1. Field of the Invention
The present invention relates to an input device and an electronic apparatus having such an input device capable of providing visual amusement at the time of operating thereof.
2. Description of Related Art
In input devices such as key switch, touch switch and touch panel operated by finger touch, feedback for the input operation largely depends on tactual sense of a finger. A key switch is an only input device ever known to be integrated with a visual feedback indicator, in which color change is effected by incorporating a self-light-emitting element so as to be active in response to the ON/OFF operation of such switch, or by providing a mechanical shutter so as to cover/uncover the color-coated inner surface.
The touch panel is often mounted as a single-function device to electronic apparatus and examples of which, as combined with visual feedback display devices, include computer display and liquid crystal display.
The conventional switch is, however, disadvantageous in that feedback depending on the tactual sense cannot readily be obtained with a thinned switch due to a limited displacement in response to the input operation.
A problem also resides in that incorporating the foregoing visual feedback display device into a small-sized apparatus will also require relevant electronic circuits, wirings and contact portions, which may be an obstacle to the thinning, weight reduction and power saving.
Another problem resides in that, for a case of using a display device, a CPU (central processing unit) affording a certain level of high-speed processing will be required for ensuring real-time feedback display, which is disadvantageous in terms of cost, power consumption and heat generation.
It is therefore an object of the present invention to solve the foregoing problem and to provide an input device allowing the down sizing and thinning, and providing visual amusement at the time of operating thereof, and to provide an electronic apparatus having such an input device.
According to the first aspect of the present invention, there is provided an input device which comprises:
a reversible chromatic layer exhibiting color change in response to temperature change; and
a sheet-type input portion laminated on the reversible chromatic layer and activates ON operation upon being pressed.
Since the reversible chromatic layer causes color change simply by pressing the sheet-type input portion in the ON operation, visual change is enjoyable while achieving the down sizing and thinning.
In the second aspect of the present invention, the input device having the above first feature is characterized in that the reversible chromatic layer is located on a front surface of the sheet-type input portion and an input operation is effected by direct contact with such reversible chromatic layer.
When operating such an input device, the user directly touches the reversible chromatic layer.
In the third aspect of the present invention, the input device having the above first feature is characterized in that the reversible chromatic layer is located on a rear surface of the sheet-type input portion and an input operation is effected by direct contact with such sheet-type input portion.
When operating such an input device, the user directly touches the sheet-type input portion.
In the fourth aspect of the present invention, the input device having the above second feature is characterized in that heat required to cause temperature change of the reversible chromatic layer is provided through the direct contact thereto with a part of a human body.
That is, heat required to cause temperature change of the reversible chromatic layer is simply provided by a human touch.
In the fifth aspect of the present invention, the input device having the above third feature is characterized in that heat required to cause temperature change of the reversible chromatic layer is provided from an inner portion of an electronic apparatus.
That is, heat generated in the inner portion of the electronic apparatus can be consumed for causing temperature change in the reversible chromatic layer.
According to the sixth aspect of the present invention, there is provided an electronic apparatus having an input device, and the input device comprises:
a reversible chromatic layer exhibiting color change in response to temperature change; and
a sheet-type input portion laminated on the reversible chromatic layer and activates ON operation upon being pressed.
In such constitution, the reversible chromatic layer causes color change in response to the temperature change thereof. The sheet-type input portion is provided as laminated on the reversible chromatic layer, and can activate the ON operation simply by being pressed.
This allows color change of the reversible chromatic layer simply by pressing the sheet-type input portion in the ON operation, and can provide the user with visual amusement at the time of the ON operation of such an input device.
In the seventh aspect of the present invention, the electronic apparatus having the above sixth feature is characterized in that the reversible chromatic layer is located on a front surface of the sheet-type input portion and exposed outward within a window provided to a housing of the electronic apparatus, and
an input operation is effected by direct contact with such reversible chromatic layer.
When operating such an input device, the user directly touches the reversible chromatic layer.
In the eighth aspect of the present invention, the electronic apparatus having the above sixth feature is characterized in that the sheet-type input portion is exposed outward within a window provided to a housing of the electronic apparatus, the reversible chromatic layer is located on a rear surface of such sheet-type input portion, and an input operation is effected by direct contact with such sheet-type switch portion.
When operating such an input device, the user directly touches the sheet-type input portion.
In the ninth aspect of the present invention, the electronic apparatus having the above seventh feature is characterized in that heat required to cause temperature change of the reversible chromatic layer is provided through the direct contact thereto with a part of a human body.
That is, heat required to cause temperature change of the reversible chromatic layer is simply provided by a human touch.
In the tenth aspect of the present invention, the electronic apparatus having the above eighth feature is characterized in that heat required to cause temperature change of the reversible chromatic layer is provided from an inner portion of an electronic apparatus.
