1. Field of the Invention
The present invention relates to a driving circuit of a display and a display device and more particularly to the driving circuit of the display made up of light emitting elements including an EL (Electroluminescence) element, an LED (Light Emitting Diode) element, a VFD (Vacuum Fluorescent Display) (FED (Field Emission Display) being one of the VFDs in particular) element or a like and used to display various kinds of information, measurement results, moving pictures or still pictures and to the display device equipped with the driving circuit of the display described above.
The present application claims priority of Japanese Patent Application No. 2000-259984 filed on Aug. 29, 2000, which is hereby incorporated by reference.
2. Description of the Related Art
Conventionally, some displays are made up of light emitting elements which include an EL element, LED, VFD (FED in particular), or the like. Of them, an EL display constructed of the EL elements is considered to be promising since it has many advantages in that it can be made planar, thinner, and more lightweight, that it can provide excellent visibility by spontaneous light and can provide quick response and that it can display moving pictures. Conventionally, an inorganic EL element using inorganic materials such as ZnS:Mn (zinc sulfide:manganese) or a like is mainstream, however, an organic EL element using organic materials such as a stilbene derivative or a like has been developed recently.
In the organic EL display 1 of this example, one pixel is made up of dot pixel portions consisting of the three organic EL elements ELG, ELR, and ELB each emitting one color out of three primary colors including green, red, and blue colors. The organic EL display 1 is called a “stripe” organic EL display since the organic EL element ELG, ELR and ELB each corresponding to each of the dot pixel portions are arranged in order of the green color light emitting EL element ELG, red color light emitting EL element ELR, and blue color light emitting ELB in a column direction and in a sequentially repeated manner and the organic EL elements to emit light of same color, out of the organic EL element ELG, ELR, and ELB are consecutively arranged in a row direction. Moreover, in the organic EL display 1 of the example, a pixel portion made up of the dot pixel portions is placed at an intersection of each of the data electrodes 3 formed at specified intervals in a column direction and each of the scanning electrodes 10 formed at specified intervals in a row direction, that is, the pixel portions made up of the dot pixel portions are arranged in a matrix form, and a character, image, or a like are displayed by light-emitting of the light emitting layers 6 to 8 corresponding to an arbitrary dot pixel portion occurring when a data signal produced based on a video signal is applied to the data electrodes 3 and a scanning signal produced based on a horizontal sync signal and a vertical sync signal is applied to the scanning electrodes 10. Therefore, the above organic EL display 1 is called a “simple-matrix EL display”.
The conventional driving circuit chiefly includes a controller 11, data electrode driving circuits 12 and 13 and a scanning electrode driving circuit 14. The controller 11 produces a green video signal SG, red video signal SR, and blue video signal SB based on a video signal SP supplied from outside and feeds them to the data electrode driving circuits 12 and 13 and further produces a horizontal scanning pulse PH and vertical scanning pulse PV based on a horizontal sync signal SH and vertical sync signal SV and feeds the horizontal scanning pulse PH to the data electrode driving circuits 12 and 13 and feeds the vertical scanning pulse PV to the scanning electrode driving circuit 14. Each of the data electrode driving circuits 12 and 13 has driving sections 15 in numbers being equivalent to the number of the data electrodes 3 and produces a data green signal IDG, data red signal IDR, and data blue signal IDB each having a specified current value, respectively, using the green video signal SG, red video signal SR, and blue video signal SB, all of which are voltage signals, with the timing when the horizontal scanning pulse PH is fed from the controller 11 and then feeds each of them to each of corresponding data electrodes 3 in the organic EL display 1. The scanning electrode driving circuit 14, with the timing when the vertical scanning pulse PV is supplied from the controller 11, sequentially switches the scanning electrodes 10 in the organic EL display 1 for scanning.
The organic EL display 1 that can display full color described above is one that has been developed recently and EL displays that have become generally and commercially practical are organic EL displays made up of organic EL elements that can display a yellowish-orange monochrome color. Therefore, as ICs making up the data electrode driving circuit adapted to drive the EL display, only the ICs that have been prepared for the use in the organic EL display adapted to display the monochrome color and that are provided with driving sections having same current driving capability, are distributed commercially. It is a current status quo that such ICs as have been prepared for the use in the organic EL display adapted to display the monochrome color are also used in the data electrode driving circuits 12 and 13.
