned between the operating system

210

and hardware members such as the device controller

105

and the display memory unit

106

. More specifically, the image displaying device driver

240

is a program which implements a draw instruction issued by the operating system

210

, by reading out and writing information from and into internal registers of the display controller

105

and the display memory unit

106

. It should be noted that the internal registers themselves are not shown in the figure.

The application program

200

is provided with area-attribute-information generating means

201

. When there is detected a need to change the display attribute of the specific area on the display screen of the image displaying apparatus

110

, area-attribute information

250

for changing the display attribute of the specific area on the display screen of the image displaying apparatus

110

is generated in the application program

200

and passed to the operating system

210

by the area-attribute-information generating means

201

.

The operating system

210

comprises display-attribute-change control means

211

, area-attribute-information generating means

212

, and area-attribute-information acquiring means

213

. The display-attribute-change control means

211

controls the entire display-attribute-change processing of the information processing apparatus

100

by making an inquiry into an ability of the image displaying apparatus

110

to display an image on a specific area on its display screen, by changing the display attribute of the specific area, and by receiving a response to the inquiry. The area-attribute-information generating means

212

generates area-attribute information

251

in the operating system

210

when there is detected a need to change the display attribute. The area-attribute-information acquiring means

213

acquires the area-attribute information

250

generated by the area-attribute-information generating means

201

of the application program

200

.

In addition, the USB device driver

230

and the image displaying device driver

240

are included in the operating system

210

. The USB device driver

230

converts area-attribute information

251

and image-displaying-apparatus information

260

into USB data packets and vice versa in accordance with USB standards, and exchanges image-displaying-apparatus information

261

between the information processing apparatus

100

and the image displaying apparatus

110

. The image displaying device driver

240

stores data to be displayed in the display-memory unit

106

.

The USB controller

107

is controlled by the USB device driver

230

so that the USB controller

107

transmits to the image displaying apparatus

110

the inquiry into the ability of the image displaying apparatus

110

to display an image on a specific area on its display screen by changing a display attribute of the specific area, whereas the image displaying apparatus

110

transmits, in response to the inquiry, a report to the USB controller

107

indicating the capability of the image displaying apparatus

110

to so display an image.

It should be noted that, in the area-attribute information

250

and the image-displaying-apparatus information

260

, information similar to that shown in Tables 1 to 4 can be used. In addition, a non-USB means such as a DDC means can be used for exchanging the area-attribute information

250

and the image-displaying-apparatus information

260

between the information processing apparatus

100

and the image displaying apparatus

110

, as is indicated in the description of the first embodiment.

The following is a description of pieces of processing which are carried out by the application program

200

and the operating system

210

according to the present embodiment when a display attribute of a specific area on a display screen of the image displaying apparatus

110

is changed.

FIG. 28

is a flowchart showing a procedure of initialization processing carried out by the operating system

210

in the present embodiment. The initialization processing carried out by the operating system

210

modifies a display attribute carried out by the operating system

210

. The initialization begins with a step

1401

at which the power supply of the information processing apparatus

100

is turned on. As the power supply is turned on, at a step

1411

, the USB device driver

230

initializes the USB controller

107

.

The flow then proceeds to a step

1402

at which the display-attribute-change control means

211

of the operating system

210

makes the inquiry into the ability of the image displaying apparatus

110

to modify the display attribute through the USB driver

230

(that is, an inquiry into, among other things, whether a display-attribute changing means

2601

is provided in the image displaying apparatus

110

).

Receiving the inquiry, the USB driver

230

creates a packet containing the inquiry, and sends the inquiry packet to the image displaying apparatus

110

by way of the USB controller

107

as an inquiry signal at a step

2801

.

The image displaying apparatus

110

receives the inquiry signal transmitted by the information processing apparatus

100

by way of the USB controller

115

, and creates a packet containing image-displaying-apparatus information

261

to indicate that a display-attribute changing means

2601

is provided in the image displaying apparatus

110

. The packet is then sent to the information processing apparatus

100

by way of the USB controller

115

as a report signal in response to the inquiry packet.

The information processing apparatus

100

receives the report signal transmitted by the image displaying apparatus

110

by way of the USB controller

107

. In step

2801

, the USB device driver

230

of the information processing apparatus

100

receives the image-displaying-apparatus information

261

transmitted by the image displaying apparatus

110

by way of the USB controller

107

, and passes on the image-displaying-apparatus information

261

to the display-attribute-change control means

211

as image-displaying-apparatus information

262

.

At a step

1403

, the display-attribute-change control means

211

references the image-displaying-apparatus information

262

received at the step

1402

, to determine whether the image displaying apparatus

110

is capable of modifying a display attribute of a specific area. If the image displaying apparatus

110

is determined to be capable of modifying a display attribute of a specific area, the flow goes on to a step

1404

at which an attribute change flag is set to indicate that a display attribute of a specific area can be changed.

If the result of the step

1403

indicates that the image displaying apparatus

110

is not capable of modifying a display attribute of a specific area, or if no image-displaying-apparatus information

262

is transmitted from the image displaying apparatus

110

, a display attribute of a specific area is considered to be unchangeable and the initialization processing is ended without setting the attribute change flag cited above.

FIG. 29

is a flowchart showing a procedure carried out by the application program

200

to modify a display attribute in the present embodiment. The procedure is a series of operations performed by the application program

200

to modify a display attribute so as to display a window for reproducing dynamic-image data at a high contrast.

The flowchart begins with a step

1501

at which the user invokes the application program

200

for reproducing dynamic-image data. The flow then goes on to a step

1502

at which the application program

200

makes an inquiry to the operating system

210

, about a list of files in a recording medium storing dynamic-image data.

In response to the inquiry, the operating system

210

opens a file menu at a step

1511

. As the list of files storing dynamic-image data is displayed, the user selects a file storing dynamic-image data from the list.

The flow then goes on to a step

1503

, at which the application program

200

issues a draw instruction to the operating system

210

, to display a window for displaying a dynamic image. At the request made by the application program

200

, the operating system

210

requests the image displaying device driver

240

to display the window for displaying a dynamic image by using area information specified in the draw instruction, at a step

1512

. As a result, the window for displaying a dynamic image is displayed on the image displaying apparatus

110

by the image displaying device driver

240

, by storing the dynamic-image data in the display memory unit

106

at a step

2901

.

The flow then proceeds to a step

1504

at which the area-attribute-information generating means

201

of the application program

200

issues a contrast-increasing instruction to the operating system

210

, requesting the operating system

210

to increase the contrast of the window in which the dynamic image is to be displayed, at the step

1503

. More specifically, the area-attribute-information generating means

201

transfers area-attribute information

250

comprising area information specified when displaying the window, and attribute information showing a contrast value of the dynamic data specified in advance as a run-time parameter, to the image displaying apparatus

110

through the operating system

210

, in order to increase the contrast of the window for displaying the dynamic image.

At a step

1513

, the display-attribute-change control means

211

of the operating system

210

receives the contrast-increasing instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. Receiving the instruction, the area-attribute-information acquiring means

213

references the attribute change flag set at initialization and, if the image displaying apparatus

110

is capable of changing a display attribute of a specific area on a display screen thereof, area-attribute information

251

is supplied to the image displaying device driver

240

, making a request to increase the contrast of the window in which the dynamic image is to be displayed.

At the request described above, the image displaying device driver

240

sets the area-attribute information

251

used for increasing the contrast in a color-information control register, area start-position registers, and area end-position registers of the display controller

105

, at a step

2902

.

Receiving the area-attribute information

251

, the display controller

105

determines a specific area in which dynamic-image data is to be displayed by using the area judging means

2600

, sending an attribute control signal to the image displaying apparatus

110

indicating the contrast value of the specific area on the display screen of the image displaying apparatus

110

, along with an image signal conveying the dynamic-image data.

The flow then continues to a step

1505

at which the application program

200

reproduces the dynamic image in the window, the display attribute of which was modified to a high contrast value for the dynamic-image data. The flow then goes on to a step

1506

at which the application program examines whether the dynamic-image data has all been reproduced. If any dynamic-image data remains to be reproduced, the flow returns to the step

1505

. If the dynamic-image data has all been reproduced, on the other hand, the flow proceeds to a step

1507

.

After reproducing all the dynamic-image data, at the step

1507

, the area-attribute-information generating means

201

of the application program

200

generates area-attribute information

250

for returning the display attribute of the window displaying the dynamic image to the default value, and issues a default-contrast restoring instruction to the operating system

210

.

At a step

1514

, the display-attribute-change control means

211

of the operating system

210

receives the default-contrast restoring instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. After the instruction has been received, area-attribute information

251

for restoring the display attribute to the default contrast is supplied to the image displaying device driver

240

.

At the request described above, the image displaying device driver

240

sets the area-attribute information

251

used for restoring the contrast of the specified window to the default value in the color-information control register, the area start-position registers, and the area end-position registers of the display controller

105

, at a step

2903

.