That is, heat generated in the inner portion of the electronic apparatus can be consumed for causing temperature change in the reversible chromatic layer.
Preferred embodiments of the present invention will be explained in detail hereinafter referring to the attached drawings.
The embodiments described hereinafter are preferred specific examples of the present invention, so that they will appear with various technically preferable limitations. It is, however, to be understood that the scope of the present invention is not restricted at all to the embodiments unless otherwise being specifically noted.
An electronic apparatus 10 allows the user to enter a desired command by gently pressing a switch 18 with the finger F. The electronic apparatus 10 in this embodiment is typified as a portable music reproducing apparatus for replaying music information, and replays the music information when the user enters a predetermined command.
The electronic apparatus 10 has a housing (case) 12 and the switch 18.
The housing 12 comprises an upper housing portion 14 and a lower housing portion 16, and is made of, for example, a plastic or a metal. For a case where the housing 12 is made of a plastic, available plastics include ABS (acrylonitrile-butadiene-styrene), ABS-PC (acrylonitrile-butadiene-styrene-polycarbonate), PA (polyamide), PC (polycarbonate), LCP (liquid crystal polymer) and the like. For a case where the housing 12 is made of a metal, available metals include Mg alloy, Al alloy, Zn alloy and the like.
On an end plane 26 of the housing 12 shown in
As shown in
The battery 180 is exemplified as a nickel-cadmium battery, nickel-hydrogen battery, lithium ion secondary battery or lithium-polymer battery, and is fixed on the bottom of the lower housing portion 16.
The circuit board 170 has a plurality of electronic parts 171, 172 mounted thereon. The electronic parts 171, 172 are, for example, a driver and a CPU, both of which are causative of heat generation during the operation. The circuit board 170 is electrically connected to the output portion 92 and interface portion 22 shown in
The switch 30 is located so as to aligne with a slit portion 40 of the upper housing portion 14, and most part of the switch 30 is exposed outward within the slit portion 40. This allows the finger F to directly touch the most part of the switch 30. When directly touching the switch 30, the user can move the finger F along the direction X1 or X2 indicated in
The switch 30 comprises a reversible chromatic layer 60, a sheet-type switch portion 62 and a heat-insulating layer 64 laminated and adhered with each other. The heat-insulating layer 64 is responsible for preventing heat generated by the electronic parts 171, 172 on the circuit board 170 from conducting toward the reversible chromatic layer 60.
The reversible chromatic layer 60 is a layer comprising a substance, the spectrum of which changes at least in the visible light region in response to temperature change within a certain range, which is also known as a reversible thermochromic substance or the like.
The following materials are used for the reversible chromatic layer 60.
The reversible chromatic layer 60 comprises a substance exhibiting thermochromism and is available for heat sensitive display. Thermochromism refers to a phenomenon such that a color is not observed at a certain temperature but develops under proper heating, or such that a color is observed at the normal temperature but fades or changes into another color as the temperature rises.
As such a substance used for the reversible chromatic layer 60, conventionally used is such that liberates water under heating to cause color change and re-absorb the water under cooling to recover the initial color. Specific examples of such a substance include double salts comprising transition metals such as cobalt, nickel and manganese as combined with amine amides such as hexamethylene tetramine; mercury iodide; double complex salts comprising mercury iodide and other metal iodide; heavy metal compounds such as lead chromate and ammonium metavanadate; organic compounds such as dixanthilene and bianthrone; and certain kinds of organic dyes and pigments.
Other known thermochromic substances available for the reversible chromatic layer 60 include cholesteric liquid crystal, or mixture of cholesteric and nematic liquid crystals.
A heat sensitive chromatic agent is recently developed and widely used; the agent comprising an electron donor substance developing a color by releasing an electron and an electron acceptor substance (electron accepting developer) mixed therewith.
Known electron accepting developers include phenols, phenol resin oligomer, organic acids such as oxyaromatic carboxylic acids, acidic substances such as zinc chloride and stannous chloride, and adsorbents such as attapulgite and montmorillonite.
There are no specific limitations on the electron donating coloring substance and any known substance may arbitrary be selected, provided that it can allow reversible color change between a dark color and perfect colorless. Specific examples thereof include substituted phenylmethane and fluorane derivatives such as 3,3′-dimethoxyfluorane (yellow), 3,3′-dibutoxyfluorane (yellow), 3-chloro-6-phenylaminofluorane (yellowish orange), 3-diethylamino-6-methylchlorofluorane (reddish orange), 3-diethyl-7,8-benzofluorane (pink), 3,3′,3″-tris(p-dimethylaminophenyl)phthalide (bluish purple), 3,3′-bis(p-dimethylaminophenyl)phthalide (green), 3-diethylamino-7-dibenzylaminofluorane (dark green), 3-diethylamino-6-methyl-7-phenylaminofluorane (black); various indolyl phthalide-base dye (blue to green); and spiropyranes (yellowish brown to reddish green). These compounds may be used independently or in combination of two or more thereof.