However, in the conventional organic EL display 1 that can display full color, as shown in
For example, as shown in
Therefore, there is shortcoming in the conventional EL display in that, if the ICs that have been prepared for the use in the organic EL display adapted to display the monochrome color and for the use in data electrode driving circuits equipped with driving sections each having the same current driving capability, are used in the above data electrode driving circuits 12 and 13, in the case of emitting the red color light, sufficient luminance cannot be attained and, in the case of emitting the blue or green color light, excessive applied voltages are fed thus causing increased power consumption. This also presents problems in that a satisfactory display of full color cannot be achieved, recent demands for high definition in the display cannot be satisfied and lowering of power consumption cannot be implemented. Moreover, in recent years, strong demands for the large screen of the display have grown and, to make large a screen of the organic EL display, a double scanning method is the essential driving method. However, even when the scanning method is employed, if the number of the organic EL elements to be driven by one driving section to achieve the large screen increases, the satisfactory display of full color is made further difficult.
There is a risk that a same inconvenience as described above occurs not only in the above organic EL display adapted to display full color but also in the full color display device made up of other light emitting elements including the LED, VFD (in FED being one type of the VFD in particular) if there are the differences in characteristics of the light emitting elements to emit light of each of the green, red, and blue colors, in the applied voltage-current density characteristics, in particular.
In view of the above, it is an object of the present invention to provide a driving circuit of a display adapted to display full color using light emitting elements to emit light of each color capable of attaining a sufficient display characteristic even when there is a difference in characteristics of the light emitting elements and capable of lowering power consumption and of achieving a high picture quality and a display device equipped with the driving circuit for the display.
According to a first aspect of the present invention, there is provided a driving circuit of a display for driving the display which is made up of first to third light emitting elements in which electrical characteristics of the first light emitting element to emit light of one of three primary colors differs greatly from those of the second and third light emitting elements to emit light of other two colors and in which the first to third light emitting elements are arranged in an order in which the first light emitting element is sandwiched by the second and third light emitting elements, in a column direction in a sequentially repeated manner and in which the first to third light emitting elements to emit light of a same color are arranged consecutively in a row direction, the driving circuit including:
first driving sections each having driving capability enough to drive the first light emitting element;
second driving sections each having driving capability enough to drive the second and third light emitting elements; and
wherein the first and second driving sections are arranged in an order in which the first driving section is sandwiched by the second driving sections, in a sequentially repeated manner in a column direction in a manner to correspond to column-directional arrangement of the first to third light emitting elements.
In the foregoing, a preferable mode is one wherein the driving capability is set depending on a value given by a slope of a curve showing applied voltage-luminance characteristics of a corresponding said light emitting element.
Also, a preferable mode is one wherein driving capability of the second driving sections is set depending on an average value given by slopes of curves showing applied voltage-luminance characteristics of each of the second light emitting element and the third light emitting element.
Also, a preferable mode is one wherein each of the first and second driving sections outputs, in synchronization with a horizontal sync signal, a data signal made up of a pulse of positive polarity relative to a reference voltage and having a current value based on the driving capability.
Also, a preferable mode is one wherein the first and second driving sections are so configured that a width of the pulse making up the data signal is able to be changed depending on values given by the curves showing characteristics of each of the corresponding light emitting element.
Also, a preferable mode is one wherein the display is of a simple-matrix type in which the first to third light emitting elements are placed at an intersection of each of a plurality of scanning electrodes arranged at specified intervals in a row direction and each of a plurality of data electrodes arranged at specified intervals in a column direction.
Also, a preferable mode is one wherein the display is of a passive-matrix type in which the first to third light emitting elements and a diode serving as a switching element are placed at an intersection of each of the plurality of the scanning electrodes arranged at the specified intervals in the row direction and each of the plurality of the data electrodes arranged at specified intervals in the column direction.