The flow then goes on to a step

1508

at which the application program

200

sends an instruction to the operating system

210

to close the window in which the dynamic image was displayed. Receiving the instruction, the operating system

210

deletes the window at a step

1515

. As the window is deleted, the application program

200

terminates the procedure of reproducing the dynamic-image data.

FIG. 30

is a diagram showing the color-information control register, the area start-position registers, and the area end-position registers employed in the present embodiment. To be more specific, the color-information control register is shown in FIG.

30

(

a

), and the area start-position registers and the area end-position registers are shown in FIG.

30

(

b

). The color-information control register shown in FIG.

30

(

a

) contains attribute information indicating whether the contrasts of pieces of data to be displayed in areas

0

to

3

are to be changed. On the other hand, the area start-position registers and the area end-position registers shown in FIG.

30

(

b

) contain area information for the four areas, the attribute information for which is stored in the color-information control register shown in FIG.

30

(

a

).

The color-information control register shown in FIG.

30

(

a

) is eight bits in width, comprising four two-bit control fields for the four areas

0

to

3

. Each of the four two-bit control fields is denoted by CCX

1

and CCX

0

, where X is the area number ranging from a to

3

. For (CCX

1

, CCX

0

)=(0, 0), the control is turned off, setting the contrast of the area at an ordinary value. For (CCX

1

, CCX

0

)=(0, 1), the control is turned on, setting the contrast of the area at twice the ordinary value. For (CCX

1

, CCX

0

)=(1, 0), the control is turned on, setting the contrast of the area at three times the ordinary value. For (CCX

1

, CCX

0

)=(1, 1), the control is turned on, setting the contrast of the area at four times the ordinary value.

The area start-position registers and the area end-position registers shown in FIG.

30

(

b

) are each 32 bits in width. An area-

0

start-position register comprises a 16-bit field X

0

S representing an X-direction start position, and a 16-bit field Y

0

S representing a Y-direction start position . Area-

1

, area-

2

and area-

3

start-position registers have the same configuration as the area-

0

start-position register.

An area-

0

end-position register comprises a 16-bit field X

0

E representing an X-direction end position, and a 16-bit field Y

0

E representing a Y-direction end position. Area-

1

, area-

2

and area-

3

end-position registers have the same configuration as the area-

0

end-position register.

FIG. 31

is a diagram showing the internal configuration of the display controller

105

employed in the present embodiment. As shown in the figure, in the display controller

105

, a color-information controller

2400

generates an attribute control signal

2500

for changing a display attribute of an image signal. In the CRT display

322

which serves as the image displaying apparatus

110

, a display attribute such as the contrast can be adjusted by using the attribute control signal

2500

. In addition, display attributes such as the brightness, the chromaticity, the γ characteristic and the RGB level can also be controlled.

The attribute control signal

2500

generated from the color-information controller

2400

is transmitted to the image displaying apparatus

110

through an available signal line in a cable for transmitting an image signal. It should be noted that the attribute control signal can also be transmitted to the image displaying apparatus

110

through the USB controller

The display controller

105

includes a CPU interface controller

2100

for controlling accesses between the CPU

101

and the display controller

105

, and a display-memory interface controller

2200

for controlling accesses between the display controller

105

and the display memory unit

106

.

When data is set by the CPU

101

in the display memory unit

106

or, conversely, when data is read out by the CPU

101

from the display memory unit

106

, the data is transferred through a path between the CPU

101

and the display memory unit

106

comprising a host bus

301

, a memory controller

302

, a system bus

306

and the display controller

105

composed of the CPU interface controller

2100

and the display-memory interface controller

2200

.

In addition, the CPU interface controller

2100

also controls operations carried out by the CPU

101

to set and read out data in and from registers in the CRT controller

2300

and the color-information controller

2400

.

The CRT controller

2300

generates a horizontal synchronization signal HSYNC and a vertical synchronization signal VSYNC. In addition, the CRT controller

2300

supplies position information

2350

for reading out data to be displayed to the display-memory interface controller

2200

, and reads out raw display data

2203

, data required in displaying data, from the display memory unit

106

.

FIG. 32

is a diagram showing the internal configuration of the color-information controller

2400

employed in the present embodiment. As shown in the figure, the color-information controller

2400

is provided with area start- and end-position registers serving as storage means, in which is set the area-attribute information

251

for changing a display attribute of a specific area on the display screen of the image displaying apparatus

110

, and a color-information control register

2640

.

It should be noted that even though only the area-

0

start-position register

2610

and an area-

0

end-position register

2620

are shown in the figure, the area start- and end-position registers for the areas

1

to

3

are also provided in the same way as the area

0

.

The area-attribute information

251

coming from the CPU

101

is set in the area-

0

start- and end-position registers

2610

and

2620

, as well as the color-information control register

2640

by a data signal

2102

coming from the CPU interface controller

2100

.

Corresponding to the area judging means

2600

, a comparator

2630

compares position information

2350

coming from the CRT controller

2300

with data

2611

set in the area-

0

start-position register

2610

and data

2621

set in the area-

0

end-position register

2620

, and outputs a control signal

2631

representing a result of the comparison.

In the color-information controller

2400

, data

2641

set in the color-information register

2640

is supplied to a multiplexer

2559

and a DAC

2560

. An analog signal

2541

resulting from digital-to-analog conversion of the data

2641

by the DAC

2560

is supplied to a multiplexer

2550

. Control signals

2558

and

2551

output by the multiplexers

2559

and

2550

are supplied to a multiplexer

2650

for generating an attribute control signal

2500

. The operations of the multiplexers

2559

and

2550

are controlled by the control signal

2631

output by the comparator

2630

.

The multiplexer

2550

is controlled by the control signal

2631

to select the analog signal

2541

resulting from digital-to-analog conversion of the data

2641

set in the color-information register

2640

by the DAC

2560

, if the position information

2350

of the CRT controller

2300

is within the range of the area

0

(that is, if the area information in the X direction is equal to or greater than X

0

S and equal to or smaller than X

0

E, whereas the area information in the Y direction is equal to or greater than Y

0

S and equal to or smaller than Y

0

E), outputting the analog signal

2541

as the control signal

2551

. Otherwise, the multiplexer

2550

outputs “0”.

Similarly, the multiplexer

2559

is controlled by the control signal

2631

to select the data

2641

set in the color-information register

2640

if the position information

2350

of the CRT controller

2300

is within the range of the area

0

, (that is, if the area information in the X direction is equal to or greater than X

0

S and equal to or smaller than X

0

E, whereas the area information in the Y direction is equal to or greater than Y

0

S and equal to or smaller than Y

0

E), outputting the data

2641

as the control signal

2558

. Otherwise, the multiplexer

2550

outputs “0”.

The multiplexer

2650

selects one of the control signals

2558

and

2551

in accordance with a control signal

2700

, and outputs the selected control signal as an attribute control signal

2500

. The control signal

2700

can be fixed in advance or controlled in dependence on the type of the CRT display unit

322

connected to the information processing apparatus

100

.

FIG. 33

is a diagram showing the internal configuration of a pallet

2520

used in the present embodiment. As shown in the figure, the pallet

2520

includes a pallet RAM

2526

for storing data to be displayed in eight-bit blocks. The data to be displayed comprises 16 blocks of red data R (R

0

to R

15

), 16 blocks of green data G (G

0

to G

15

), and 16 blocks of blue data B (B

0

to B

15

). Each data block is set by a data signal

2102

generated by the CPU interface controller

2100

.

A multiplexer

2529

selects one of the red-data blocks R

0

to R

15

in accordance with four-bit raw display data

2203

, outputting the selected block as digital data

2521

. Similarly, a multiplexer

2528

selects one of the green-data blocks G

0

to G

15

in accordance with the four-bit raw display data

2203

, outputting the selected block as digital data

2522

, and a multiplexer

2527

selects one of the blue-data blocks B

0

to B

15

in accordance with the four-bit raw display data

2203

, outputting the selected block as digital data

2523

.

FIG. 34

is a diagram showing the internal configuration of the comparator

2630

. As shown in the figure, the comparator

2630

includes a comparator

2632

for comparing X-direction data of the position information

2350

with the contents X

0

S of the area-

0

start-position register

2610

. If the X-direction data of the position information

2350

is equal to or greater than the contents X

0

S of the area-

0

start-position register

2610

, the comparator

2632

sets a signal

26320

output thereby at “1”. Otherwise, the comparator

2632

sets the signal

26320

at “0”.

In addition, the comparator

2630

also includes a comparator

2633

for comparing the X-direction data of the position information

2350

with the contents X

0

E of the area-

0

end-position register

2620

. If the X-direction data of the position information

2350

is equal to or smaller than the contents X

0

E of the area-

0

end-position register

2620

, the comparator

2633

sets a signal

26330

output thereby at “1”. Otherwise, the comparator

2633

sets the signal

26330

at “0”.