There are no specific limitations also on the electron accepting developer and any known substance may arbitrary be selected. Specific examples thereof include phenols, oxyaromatic carboxylic acid, carboxylic acid, azoles, azole esters, azole amides, and metal salts thereof such as lithium salt, sodium salt, calcium salt, magnesium salt, aluminum salt, zinc salt, tin salt, titanium salt and nickel salt. These compounds may be used independently or in combination of two or more thereof.
In the switch 30, which is also referred to as an input apparatus, a paint exhibiting reversible thermochromism is coated in an area coming into direct contact with the finger F. The thermochromic coloring agents include organic phosphor, metal complex solution and chiral nematic liquid crystal, all of which can vary the light emission spectrum in response to temperature. These coloring agents are mixed with an auxiliary of petroleum-base, ester-base, ketone-base or aromatic-base, and coated using a spray gun or brush.
The auxiliary is selected optimally depending on the material composing the switch contact portion to be coated therewith. Thickness of the coated paint is closely related to the temperature rise through heat conduction, so that a thickness allowing a sufficient chromatic effect is preferable. The temperature range allowing the color change is preferably selected so that a first color in the lower temperature region is developed at the temperature of the housing or other peripheral portions, and that a second color in the higher temperature region is developed at the temperature within an area around the site of the finger touch at the time of such finger touch. It is now necessary to properly select the coloring agent and the auxiliary depending on the environment in which they are used, since the above temperature may vary depending on such environment of use.
With such an input device involving the coated layer, an input operation is effected by a direct touch by the user's finger F, heat required for the temperature change of the reversible chromatic layer 60 will be provided through heat conduction toward the coated plane, and the temperature within an area around the site of the finger touch will rise to develop the color change in such area.
As shown in
The sheet-type switch portion 62 has the upper sheet 62A susceptible of elastic deformation upon a gentle touch with the finger F, the lower sheet 62B and spacers 62C. The spacers 62C contribute to maintain a space SP between the upper sheet 62A and lower sheet 62B, and in the space SP electrodes 63A and 63B are housed. The upper sheet 62A, lower sheet 62B and spacers 62C are made of an insulating material such as biaxially stretched PET (polyethylene terephthalate) film, uniaxially stretched PET film, PC (polycarbonate) film or PES (polyether sulfone) film.
The switch 30 has switch contact points 50 to 54 regularlly spaced as shown in
The electrodes 63A and 63B are made of, for example, Ag—C, C or Cu.
Next, an exemplary operation of the switch (also referred as to the input device) and the electronic apparatus having such switch previously shown in
In such a manner, the user can activate ON operation of any one of, or an arbitrary combination of the switch contact points 50 to 54 by sliding the finger F on the reversible chromatic layer 60 of the switch 30 shown in
Another exemplary embodiment of the switch and the electronic apparatus having such switch of the present invention will be described referring to
The switch and the electronic apparatus shown in
The switch 130 does not have the heat-insulating layer 64, unlike the embodiment shown in
The heat insulating layer 64 in the foregoing embodiment shown in
On the contrary in the embodiment shown in
Since the reversible chromatic layer 60 is provided on the rear side of the sheet-type switch portion 62 comprising the upper sheet 62A, spacers 62C and lower sheet 62B as shown in
In this case, the upper sheet 62A, the lower sheet 62B and the spacers 62C are individually made of, for example, a transparent material, and specific examples of which include a uniaxially stretched PET film, PC film and PES film. Also the electrodes 63A and 63B are preferably made of a transparent material such as ITO (indium tin oxide; In2O3—SnO2) obtained by sputtering, vapor deposition, ion plating or CVD (chemical vapor deposition); ATO (antimony tin oxide; SnO2—Sb2O5); CTO (cadmium tin oxide; Cd2SnO4); SnO2; ZnO—SnO2; and CdO—ZnO—SnO2.
The reversible chromatic layer 60 shown in
Since other parts of the switch and the electronic apparatus incorporating such switch shown in
In the embodiment shown in
The reversible chromatic layer 60 shown in
When different kinds of reversible chromatic substances are coated, masking with a masking tape or so can allow a specific kind of the substance to be coated only to the limited area, and repeating such process by numbers of substances will provide such different color change as shown in
As shown in
Or, as shown in
With such patterning of the letters based on the masking technique as shown in
Using thus aligned switch 18 shown in
It has been thought in the conventional art that providing a visual feedback display device to an input device such as a keyboard or touch panel was disadvantageous in terms of power consumption and complicated mechanism. Whereas the present invention is successful in the thinning, down sizing and the feedback without additional power consumption, so that down sizing and power saving of the electronic apparatus can be achieved while providing amusement through the visual effect.