Also, a preferable mode is one wherein the display is so configured that the plurality of the data electrodes are divided into two portions at an approximately central place of a display region and the divided data electrodes installed from the approximately central place toward an upper end portion of the display region is routed to an upper portion on an upper side of the display region and each terminal portion of the divided data electrodes is connected to each of data terminals mounted at an upper end of the display at specified pitches and the divided data electrodes installed from the approximately central place toward a lower end portion of the display region is routed to a lower portion on a lower side of the display region and each terminal portion of the divided data electrodes is connected to each of corresponding data terminals mounted at the specified pitches.
Also, a preferable mode is one that wherein includes an integrated circuit in which, inside the integrated circuit, the first and second driving sections are arranged in the order in which the first driving section is sandwiched by the second driving sections, in a sequentially repeated manner, from a left end portion toward a right end portion of the integrated circuit in a column direction and in a manner to correspond to the column-directional arrangement of the first to third light emitting element and in which, in a lower or in an upper end portion of the integrated circuit, output pins are provided which are arranged from the left end portion to the right end portion of the integrated circuit at pitches being approximately equal to the specified pitches at which the data terminals are placed in either of an upper end portion or lower end portion of the display, in a manner to correspond to the data terminals and an output terminal corresponding to each of the first and second driving sections arranged from the left end portion to the right end portion of the integrated circuit is connected to each of the output terminals.
Furthermore, a preferable mode is one wherein the light emitting element is any one of an electroluminescence element, a light emitting diode or a vacuum fluorescent display.
According to a second aspect of the present invention, there is provided a display device having a driving circuit of the display described above.
With the above configurations, since first driving sections each having driving capability enough to drive first light emitting element and second driving sections each having driving capability enough to drive second and third light emitting elements are arranged in a sequentially repeated manner, in a column direction in an order in which the first driving section is sandwiched by the second driving sections and in a manner to correspond to a column-directional arrangement of the first to third light emitting elements, in a display adapted to display full color by using light emitting elements to emit light of each color, even when there is a difference in characteristics of light emitting elements, sufficient display characteristics can be attained and high picture quality can be achieved and power consumption can be lowered.
The above and other objects, advantages, and features of the present invention will be more apparent from the following description taken in conjunction with the accompanying drawings in which:
Best modes of carrying out the present invention will be described in further detail using various embodiments with reference to the accompanying drawings.
Each of the data electrode driving circuits 21 and 22 is made up of an IC and produces, with a timing when a horizontal scanning pulse PH is fed from a controller 11, a data green signal IDG, data red signal IDR, and data blue signal IDB, each of which is a current signal having a predetermined current value, from a green video signal SG, red video signal SR, and blue video signal SB, all of which are voltage signals, respectively, and feeds each of them to each of corresponding data electrodes 3 in the organic EL display 1. Each of the data electrode driving circuits 21 and 22 is made up of an IC which contains driving sections 23 each having enough specified current driving capability to drive organic EL elements ELG and ELB adapted to emit green color light and blue color light, respectively, and driving sections 24 each having enough current driving capability to drive an organic EL element ELR adapted to emit red color light and each having current driving capability being larger than that possessed by each of the driving sections 23 and in which the driving sections 23 and 24 are arranged repeatedly in order of the driving sections 23, 24, 23, 23, 24, 23, . . . in a manner to correspond to arrangement of the organic EL elements ELG, ELR, and ELB arranged in a stripe form in order of the green color light emitting organic EL element ELG, the red color light emitting organic EL element ELR, and the blue color light emitting organic EL element ELB.