Further, the comparator

2630

also includes a comparator

2634

for comparing the Y-direction data of the position information

2350

with the contents Y

0

S of the area-

0

start-position register

2610

. If the Y-direction data of the position information

2350

is equal to or greater than the contents Y

0

S of the area-

0

start-position register

2610

, the comparator

2634

sets a signal

26340

output thereby at “1”. Otherwise, the comparator

2634

sets the signal

26340

at “0”.

Furthermore, the comparator

2630

includes a comparator

2635

for comparing the Y-direction data of the position information

2350

with the contents Y

0

E of the area-

0

end-position register

2620

. If the Y-direction data of the position information

2350

is equal to or smaller than the contents Y

0

E of the area-

0

end-position register

2620

, the comparator

2632

sets a signal

26350

output thereby at “1”. Otherwise, the comparator

2632

sets the signal

26350

at “0”.

An AND gate

2636

employed in the comparator

2630

sets a signal

26361

output thereby at “1” when both the signals

26320

and

26330

are “1”, that is, when the X-direction data of the position information

2350

is equal to or greater than X

0

S and equal to or smaller than X

0

E.

Similarly, an AND gate

2637

employed in the comparator

2630

sets a signal

26371

output thereby at “1” when both the signals

26340

and

26350

are “1”, that is, when the Y-direction data of the position information

2350

is equal to or greater than Y

0

S and equal to or smaller than Y

0

E.

An AND gate

2638

employed in the comparator

2630

sets a control signal

2631

output thereby at “1” when both the signals

26361

and

26371

are “1”, that is, when the X-direction data of the position information

2350

is equal to or greater than X

0

S and equal to or smaller than X

0

E and, at the same time, the Y-direction data of the position information

2350

is equal to or greater than Y

0

S and equal to or smaller than Y

0

E. That is to say, only when the X-direction data of the position information

2350

coming from the CRT controller

2300

is equal to or greater than X

0

S and equal to or smaller than X

0

E and, at the same time, the Y-direction data of the position information

2350

is equal to or greater than Y

0

S and equal to or smaller than Y

0

E, is the control signal

2631

set to “1”.

FIG. 35

is a timing chart for the operations carried out by the color-information controller

2400

employed in the present embodiment. As shown in the figure, in the operation of the color-information controller

2400

, the attribute control signal

2500

is output in synchronization with the pieces of analog display data

2501

to

2503

. In the CRT display unit

322

, it is possible to adjust display attributes such as the contrast by using the pieces of analog display data

2501

to

2503

and the attribute control signal

2500

. In addition, other display attributes, such as the brightness, the chromaticity, the γ characteristic, and the RGB levels can also be adjusted.

In this way, a display attribute of any arbitrary area on the display screen of the image displaying apparatus can be controlled by using the area-

0

start-position register

2610

, the area-

0

end-position register

2620

, and the color-information control register

2640

.

So far, the image displaying system implemented by the present embodiment has been explained by focusing only on the area

0

. It should be noted that display attributes of a plurality of arbitrary areas

1

,

2

, and

3

can also each be controlled by using an area start-position register, an area end-position register, and the color-information control register

2640

, in the same way as the area

0

.

FIG. 36

is a diagram showing a preferred implementation of the image displaying apparatus

110

provided by the present embodiment. More particularly, the figure shows a preferred implementation of a display-attribute changing means

2601

employed in the image displaying apparatus

110

for changing a display attribute of an image signal on the image-displaying apparatus side. As shown in the figure, the attribute control signal

2500

transmitted from the information processing apparatus

100

by way of a buffer/DAC

3600

is supplied to the variable power supply

2306

. The variable power supply

2306

is controlled by the attribute control signal

2500

.

When the attribute control signal

2500

for a specific area on a display screen of the image displaying apparatus

110

, in which data is to be displayed, is received from the information processing apparatus

100

, the display-attribute changing means

2601

employed in the image displaying apparatus

110

changes a display attribute of only the specific area. For example, the display-attribute changing means

2601

increases the contrast of the image B.

As described above, according to the image displaying apparatus implemented by the present embodiment, the information processing apparatus

100

determines data to be displayed in a specific area on a display screen of the image displaying apparatus

110

, transmitting an image signal and the attribute control signal

2500

for the image signal to the image displaying apparatus

110

, whereby a display attribute of the data to be displayed is changed. As a result, processing to modify a display attribute of a specific area on a display screen of the image displaying apparatus

110

can be distributed among the information processing apparatus

100

and the image displaying apparatus

110

.

Third Embodiment

The following is a description of an image displaying system implemented by a third embodiment of the invention. In this third embodiment, after the attribute information is developed and stored as attribute data, the data to be displayed and the attribute data for the data to be displayed are read out from the display memory unit and transferred from the information processing apparatus to the image displaying apparatus for display of the data to be displayed in the specific area, by modifying a display attribute of the specific area.

FIG. 37

is a diagram showing the configuration of the image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system comprises an information processing apparatus

100

provided with a display memory unit

106

for storing data to be displayed and attribute data, and an image displaying apparatus

110

having a display-attribute changing means

2601

for changing a display attribute of an image signal. The image displaying apparatus

110

is connected to the information processing apparatus

100

.

In the image displaying system implemented by the present embodiment, the display controller

105

employed in the information processing apparatus

100

reads out data to be displayed and attribute data from the display memory unit

106

, transmitting an image signal and an attribute control signal

2500

from the information processing apparatus

100

to the image displaying apparatus

110

. In the image displaying apparatus

110

, the data is displayed after the display-attribute changing means

2601

changes the display attribute.

The CPU

101

employed in the image processing apparatus

100

controls the entire information processing apparatus

100

. More specifically, the CPU

101

controls the information processing apparatus

100

as a whole by actually interpreting and executing an application program

200

, an operating system

210

, and a group of programs such as a USB device driver

230

and an image displaying device driver

240

, which are loaded into the main memory unit

102

.

In addition, the information processing apparatus

100

includes an HDD

103

for storing software such as the application program

200

, the operating system

210

, a GUI program, an API program, the USB device driver

230

, and the image displaying device driver

240

. The information processing apparatus

100

is also provided with a DVD

104

for storing texts as well as display data of static and dynamic images to be displayed on the image displaying apparatus

110

.

Further, the information processing apparatus

100

also has a display controller

105

and a display memory unit

106

. The display controller

105

controls a write operation for writing data to be displayed on the image displaying apparatus

110

into the display memory unit

106

, and a read operation for reading out the data from the display memory unit

106

as an image signal to be transmitted to the image displaying apparatus

110

. An attribute control signal

2500

for modifying a display attribute contained in the image signal is generated from attribute data which has been developed in the display memory unit

106

on the basis of area-attribute information

251

. The attribute control signal

2500

is also transmitted to the image displaying apparatus

110

.

The display memory unit

106

employed in the information processing apparatus

100

includes a storage portion in which attribute information in a specific area on a display screen of the image displaying apparatus

110

is developed. The specific area is indicated by the area-attribute information

251

for changing a display attribute of the specific area.

The information processing apparatus

100

is also provided with a USB controller

107

for transmitting an inquiry signal to the image displaying apparatus

110

and receiving a report signal, in response to the inquiry signal, from the image displaying apparatus

110

.

The image displaying apparatus

110

comprises a CPU

111

and a ROM

112

. The CPU

111

controls the image displaying apparatus

110

as a whole by interpretation and execution of a control program stored in a storage area of the ROM

112

. It should be noted that the control program itself is not shown in the figure.

The ROM

112

employed in the image displaying apparatus

110

stores information on the image displaying apparatus

110

. This information indicates whether the image displaying apparatus

110

has a display-attribute changing means

2601

, (that is, whether the image displaying apparatus

110

has the capability of displaying an image on a specific area on the display screen thereof by changing a display attribute of the specific area). The display-attribute changing means

2601

changes a display attribute of an image signal input to the image displaying apparatus

110

in accordance with an attribute control signal.

In addition, the image displaying apparatus

110

also employs a USB controller

115

, which serves as a counterpart of the USB controller

107

employed in the information processing apparatus

100

. More specifically, the USB controller

115

receives an inquiry signal from the information processing apparatus

100

and transmits a report signal, in response to the inquiry signal, to the information processing apparatus

100

. The inquiry signal is used to determine whether the image displaying apparatus

110

can display an image on a specific area on the display screen thereof by changing a display attribute of the specific area in accordance with USB standards.

FIG. 38

is a diagram showing an outline of a procedure carried out by the image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system has an image displaying device driver

240

and an area judging means

3800

in the information processing apparatus

100

, in addition to a display-attribute changing means

2601

for changing a display attribute in accordance with an image signal and an attribute control signal in the image displaying apparatus

110

. The area judging means

3800

and the display-attribute changing means

2601

correspond to the specific-area display-attribute changing means

113

.

The application program

200

in the information processing apparatus

100

comprises a GUI, which is visible to the operator who operates the information processing apparatus

100

, and which serves as an interface with the operating system

210

.

The operating system

210

in the information processing apparatus

100

is a basic program serving as the nucleus of the image displaying system. More specifically, the operating system

210

connects the application program

200

with program members directly controlling hardware such as a USB device driver

230

and the image displaying device driver

240

.

The image displaying device driver

240

in the information processing apparatus

100

is positioned between the operating system

210

and hardware members such as the device controller

105

and the display memory unit

106

. More specifically, the image displaying device driver

240

is a program which implements a draw instruction issued by the operating system

210

by reading out and writing information from and into internal registers of the display controller

105

and the display memory unit

106

. It should be noted that the internal registers themselves are not shown in the figure.

The application program

200

is provided with an area-attribute-information generating means

201

. When there is detected a need to change a display attribute of a specific area on the display screen of the image displaying apparatus

110

, area-attribute information

250

for changing the display attribute of the specific area is generated in the application program

200

and passed to the operating system

210

by the area-attribute-information generating means

201

.

The operating system

210

comprises display-attribute-change control means

211

, area-attribute-information generating means

212

, and area-attribute-information acquiring means

213

. The display-attribute-change control means

211

controls the entire display-attribute-change processing of the information processing apparatus

100

by making an inquiry about an ability of the image displaying apparatus

110

to display an image on a specific area on the display screen thereof by changing a display attribute of the specific area and receiving a response to the inquiry. The area-attribute-information generating means

212

generates area-attribute information

251

in the operating system

210

when there is detected a need to change a display attribute of the specific area. The area-attribute-information acquiring means

213

acquires the area-attribute information

250

generated by the area-attribute-information generating means

201

of the application program

200

.

In addition, the USB device driver

230

and the image displaying device driver

240

are included in the operating system

210

. The USB device driver

230

converts area-attribute information

251

and image-displaying-apparatus information

260

into USB data packets and vice versa in accordance with USB standards, and exchanges image-displaying-apparatus information

261

between the information processing apparatus

100

and the image displaying apparatus

110

. The image displaying device driver

240

stores data to be displayed in the display-memory unit

106

.

The USB controller

107

is controlled by the USB device driver

230

so that the inquiry about the ability of the image displaying apparatus

110

to display an image on a specific area on its display screen by changing a display attribute of the specific area is transmitted from the USB controller

107

to the image displaying apparatus

110

, whereas a report indicating the ability of the image displaying apparatus

110

to display such an image on a specific area on the display screen thereof is also received by the USB controller

107

in response to such an inquiry.

The area judging means

3800

employed in the image displaying device driver

240

forms a judgment as to whether display data stored in the display memory unit

106

is of a specific area, a display attribute of which is to be changed, on the display screen of the image displaying apparatus

110

based on the area-attribute information

251

. If the display data stored in the display memory unit

106

is of such a specific area, the area judging means

3800

stores attribute data in a storage portion at a specific address in the display memory unit

106

associated with the data to be displayed. In the storage portion, the area-attribute information

251

for changing a display attribute of the specific area on the display screen of the image displaying apparatus

110

is developed.

It should be noted that, in the area-attribute information

250

and the image-displaying-apparatus information

260

of the image displaying system implemented by the present embodiment, information similar to that shown in Tables 1 to 4 can be used. In addition, as a communication means for exchanging the area-attribute information

250

and the image-displaying-apparatus information

260

between the information processing apparatus

100

and the image displaying apparatus

110

, a non-USB means such as a DDC means can be used as is shown in the description of the first embodiment.

The following is a description of pieces of processing which are carried out by the application program

200

and the operating system

210

in the image displaying system implemented by the present embodiment when a display attribute of a specific area on a display screen of the image displaying apparatus

110

is changed. It should be noted that the initialization carried out by the operating system

210

is the same as that of the second embodiment.

FIG. 39

is a flowchart showing a procedure carried out by the application program

200

in the present embodiment to modify a display attribute. The procedure carried out by the application program

200

is a series of operations to increase the contrast of a window for displaying a dynamic image reproduction of the dynamic-image data by the application program

200

.

The procedure begins with a step

1501

at which the user invokes the application program

200

for reproducing the dynamic-image data. The flow then goes on to a step

1502

at which the application program

200

makes an inquiry to the operating system

210

about a list of files in a recording medium storing dynamic-image data.

In response to the inquiry, the operating system

210

opens a file menu at a step

1511

. As the list of files storing dynamic-image data are displayed, the user selects a file from the list that the user wants to reproduce.

The flow then goes on to a step

1503

at which the application program

200

issues a draw instruction requesting the operating system

210

to display a window for displaying a dynamic image. At the request made by the application program

200

, the operating system

210

requests the image displaying device driver

240

to display the window by using area information specified in the draw instruction, at a step

1512

. As a result, the window is displayed on the image displaying apparatus

110

by the image displaying device driver

240

by storing the dynamic-image data in the display memory unit

106

, at a step

2901

.

The flow then proceeds to a step

1504

at which the area-attribute-information generating means

201

of the application program

200

issues a contrast-increasing instruction to the operating system

210

, requesting the operating system

210

to increase the contrast of the window in which the dynamic image is to be displayed. More specifically, the area-attribute-information generating means

201

transfers area-attribute information

250

comprising area information specified when displaying the window and attribute information showing a contrast value of the dynamic data specified in advance as a run-time parameter, to the image displaying apparatus

110

through the operating system

210

, in order to increase the contrast of the window in which the dynamic image is to be displayed.

At a step

1513

, the display-attribute-change control means

211

of the operating system

210

receives the contrast-increasing instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. Receiving the instruction, the area-attribute-information acquiring means

213

references the attribute change flag set at initialization and, if the image displaying apparatus

110

is capable of changing a display attribute of a specific area on its display screen, area-attribute information

251

is supplied to the image displaying device driver

240

, making a request to increase the contrast of the window for displaying a dynamic image to the image displaying device driver

240

.

At the request described above, the area judging means

3800

of the image displaying device driver

240

determines the specific area for displaying dynamic-image data, develops attribute information indicating a contrast value of the specific area in the display memory unit

106

for the dynamic-image data, and stores the attribute data at a step

3901

. The display controller

105

reads out the attribute data developed in the display memory unit

106

, and transfers the attribute data to the image displaying apparatus

110

along with the dynamic-image data.

The flow then continues to a step

1505

at which the application program

200

reproduces the dynamic image on the specified window, the display attribute of which was modified to a high contrast value for the dynamic-image data. The flow then goes on to a step

1506

at which the application program examines whether the dynamic-image data has all been reproduced. If any dynamic-image data remains to be reproduced, the flow returns to the step

1505

. If the dynamic-image data has all been reproduced, on the other hand, the flow proceeds to a step

1507

.

After reproducing all the dynamic-image data, at the step

1507

, the area-attribute-information generating means

201

of the application program

200

generates area-attribute information

250

for returning the display attribute of the window displaying the dynamic image to the default value, issuing a default-contrast restoring instruction to the operating system

210

.

At a step

1514

, the display-attribute-change control means

211

of the operating system

210

receives the default-contrast restoring instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. Receiving the instruction, area-attribute information

251

for restoring the display attribute to the default contrast is supplied to the image displaying device driver

240

, making a request to the image displaying device driver

240

to carry out restoration of the display attribute to the default value (that is, to restore the display attribute of the specified window to the default contrast).

At the request described above, the image displaying device driver

240

develops attribute information indicating the default contrast value of the specific area in a storage portion of the display memory unit

106

for the dynamic-image data, stores the attribute data, and restores the contrast of the specified window to the default value, at a step

3902

.

The flow then goes on to a step

1508

at which the application program

200

sends an instruction to the operating system

210

to close the window in which the dynamic image was displayed. Receiving the instruction, the operating system

210

deletes the window at the step

1515

. As the window is deleted, the application program

200

terminates the procedure of reproducing the dynamic-image data.

In the image displaying system implemented by the present embodiment, attribute data resulting from development of attribute information stored in the color-information control register

2640

in the second embodiment is stored in the display memory unit

106

along with the corresponding data to be displayed. Representative layouts of the data to be displayed and the attribute data stored in the display memory unit

106

are a plane system like that shown in

FIG. 40

, and a packed-pixel system like that shown in FIG.

41

.

FIG. 40

is a diagram showing the plane system of the layout of the data to be displayed and the attribute data stored in the display memory unit

106

in the present embodiment. As shown in the figure, the display memory unit

106

has a storage portion in which display data and attribute data of a picture element are laid out in the depth direction. For example, four-bit display data (P

00

, P

01

, P

02

and P

03

) and two-bit attribute data (C

00

and C

01

) pertain to a picture element, whereas four-bit display data (P

10

, P

11

, P

12

and P

13

) and two-bit attribute data (C

10

and C

11

) pertain to an adjacent picture element. Thus, each picture element comprises a total of six bits.

FIG. 41

is a diagram showing the packed-pixel system of the layout of the data to be displayed and the attribute data stored in the display memory unit

106

in the present embodiment. As shown in the figure, the display memory unit

106

has a storage portion in which display data and attribute data of a picture element are laid out contiguously in the width direction. For example, four-bit display data (p

00

, P

01

, P

02

and P

03

) and two-bit attribute data (C

00

and C

01

) pertain to a picture element, whereas four-bit display data (P

10

, P

11

, P

12

and P

13

) and two-bit attribute data (C

10

and C

11

) pertain to an adjacent picture element. Thus, each picture element comprises a total of six bits.