That is, in the IC making up the data electrode driving circuit 21, in its internal portion, the driving sections 23 and 24 are arranged in a repeated manner in order of the driving sections 23, 24, 23, 23, 24, 23, . . . in a direction from its left end portion toward its right end portion and, in its lower end portion, output pins (not shown) are mounted in a direction from its left end portion toward its right end portion at a pitch being approximately equal to a specified pitch at which data terminals (not shown) are formed in an upper end portion of the organic EL display 1, in a manner that the output pins correspond to the data terminals (not shown), and each of output terminals each corresponding to each of the driving sections 23 and 24 arranged in the direction from the left end portion toward the right end portion of the IC is connected to each of the output pins. On the other hand, configurations of the IC making up the data electrode driving circuit 22 are the same as those of the IC making up the data electrode driving circuit 21, however, in the data electrode driving circuit 22, the IC is reversed upside down and is mounted in a direction opposite to the lower end portion of the organic EL display 1. That is, in
Next, operations of the data electrode driving circuits 21 and 22 making up the driving circuit of the organic EL display 1 having configurations described above by referring to a timing chart shown in
Next, after lapse of a predetermined period of time since the horizontal scanning pulse PH changed from a low to a high, as shown as a waveform (2) in
Thus, according to the first embodiment of the present invention, the organic EL display 1 in which the organic EL elements ELG, ELR, and ELB are arranged in the stripe form in order of the EL element ELG, ELR, and ELB emitting the green color light, red color light, and blue color light respectively and in which the applied voltage-luminance characteristics or the applied voltage-current density characteristics of the organic EL element ELR adapted to emit the red color light differ greatly from those of the organic EL elements ELG and ELB adapted to emit the green color and blue color light respectively, is driven by using the data electrode driving circuits 21 and 22 made up of the IC in which the driving section 23 having enough specified current driving capability to drive the organic EL elements ELG and ELB and the driving section 24 having enough current driving capability to drive the organic EL element ELR adapted to emit the red color light and having the current driving capability being larger than that possessed by the driving sections 23 are arranged in a manner to correspond to arrangement of the organic EL elements ELG, ELR, and ELB. This enables sufficient luminance to be attained even in a case of emitting the red color light and power consumption to be lowered even in a case of emitting the blue or green color light owing to proper application of the applied voltage. Therefore, it is possible to achieve satisfactory full color display and to respond to a demand for high picture quality. Moreover, even in an organic EL display employing the double scanning method, since the data electrode driving circuit 21 can be used as the data electrode driving circuit 22 by reversing, upside down, the IC making up the data electrode driving circuit 21, high general versatility can be provided accordingly.
Each of the data electrode driving circuits 31 and 32, with a timing when a horizontal scanning pulse PH is fed from a controller 11, produces a green video signal SG, red video signal SR, and blue video signal SB each being a current signal having a specified current value by using a data green signal IDG, data red signal IDR, and data blue signal IDB each being a voltage signal and feeds produced signals to each of corresponding data electrodes 3 of the organic EL display 1.
Each of the data electrode driving circuits 31 and 32 is made up of an IC which contains driving sections 33 each having enough specified current driving capability to drive the organic EL element ELG adapted to emit green color light and driving sections 34 each having enough current driving capability to drive an organic EL element ELB adapted to emit blue color light and further driving sections 24 each having current driving capability being larger than that possessed by each of the driving sections 33 and 34 and in which the driving sections 33, 24, and 34 are arranged in a repeated manner in order of the driving sections 33, 24, 34, 33, 24, 34, . . . in a manner to correspond to arrangement of the organic EL elements ELG, ELR, and ELB arranged in a stripe form in order of the green color light emitting organic EL element ELG, the red color light emitting organic EL element ELR, and the blue color light emitting organic EL element ELB (refer to light emitting layers in
That is, in the IC making up the data electrode driving circuit 31 as shown in
Thus, according to the second embodiment of the present invention, the organic EL display 1 in which the organic EL elements ELG, ELR, and ELB are arranged in a stripe form in order of the green color light emitting organic EL element ELG, red color light emitting organic EL element ELR, and blue color light emitting organic EL element ELB and in which the applied voltage-luminance characteristics or the applied voltage-current density characteristics of the green color light emitting organic EL element ELG, red color light emitting EL element ELR, and blue color light emitting EL element ELB are different from each other, is driven by using the data electrode driving circuits 31 and 32 made up of the IC in which the driving sections 33, 24 and 34 each having enough specified current driving capability to drive each of the organic EL elements ELG, ELR, and ELB are arranged in a manner to correspond to the arrangement of the organic EL elements ELG, ELR, and ELB. This enables sufficient luminance to be attained in a case of emitting any of the green color, red color, and blue color light and power consumption to be lowered more owing to proper application of the applied voltage to each of the organic EL elements ELG, ELR, and ELB.