If the user wants to change display attributes, such as the contrast and the sharpness of the image displaying apparatus

110

(which may be either a CRT display unit

322

or a liquid-crystal display unit

323

), display data (P

00

, P

01

etc.) and attribute data (C

00

, C

01

etc.) are developed in the memory display unit

106

by using the area judging means

3800

of the image displaying device driver

240

of the operating system

210

.

FIG. 42

is a diagram showing the internal configuration of the display controller

105

employed by the present embodiment. As shown in the figure, attribute data

2202

is input from the display memory unit

106

and attribute control information

2500

is generated by the color-information controller

2400

. In the CRT display unit

322

(which serves as the image displaying apparatus

110

in the present example), it is possible to adjust display attributes, such as the contrast, by using the attribute control signal

2500

. In addition, other display attributes, such as the brightness, the chromaticity, the γ characteristic, and the RGB levels, can be adjusted as well.

The attribute control signal

2500

generated from the color-information controller

2400

is transmitted to the image displaying apparatus

110

through an available signal line in a cable for transmitting an image signal. It should be noted that the attribute control signal can also be transmitted to the image displaying apparatus

110

through the USB controller

107

.

The CRT controller

2300

generates a horizontal synchronization signal HSYNC and a vertical synchronization signal VSYNC. In addition, the CRT controller

2300

supplies position information

2350

for reading out data to be displayed to the display-memory interface controller

2200

, and reads out raw display data

2203

, data required in displaying data, and attribute data

2202

from the display memory unit

106

.

FIG. 43

is a diagram showing the internal configuration of the color-information controller

2400

employed in the present embodiment. As shown in the figure, in the color-information controller

2400

, either an analog signal

2541

resulting from digital-to-analog conversion of the attribute data

2202

by a DAC

2560

or the attribute data

2202

is selected by a multiplexer

2550

, which outputs the selected one as an attribute control signal

2500

.

The multiplexer

2550

selects one of the signals in accordance with a control signal

2700

. The control signal

2700

can be fixed in advance or controlled by information on the type of the CRT display unit

322

connected to the information processing apparatus

100

.

FIG. 44

is an operational timing chart of the color-information controller

2400

employed in the present embodiment. As shown in the figure, in the operation of the color-information controller

2400

, the attribute control signal

2500

is output in synchronization with the pieces of analog display data

2501

to

2503

. In the CRT display unit

322

connected to the information processing apparatus

110

, it is possible to adjust display attributes, such as the contrast, by using the pieces of analog display data

2501

to

2503

and the attribute control signal

2500

. In addition, other display attributes, such as the brightness, the chromaticity, the γ characteristic, and the RGB levels, can also be adjusted.

In addition, in the image displaying system implemented by the present embodiment, an image displaying apparatus

110

like that of

FIG. 36

provided by the second embodiment can be used as well.

As described above, according to the image displaying system implemented by the present embodiment, the information processing apparatus

100

forms a judgment as to whether or not data to be displayed exists in a specific area on a display screen of the image displaying apparatus

110

, and attribute data

2202

for the data to be displayed is stored in the display memory unit

106

, making it possible to control a display attribute for each pixel. In addition, since the data to be displayed and the attribute data

2202

are treated on the same column, the amount of restriction on the expression of the designer who creates a raw image of the data to be displayed is decreased.

In addition, according to the image displaying system implemented by the present embodiment, when the position at which data is displayed is moved, the attribute data

2202

for the displayed data is just moved along with the displayed data without the need to form a judgment as to whether the displayed data exists in a specific area on a display screen of the image displaying apparatus

110

, making it possible to move at a high speed the data displayed in the specific area whose display attribute has been changed.

Further, according to the image displaying system implemented by the present embodiment, the attribute data

2202

for the data to be displayed is stored in a storage portion of the display memory unit

106

. As a result, the attribute data

2202

can be stored without newly providing a storage means for the attribute data

2202

.

Fourth Embodiment

The following is description of an image displaying system implemented by a fourth embodiment, wherein a display attribute of a specific area on a display screen of an image displaying apparatus is changed by an information processing apparatus, and an image signal with a changed display attribute is displayed by the image displaying apparatus.

FIG. 45

is a diagram showing the configuration of an image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system comprises an image displaying apparatus and an information processing apparatus

100

provided with a specific-area-display-attribute changing means

4500

for changing a display attribute of a specific area on a display screen of the image displaying apparatus

110

, which has a modified display attribute in a specific area, and displaying the image signal. The image displaying apparatus

110

is connected to the information processing apparatus

100

.

In the image displaying system implemented by the present embodiment, after the specific-area-display-attribute changing means

4500

employed in the display controller

105

has changed a display attribute for a specific area on a display screen of an image displaying apparatus

110

, an image signal is transmitted from the information processing apparatus

100

to the image displaying apparatus

110

for displaying the image signal.

The CPU

101

employed in the image processing apparatus

100

controls the entire information processing apparatus

100

. More specifically, the CPU

101

controls the information processing apparatus

100

as a whole by actually interpreting and executing an application program

200

, an operating system

210

, and a group of programs such as a USB device driver

230

and an image displaying device driver

240

, which are loaded into the main memory unit

102

.

In addition, the information processing apparatus

100

also includes an HDD

103

for storing software such as the application program

200

, the operating system

210

, a GUI program, an API program, the USB device driver

230

, and the image displaying device driver

240

. The information processing apparatus

100

is also provided with a DVD

104

for storing texts as well as display data of static and dynamic images to be displayed on the image displaying apparatus

110

.

Further, the information processing apparatus

100

also has a display controller

105

and a display memory unit

106

. The display controller

105

controls a write operation for writing data to be displayed on the image displaying apparatus

110

into the display memory unit

106

, and controls a read operation for reading out the data from the display memory unit

106

as an image signal to be transmitted to the image displaying apparatus

110

. The display controller

105

has a plurality of registers serving as a storage means in which area-attribute information

251

for changing a display attribute of a specific area on the display screen of the image displaying apparatus

110

is set. The display controller

105

transmits an image signal with a display attribute thereof changed on the basis of the area-attribute information

251

to the image displaying apparatus

110

.

Finally, the information processing apparatus

100

is also provided with a USB controller

107

for transmitting an inquiry signal to the image displaying apparatus

110

and for receiving a report signal, in response to the inquiry signal, from the image displaying apparatus

110

.

The image displaying apparatus

110

comprises a CPU

111

and a ROM

112

. The CPU

111

is a processor for controlling the image displaying apparatus

110

as a whole by interpretation and execution of a control program stored in a storage area of the ROM

112

. It should be noted that the control program itself is not shown in the figure.

The ROM

112

employed in the image displaying apparatus

110

stores information

260

on the image displaying apparatus

110

. Such information indicates whether the image displaying apparatus

110

has a capability of displaying an image on a specific area on the screen thereof by changing a display attribute of the specific area.

In addition, the image displaying apparatus

110

also employs a USB controller

115

, which serves as a counterpart of the USB controller

107

employed in the information processing apparatus

100

. More specifically, the USB controller

115

receives the inquiry signal from the information processing apparatus

100

and transmits a report signal, in response to the inquiry signal, to the information processing apparatus

100

. The inquiry signal is used to determine whether the image displaying apparatus

110

can display an image on a specific area on the display screen thereof by changing a display attribute of the specific area in accordance with USB standards.

FIG. 46

is a diagram showing an outline of a procedure carried out by the image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system has the specific-area-display-attribute changing means

4500

provided in the information processing apparatus

100

for changing a display attribute of a specific area on the display screen of the image displaying apparatus

110

.

The application program

200

in the information processing apparatus

100

comprises a GUI, which is visible to the operator who operates the information processing apparatus

100

, and which serves as an interface with the operating system

210

.

The operating system

210

in the information processing apparatus

100

is a basic program serving as the nucleus of the image displaying system. More specifically, the operating system

210

connects the application program

200

with program members directly controlling hardware such as a USB device driver

230

and the image displaying device driver

240

.

The image displaying device driver

240

in the information processing apparatus

100

is positioned between the operating system

210

and hardware members such as the device controller

105

and the display memory unit

106

. More specifically, the image displaying device driver

240

is a program which implements a draw instruction issued by the operating system

210

by reading out and writing information from and into internal registers of the display controller

105

and the display memory unit

106

. It should be noted that the internal registers themselves are not shown in the figure.

The application program

200

in the information processing apparatus

100

is provided with an area-attribute-information generating means

201

. When there is detected a need to change a display attribute of a specific area on the display screen of the image displaying apparatus

110

, area-attribute information

250

for changing the display attribute of the specific area is generated in the application program

200

and passed to the operating system

210

by the area-attribute-information generating means

201

.

The operating system

210

in the information processing apparatus

100

comprises display-attribute-change control means

211

, area-attribute-information generating means

212

, and area-attribute-information acquiring means

213

. The display-attribute-change control means

211

controls the entire display-attribute-change processing of the information processing apparatus

100

by making an inquiry about an ability of the image displaying apparatus

110

to display an image on a specific area on the display screen thereof by changing a display attribute of the specific area, and by receiving a response to the inquiry. The area-attribute-information generating means

212

generates area-attribute information

251

in the operating system

210

when there is detected a need to change a display attribute of the specific area. The area-attribute-information acquiring means

213

acquires the area-attribute information

250

generated by the area-attribute-information generating means

201

of the application program

200

.

In addition, the USB device driver

230

and the image displaying device driver

240

are included in the operating system

210

. The USB device driver

230

converts area-attribute information

251

and image-displaying-apparatus information

260

into USB data packets and vice versa in accordance with USB standards, and exchanges image-displaying-apparatus information

261

between the information processing apparatus

100

and the image displaying apparatus

110

. The image displaying device driver

240

stores data to be displayed in the display-memory unit

106

.

The USB controller

107

is controlled by the USB device driver

230

so that the inquiry is transmitted from the USB controller

107

to the image displaying apparatus

110

. Then, a report indicating the ability of the image displaying apparatus

110

to display an image on the specific area on the display screen thereof by changing a display attribute of the specific area is transmitted by the image displaying apparatus

110

in response to the inquiry and received by the USB controller

107

.

It should be noted that, in the area-attribute information

250

and the image-displaying-apparatus information

260

of the image displaying system implemented by the present embodiment, information similar to that shown in Tables 1 to 4 can be used. In addition, as a communication means for exchanging the area-attribute information

250

and the image-displaying-apparatus information

260

between the information processing apparatus

100

and the image displaying apparatus

110

, a non-USB means such as a DDC means can be used, as is shown in the description of the first embodiment.

The following is a description of pieces of processing which are carried out by the operating system

210

in the image displaying system implemented by the present embodiment when a display attribute of a specific area is changed. It should be noted that the processing carried out by the application program

200

to change a display attribute is the same as that performed by the second embodiment.

FIG. 47

is a flowchart showing a procedure of initialization processing carried out by the operating system

210

in the present embodiment. The initialization processing carried out by the operating system

210

modifies a display attribute carried out by the operating system

210

. The initialization begins with a step

1401

at which the power supply of the information processing apparatus

100

is turned on. After the power supply is turned on, at a step

1411

, the USB device driver

230

initializes the USB controller

107

.

The flow then proceeds to a step

1402

at which the display-attribute-change control means

211

of the operating system

210

makes an inquiry, to the image displaying apparatus

110

through the USB driver

230

, about the capability of displaying, among other things, a maximum allowable input voltage indicating whether the image displaying apparatus

110

is capable of displaying an image signal with a modified display attribute in a specific area on a display screen thereof.

Receiving the inquiry, the USB driver

230

creates a packet containing the inquiry, and sends the inquiry packet to the image displaying apparatus

110

by way of the USB controller

107

at a step

4701

.

The image displaying apparatus

110

receives the inquiry signal transmitted by the information processing apparatus

100

by way of the USB controller

115

, and creates a packet containing image-displaying-apparatus information

261

to indicate that the image displaying apparatus

110

is capable of displaying an image in a specific area on the display screen thereof by modifying a display attribute of the specific area. The packet is sent to the information processing apparatus

100

by way of the USB controller

115

as a report signal in response to the inquiry packet.

The information processing apparatus

100

receives the report signal transmitted by the image displaying apparatus

110

by way of the USB controller

107

. At the step

4701

, the USB device driver

230

of the information processing apparatus

100

receives the image-displaying-apparatus information

261

transmitted by the image displaying apparatus

110

by way of the USB controller

107

, passing on the image-displaying-apparatus information

261

to the display-attribute-change control means

211

as image-displaying-apparatus information

262

.

At a step

1403

, the display-attribute-change control means

211

references the image-displaying-apparatus information

262

received at the step

1402

to find out whether or not the image displaying apparatus

110

is capable of displaying an image signal with a modified display attribute for a specific area on a display screen of the image displaying apparatus

110

. If the image displaying apparatus

110

is found out to be so capable, the flow goes on to a step

1404

at which an attribute change flag is set to indicate that an image signal with a modified display attribute in a specific area on a display screen of the image displaying apparatus

110

can be input.

If, on the other hand, a result of the examination of the image-displaying-apparatus information

262

carried out at the step

1403

indicates that the image displaying apparatus

110

is not capable of displaying an image signal with a modified display attribute of a specific area on a display screen thereof, or if no image-displaying-apparatus information

262

is transmitted from the image displaying apparatus

110

, a display attribute of a specific area on the display screen of the image displaying apparatus

110

is considered to be unchangeable and the initialization processing is ended without setting the attribute change flag cited above.

After the initialization has been completed, the display-attribute-change control means

211

of the operating system

210

receives the contrast-increasing instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. Receiving the instruction, the area-attribute-information acquiring means

213

references the attribute change flag set at the initialization and, if the image displaying apparatus

110

is capable of changing a display attribute of a specific area on its display screen, area-attribute information

251

is supplied to the image displaying device driver

240

, making a request to increase the contrast of the window for displaying a dynamic image.

At the request described above, the image displaying device driver

240

sets the area-attribute information

251

used for increasing the contrast values stored in registers employed in the display controller

105

. In the display controller

105

, the received area-attribute information

251

is used by the specific-area-display-attribute changing means

4500

for determining a specific area on the display screen of the image displaying apparatus

110

for displaying dynamic-image data, and for changing the contrast value of the specific area. An image signal with the display attribute thereof modified in the specific area is then transmitted to the image displaying apparatus

110

.

FIG. 48

is a diagram showing the internal configuration of the display controller

105

provided by the present embodiment. As shown in the figure, in the display controller

105

, raw display data

2203

and position information

2350

are supplied to the color-information controller

2400

corresponding to the special-area-display-attribute changing means

4500

. In the color-information controller

2400

, display attributes, such as the contrast, can be adjusted. In addition, other display attributes, such as the brightness, the chromaticity, the γ characteristic, and the RGB levels, can also be adjusted.

The CRT controller

2300

generates a horizontal synchronization signal HSYNC and a vertical synchronization signal VSYNC. In addition, the CRT controller

2300

supplies the position information

2350

for reading out data to be displayed to the display-memory interface controller

2200

and reads out raw display data

2203

, data required in displaying data, from the display memory unit

106

.

FIG. 49

is a diagram showing the internal configuration of the color-information controller

2400

employed in the present embodiment. As shown in the figure, the color-information controller

2400

is provided with an area start-position register, an area end-position register, and a color-information control register

2640

. The area start-position register and the area end-position register are used for setting the area-attribute information

251

for modifying a display attribute of a specific area on the display screen.

So far, the image displaying system implemented by the present embodiment has been explained by showing only the area start-position register

2610

and the area end-position register

2620

of the area

0

. It should be noted that, for each of a plurality of arbitrary areas

1

,

2

, and

3

, an area start-position register and an area end-position register can be provided in the same way as for the area

0

.

The area-attribute information

251

coming from the CPU

101

is set in the area-

0

start-position register

2610

, the area-

0

end-position register

2620

, and the color-information control register

2640

by a data signal

2102

coming from the CPU interface controller

2100

.

A comparator

2630

compares the position information

2350

coming from the CRT controller

2300

with data

2611

set in the area-

0

start-position register

2610

and data

2621

set in the area-

0

end-position register

2620

, outputting a control signal

2631

as a result of the comparison.

FIG. 50

shows timing charts of operations of the color-information controller

2400

employed in the present embodiment. As shown in the figure, in an operation of the color-information controller

2400

, a multiplexer

2650

selects either data

2641

set in the color-information control register

2640

or “0” in accordance with the value of the control signal

2631

, outputting the selected one as a control signal

2651

.

More specifically, only when the position information

2350

coming from the CRT controller

2300

is in the range of the area

0

, that is, only when the X-direction data of the position information

2350

coming from the CRT controller

2300

is equal to or greater than X

0

S and equal to or smaller than X

0

E and, at the same time, the Y-direction data of the position information

2350

is equal to or greater than Y

0

S and equal to or smaller than Y

0

E, does the control signal

2631

drive the multiplexer

2650

to select the data

2641

set in the color-information control register

2640

as the control signal

2651

. Otherwise, the multiplexer

2650

selects “0”.

Therefore, when area-

0

control bits (CC

00

, CCO

1

) of the color-information register

2640

are set at (0, 1), the control signal

2651

is

01

B if the position information

2350

coming from the CRT controller

2300

is in the range of the area

0

, and

00

B otherwise.

An amplifier

2540

determines whether or not to amplify analog signals

2531

to

2533

in dependence on the value of the control signal

2651

.

If the position information

2350

coming from the CRT controller

2300

is in the range of the area

0

, the control signal

2651

is

01

B as described above. In this case, the analog signals

2531

to

2533

are amplified by the amplifier

2540

at an amplification factor of 2.