It is apparent that the present invention is not limited to the above embodiments but may be changed and modified without departing from the scope and spirit of the invention. For example, in the above embodiments, the present invention is applied to the simple-matrix organic EL display 1, however, the present invention can be also applied to a passive-matrix organic EL display 41, as shown in
Also, in the above embodiments, each of the data electrode driving circuits 21, 22, 31, and 32 is made up of the IC and the output pin is placed in the lower end portion of the IC, however, the output pin may be mounted in an upper end portion of the IC. In this case, the data electrode driving circuits 22 and 32 are so mounted that the upper end portion of the data electrodes 22 and 32 are placed opposite to the lower end portion of the organic EL display 1, while the data electrode driving circuits 21 and 31 are so mounted that the lower end portion obtained by reversing each of the data electrode driving circuits 21 and 31 upside down is placed opposite to the upper end portion of the organic EL display 1.
Also, in the above first embodiment, the example is shown in which the current ratio between the bipolar transistors Q1 and Q3 is 1:6, however, the present invention is not limited to this. That is, the above current ratio may be calculated from an average value given by the slopes of both the curves “a” and “c” showing the applied voltage-luminance characteristic shown in
In the above embodiments, any of the driving sections 23, 24, 33, and 34 is made up of the bipolar transistors, however, these driving sections may be constructed of MOSFETs (Metal Oxide Semiconductor FET).
In the above embodiments, the present invention is applied to the organic EL display 1 employing the double scanning method, however, the present invention may be applied to the organic EL display in which the data electrodes 3 are installed from the lower end toward the upper end of the display region and are routed from either of the lower end or the upper end outside the display region and are connected to data terminals formed at specified intervals in the upper or lower portion of the display region.
In the above embodiments, the present invention is applied to the organic EL display 1 in which the organic EL elements ELG, ELR, and ELB are arranged in the stripe form in order of the green color light emitting organic EL element ELG, red color light emitting organic EL element ELR, and blue color light emitting organic EL element ELB and in which the applied voltage-luminance characteristics or the applied voltage-current density characteristics of the red color light emitting organic EL element ELR differ greatly from those of the green color light emitting organic EL elements ELG and blue color light emitting organic EL element ELB, however, the present invention is not limited to this. That is, the present invention may be applied to the stripe-type organic EL display which is made up of three types of the light emitting elements each emitting any one of three primary color light and in which electrical characteristics of the light emitting element adapted to emit one color light differ greatly from of those of two types of the light emitting elements adapted to emit light of other remaining two colors and in which the light emitting elements are so mounted that the former light emitting element is sandwiched by the latter two light emitting elements.
In the above embodiments, the present invention is applied to the organic EL display 1 which is made up of the organic EL element, however, the present invention may be applied to the “stripe” type display which is made up of an inorganic EL element, LED, VFD (FED being one of the VFD in particular) or a like. Even when there is the difference in the electric characteristics, in particular, in the applied voltage-current density characteristics, of the light emitting elements each being adapted to emit light of one of the three primary colors, the same effect can be achieved by the present invention.
Furthermore, the driving circuit of the display of the present invention can be applied to the display device equipped with the display used as monitors of a personal computer.
Number | Date | Country | Kind |
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2000-259984 | Aug 2000 | JP | national |
The present application is a continuation of and claims, under 35 U.S.C. § 120, the benefit of U.S. patent application Ser. No. 09/939,645, filed on Aug. 28, 2001, now U.S. Pat. No. 6,788,298 which claims priority to Japanese Patent Application No. 2000-259984 filed on Aug. 29, 2000, the contents of which are fully incorporated herein by reference.
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Number | Date | Country | |
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Parent | 09939645 | Aug 2001 | US |
Child | 10927216 | US |