If, on the other hand, the position information

2350

coming from the CRT controller

2300

is not in the range of the area

0

, the control signal

2651

is

00

B as described above. In this case, the analog signals

2531

to

2533

are not amplified by the amplifier

2540

but just passed on as analog display signals

2501

to

2503

as they are.

As described above, the contrast of any arbitrary area can be controlled by using the area-

0

start-position register

2610

, the area-

0

end-position register

2620

, and the color-information control register

2640

. In addition, other display attributes such as the brightness, the chromaticity, the γ characteristic, and the RGB levels can be adjusted as well.

It should be noted that, in the image displaying system implemented by the present embodiment, display attributes of a plurality of arbitrary areas

1

,

2

, and

3

can also each be controlled by using an area start-position register, an area end-position register, and the color-information control register

2640

in the same way as the area

0

.

FIG. 51

is a diagram showing a preferred implementation of the image displaying apparatus

110

provided by the present embodiment. As shown in the figure, the image displaying apparatus

110

inputs and then displays an image signal with a display attribute thereof changed in a specific area on a display screen thereof. Since the image displaying apparatus

110

merely displays an image signal with a display attribute thereof changed by the information processing apparatus

100

, it can be any apparatus as long as it is capable of displaying an image signal with a display attribute thereof changed in a specific area on its display screen.

As described above, according to the image displaying system implemented by the present embodiment, a display attribute of a specific area on a display screen of the image displaying apparatus

110

is changed by the information processing apparatus

100

, and an image signal with a display attribute thereof changed in the specific area is then transmitted by the information processing apparatus

100

to the image displaying apparatus

110

. It is thus possible to display an image signal with a display attribute thereof changed in a specific area on a display screen by using the image displaying apparatus

110

.

Fifth Embodiment

The following is a description of an image displaying system implemented by a fifth embodiment of the invention. In this fifth embodiment, after attribute data has been stored in a storage portion of a display memory unit for data to be displayed in a specific area on a display screen of an image displaying apparatus, an information processing apparatus reads out the data to be displayed along with its attribute data, and changes the display attribute of the specific area. Then, the image displaying apparatus displays an image signal with a display attribute thereof changed in the specific area.

FIG. 52

is a diagram showing the configuration of an image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system comprises an information processing apparatus

100

provided with a display-memory unit

106

for storing data to be displayed and attribute data, an image displaying apparatus

110

for receiving an image signal which has a modified display attribute in a specific area to be displayed on a display screen of the image displaying apparatus

110

, and display-attribute changing means

5200

for changing a display attribute of a specific area on a display screen of the image displaying apparatus

110

in accordance with the attribute data. The image displaying apparatus

110

is connected to the information processing apparatus

100

.

In the image displaying system implemented by the present embodiment, after a display controller

105

employed in the information processing apparatus

100

reads out the data to be displayed and its attribute data from the display memory unit

106

and the display-attribute changing means

5200

changes a display attribute for a specific area on the display screen of the image displaying apparatus

110

, the image signal is transmitted from the information processing apparatus

100

to the image displaying apparatus

110

for displaying the image signal.

The CPU

101

employed in the image processing apparatus

100

controls the entire information processing apparatus

100

. More specifically, the CPU

101

controls the information processing apparatus

100

as a whole by actually interpreting and executing an application program

200

, an operating system

210

, and a group of programs such as a USB device driver

230

and an image displaying device driver

240

, which are loaded into the main memory unit

102

.

In addition, the information processing apparatus

100

also includes an HDD

103

for storing software such as the application program

200

, the operating system

210

, a GUI program, an API program, the USB device driver

230

, and the image displaying device driver

240

. The information processing apparatus

100

is also provided with a DVD

104

for storing texts as well as display data of static and dynamic images to be displayed on the image displaying apparatus

110

.

Further, the information processing apparatus

100

also has a display controller

105

and a display memory unit

106

. The display controller

105

controls a write operation for writing data to be displayed on the image displaying apparatus

110

into the display memory unit

106

, and a read operation for reading out the data from the display memory unit

106

as an image signal to be transmitted to the image displaying apparatus

110

. The display controller

105

has a plurality of registers serving as a storage means in which area-attribute information

251

for changing a display attribute of a specific area on the display screen is set. The display controller

105

transmits to the image displaying apparatus

110

an image signal with a display attribute thereof changed on the basis of the area-attribute information

251

.

Finally, the information processing apparatus

100

is also provided with a USB controller

107

for transmitting an inquiry signal to the image displaying apparatus

110

and for receiving a report signal, in response to the inquiry signal, from the image displaying apparatus

110

.

On the other hand, the image displaying apparatus

110

comprises a CPU

111

and a ROM

112

. The CPU

111

controls the image displaying apparatus

110

as a whole by interpretation and execution of a control program stored in the ROM

112

. It should be noted that the control program itself is not shown in the figure.

The ROM

112

employed in the image displaying apparatus

110

stores information

260

on the image displaying apparatus

110

. Such information indicates whether the image displaying apparatus

110

has a capability of displaying an image on a specific area of the display screen thereof by changing a display attribute of the specific area.

In addition, the image displaying apparatus

110

also employs a USB controller

115

, which serves as a counterpart of the USB controller

107

employed in the information processing apparatus

100

. More specifically, the USB controller

115

receives the inquiry signal from the information processing apparatus

100

and transmits the report signal to the information processing apparatus

100

in response to the inquiry signal. The inquiry signal is used for making an inquiry into the ability of the image displaying apparatus

110

to display an image on a specific area of the display screen thereof by changing a display attribute of the specific area in accordance with USB standards.

FIG. 53

is a diagram showing an outline of processing carried out by the image displaying system implemented by the present embodiment. As shown in the figure, the image displaying system includes an image displaying device driver

240

having an area judging means

3800

provided in the information processing apparatus

100

, for determining an area that is subject to a change of a display area; and the display-attribute changing means

5200

provided in the information processing apparatus

100

, for changing a display attribute of a specific area on the display screen of the image displaying apparatus

110

. The area judging means

3800

and the display-attribute changing means

5200

correspond to the specific-area-display-attribute changing means

4500

.

The application program

200

in the information processing apparatus

100

comprises a GUI, which includes a portion that is visible to the operator who operates the information processing apparatus

100

, and which serves as an interface with the operating system

210

.

The operating system

210

in the information processing apparatus

100

is a basic program serving as the nucleus of the image displaying system. More specifically, the operating system

210

connects the application program

200

with program members directly controlling hardware, such as a USB device driver

230

and the image displaying device driver

240

.

The image displaying device driver

240

in the information processing apparatus

100

is positioned between the operating system

210

and hardware members such as the device controller

105

and the display memory unit

106

. More specifically, the image displaying device driver

240

is a program which implements a draw instruction issued by the operating system

210

by reading out and writing information from and into internal registers of the display controller

105

and the display memory unit

106

. It should be noted that the internal registers themselves are not shown in the figure.

The application program

200

in the information processing apparatus

100

is provided with an area-attribute-information generating means

201

. When there is detected a need to change a display attribute of a specific area on the display screen of the image displaying apparatus

110

, area-attribute information

250

for changing the display attribute of the specific area on the display screen of the image displaying-apparatus

110

is generated in the application program

200

and passed to the operating system

210

by the area-attribute-information generating means

201

.

The operating system

210

in the information processing apparatus

100

comprises display-attribute-change control means

211

, area-attribute-information generating means

212

, and area-attribute-information acquiring means

213

. The display-attribute-change control means

211

controls the entire display-attribute-change processing of the information processing apparatus

100

by making the inquiry about the ability of the image displaying apparatus

110

to display an image on a specific area on the display screen thereof by changing a display attribute of the specific area, and by receiving the response to the inquiry. The area-attribute-information generating means

212

generates area-attribute information

251

in the operating system

210

when there is detected a need to change a display attribute of a specific area on the display screen. The area-attribute-information acquiring means

213

acquires the area-attribute information

250

generated by the area-attribute-information generating means

201

of the application program

200

.

In addition, the USB device driver

230

and the image displaying device driver

240

are included in the operating system

210

. The USB device driver

230

converts area-attribute information

251

and image-displaying-apparatus information

260

into USB data packets and vice versa in accordance with USB standards, and exchanges image-displaying-apparatus information

261

between the information processing apparatus

100

and the image displaying apparatus

110

. The image displaying device driver

240

stores data to be displayed in the display-memory unit

106

.

The USB controller

107

is controlled by the USB device driver

230

so that the inquiry about the ability of the image displaying apparatus

110

to display an image on a specific area on the display screen thereof by changing a display attribute of the specific area is transmitted from the USB controller

107

to the image displaying apparatus

110

, whereas the report indicating such an ability and transmitted by the image displaying apparatus

110

as a response to such an inquiry is also received by the USB controller

107

.

The area judging means

3800

employed in the image displaying device driver

240

forms a judgment as to whether display data stored in the display memory unit

106

is in a specific area, a display attribute of which is to be changed, on a display screen of the image displaying apparatus

110

based on the area-attribute information

251

. If the display data stored in the display memory unit

106

is in the specific area, the area judging means

3800

stores attribute data in a storage portion at a specific address in the display memory unit

106

associated with the data to be displayed. The display-attribute changing means

5200

employed in the display controller

105

reads out the data to be displayed and the attribute data from the display memory unit

106

at the same time, and changes a display attribute.

It should be noted that, in the area-attribute information

250

and the image-displaying-apparatus information

260

of the image displaying system implemented by the present embodiment, information similar to that shown in Tables 1 to 4 can be used. In addition, as a communication means for exchanging the area-attribute information

250

and the image-displaying-apparatus information

260

between the information processing apparatus

100

and the image displaying apparatus

110

, a non-USB means such as a DDC means can be used, as is shown in the description of the first embodiment.

Initialization processing carried out by the operating system

210

is the same as that of the fourth embodiment, and the procedure carried out by the application program

200

to modify a display attribute is the same as that of the third embodiment.

First of all, in the case of an image displaying apparatus

110

capable of displaying an image signal with a modified display attribute in a specific area on a display screen thereof, the display-attribute-change control means

211

of the operating system

210

sets an attribute change flag to indicate that the image displaying apparatus

110

is so capable.

The display-attribute-change control means

211

of the operating system

210

receives the contrast-increasing instruction from the application program

200

by way of the area-attribute-information acquiring means

213

. Receiving the instruction, the area-attribute-information acquiring means

213

references the attribute change flag set at the initialization and, if the image displaying apparatus

110

is capable of displaying an image signal with its display attribute changed in a specific area on a display screen thereof, area-attribute information

251

is supplied to the image displaying device driver

240

, making a request to increase the contrast of the specific area to the image displaying device driver

240

.

At the request described above, the area judging means

3800

of the image displaying device driver

240

determines a specific area on the display screen of the image displaying apparatus

110

for displaying dynamic-image data, develops attribute information indicating a contrast value of the specific area stored in the display memory unit

106

for the dynamic-image data, and stores the attribute data in the display memory unit

106

. The display controller

105

reads out the dynamic-image data and the attribute data developed in the display memory unit

106

. The display-attribute changing means

5200

changes the contrast value of a specific area on the display screen in which the dynamic-image data is to be displayed, and transmits an image signal with a display attribute thereof changed in the specific area to the image displaying apparatus

110

.

The following is description of an operation to control the contrast by using attribute data

2202

stored in the display memory unit

106

in the image displaying system implemented by the present embodiment.

FIG. 54

is a diagram showing the internal configuration of the display controller

105

provided by the present embodiment. As shown in the figure, in the display controller

105

, raw display data

2203

and the attribute data

2202

are supplied to the color-information controller

2400

corresponding to the display-attribute changing means

5200

. In the color-information controller

2400

, display attributes, such as the contrast can be adjusted. In addition, other display attributes, such as the brightness, the chromaticity, the γ characteristic, and the RGB levels, can also be adjusted.

The CRT controller

2300

generates a horizontal synchronization signal HSYNC and a vertical synchronization signal VSYNC. In addition, the CRT controller

2300

supplies the position information

2350

to the display-memory interface controller

2200

for reading out data to be displayed, and reads out raw display data

2203

, which is required in displaying data, and the attribute data

2202

from the display memory unit

106

.

FIG. 55

is a diagram showing the internal configuration of the color-information controller

2400

employed in the present embodiment. As shown in the figure, the color-information controller

2400

is provided with a pallet

2520

, a DAC

2530

, and an amplifier

2540

. The color-information controller

2400

corresponds to the display-attribute changing means

5200

for changing a display attribute of the raw display data

2203

.

Pieces of digital data

2521

to

2523

output by the pallet

2520

are converted into analog signals

2531

to

2533

by a DAC

2530

. The analog signals

2531

to

2533

are amplified into analog signals

2501

to

2503

, respectively, by the amplifier

2540

which is controlled by an attribute signal

2202

.

Depending upon the value of the attribute signal

2202

, however, the analog signals

2531

to

2533

are merely passed on as analog signals

2501

to

2503

, respectively, as they are by the amplifier

2540

without being amplified.

FIG. 56

is a timing chart showing operations of the color-information controller

2400

provided by the present embodiment. As shown in the figure, in the operation of the color-information controller

2400

, the analog signals

2531

to

2533

are amplified into analog signals

2501

to

2503

, respectively, by the amplifier

2540

at an amplification factor of

1

,

2

,

3

, and

4

for an attribute signal

2202

having a value of 00B, 01B, 10B, and 11B, respectively, where notation B indicates a binary expression.

Now, assume that the raw display data

2203

is 0002B, 0000B, 0000B, 0000B, 0000B, and 0001B, the attribute data

2202

is 11B, 00B, 11B, 01B, 10B, and 11B, and the digital data

2521

to

2523

output by the pallet

2520

is 1FH, 3FH, 3FH, 3FH, 3FH, and 00H. In this case, the analog display data

2501

,

2502

, and

2503

is 2PV/4, 1PV/4, PV, 2PV/4, 3PV/4, and PV/4, where notation PV is a peak voltage, indicating that the contrast can be adjusted for each picture element. In addition, other display attributes such as the brightness, the chromaticity, the γ characteristic, and the RGB levels can be adjusted as well.

According to the description given so far, the image-displaying-apparatus information

260

of the image displaying apparatus

110

stored in the ROM

112

is transferred to the information processing apparatus

100

when necessary, and a display attribute is changed. In addition to information stored in the ROM

112

, however, dynamic information, such as a driving voltage which varies from time to time, can also be transferred through the USB controller

115

.

FIG. 57

is a diagram showing a preferred implementation of an image displaying apparatus

110

provided by the present embodiment, for transmitting dynamic information to equipment such as an information processing apparatus

100

. As shown in the figure, in the image displaying apparatus

110

, which also transmits dynamic information to equipment such as the information processing apparatus

100

, a voltage driving an image displaying device

114

is converted from an analog signal into a digital one by an ADC

5700

. The digital data resulting from the A/D conversion is transmitted to the information processing apparatus

100

through the USB controller

115

. In this way, in addition to information determined in advance, dynamic information, such as a driving voltage which varies from time to time, can also be transferred to the information processing apparatus

100

.

In this way, the present driving state of the image displaying device

114

(for example, the average beam current in the case of a Braun tube) can be detected. By transmitting the result of the detection to equipment such as the information processing apparatus

100

, a need for changing a display attribute of a specific area can be detected. In the event of an excessively large beam current, for example, a measure for countering such an abnormality can be taken by lowering the contrast level.

As described above, according to the image displaying system implemented by the present embodiment, the information processing apparatus

100

forms a judgment as to whether data to be displayed exists in a specific area on a display screen of the image displaying apparatus

110

and, after attribute data

2202

for the data to be displayed is stored in the display memory unit

106

, a display attribute of a special area on a display screen of the image displaying apparatus

110

is modified by the information processing apparatus

100

prior to data transmission to the image displaying apparatus

110

, making it possible to control a display attribute for each pixel, as is the case with a conventional image displaying apparatus

110

. In addition, since the data to be displayed and the attribute data

2202

are treated on the same column, the amount of restriction on the expression of the designer who creates a raw image of the data to be displayed is decreased.

In addition, according to the image displaying system implemented by the present embodiment, when the position at which data is displayed is moved, the attribute data

2202

for the displayed data is just moved along with the displayed data without the need to form a judgment as to whether the displayed data exists in a specific area on a display screen of the image displaying apparatus

110

, making it possible to move the data displayed in a specific area having the changed display attribute.

Further, according to the image displaying system implemented by the present embodiment, the attribute data

2202

for the data to be displayed is stored in the display memory unit

106

. As a result, the attribute data

2202

can be stored without newly providing another storage means for the attribute data

2202

.

As described above, the present invention has been described in concrete terms with reference to some preferred embodiments. It should be noted that the description is not to be construed in a limiting sense. That is to say, the scope of the present invention is not limited to the disclosed embodiments, but a variety of changes and modifications can be made to the embodiments without departing from the spirit of the present invention.

Number	Date	Country
9-018229	Jan 1997	JP
9-068692	Mar 1997	JP
9-068693	Mar 1997	JP
9-068694	Mar 1997	JP
9-068695	Mar 1997	JP

Number	Name	Date	Kind
5276458	Swandon	Jan 1994	A
5321750	Nadan	Jun 1994	A
5483260	Parks et al.	Jan 1996	A
5499040	McLaughlin et al.	Mar 1996	A
5570108	McLaughlin et al.	Oct 1996	A

Number	Date	Country
0645750	Mar 1995	EP
7-225575	Aug 1995	JP
08251503	Sep 1996	JP
8-251503	Sep 1996	JP
WO9617338	Jun 1996	WO

Image displaying system and information processing apparatus

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Priority Claims (5)

US Referenced Citations (5)

Foreign Referenced Citations (5)

Non-Patent Literature Citations (1)