Possible styles of the switch include those having aligned switches, and more specifically include a touch panel, serially-aligned planar press switch and matrix-aligned planar press switch.
According to the present invention, an extra-thin switch, feedback of which being not dependent only on the tactual sense, can be fabricated. Using such extra-thin switch results in reduction in the size and weight of the electronic apparatus.
Since the chromatic effect can be obtained without additional power consumption, the electronic apparatus can be used for a long period while suppressing the exhaustion of the battery.
In addition, the visual effects can provide the user with amusement in the input operation through such switch.
The present invention is by no means limited to the foregoing embodiments.
While
The switch and the electronic apparatus of the present invention allows down sizing and thinning of the electronic apparatus, and provides the user with amusement of visual effect in the feedback without additional power consumption.
The microcomputers 80 and 84, the memory 86 and the music information amplifying output portion 88 composes a circuit unit 90, and the circuit unit 90 is located in an inner space of the housing 12.
The microcomputer 80 is connected to the switch contact points 50 to 54 of the sheet-type switch portion 62 previously shown in
The microcomputer 80 is also connected to the microcomputer 84 for general control. The memory 86 is connected to the microcomputer 84 for general control. The microcomputer 84 controls the microcomputer 80, memory 86 and music information amplifying output portion 88.
The microcomputer 84 is connected to the music information amplifying output portion 88. The music information amplifying output portion 88 amplifies music information received from the memory 86 via the microcomputer 84 and then outputs the information to the output portion 92 such as a headphone or earphone. Using the output portion 92 makes the music information audible to the user.
The information output from the output portion 92 may of course not only be the music information but also be other type of audio information.
A semiconductor memory, for example, and any other type of memory are applicable as the memory 86. The memory 86 may be fixed to the circuit unit 90, or may be composed so as to be detachable from the circuit unit 90. It is also possible to directly write music or other information through a communication network such as Internet.
Available semiconductor memories include DRAM (dynamic random access memory) and SRAM (static random access memory). Hard disk is a typical example of other type of memory.
The switch contact points 50 to 54 are individually connected via wirings 66 to ports P10 to P14 of the microcomputer 80 as shown in
It is also allowable to design an output portion 87 of the microcomputer 80 so as to output a voltage corresponding to an input key code decided by internal processing of a microcomputer 80. Examples of such key codes and the relevant output voltage ratio are listed in Table (A) in
Input key code VOL+ in Table (A) in
Input key code STOP stops replay of music information, the corresponding output voltage ratio being 0.59. Input key code PLAY/FF enables transfer of music information from the memory 86, shown in
Now the output voltage ratio is defined as output voltage=output voltage ratio×Vcc
where, Vcc is a reference voltage and is typically 5 V.
For example, if a key input is detected in step ST100 in
The exemplary input key code decision table of
The input key code decision table of
Rows (D) shows various key codes defined by combinations of the key initially turned ON in Column (A) and the current ON key in Column (B). For example, when the key initially turned ON is key0 and current ON key defined within a predetermined period is again key0, that is, when the same key was pressed twice within a predetermined period, the input key code will be VOL+ (raising sound level).
When the key initially turned ON is key1 and current ON key defined within a predetermined period is again key1, the input key code will be invalid. Similarly, key3 for the key initially turned ON and key3 for the current ON key defined within a predetermined period will also result in an invalid input key code.
Key2 for the key initially turned ON and key2 for the current ON key defined within a predetermined period will result in an input key code of STOP (cessation of replay of music information); and key4 for the key initially turned ON and key4 for the current ON key defined within a predetermined period will result in an input key code of VOL− (lowering sound level).
Rows (E) of
While Rows (E) correspond to the cases in which the key initially turned ON is smaller than the current ON key, Rows (F) on the contrary corresponds to the cases in which the key initially turned ON is larger than the current ON key. In these cases, the input key code will be REW (recovering replay position of music information). For example, when the key initially turned ON is key4 and the current ON key defined within a predetermined period is key3, the input key code will be REW.
In the key scan shown in Column (A) of
Of course, chattering elimination, noise isolation and other software-base processing internally proceed at that time so as to avoid false recognition of pressing the key despite no human intention of pressing the key, or to avoid false judgment of pressing the key interfered by external electromagnetic noise.
Thereafter, the switch will be pressed again according to the modes shown in Columns (B) to (D) of
When the same key is pressed within a predetermined period as described in Column (B) of
When the adjacent key is turned into ON, the input key code PLAY/FF or REW will come into effect according to the combination listed in Rows (E) and (F) of
Column (D) of
Next, an exemplary operation of the input device 18 previously shown in
As shown in
In this case, the slit portion 40 shown in
For example, when the user presses the switch contact point 50 for operation shown in
When the user presses, for example, the switch contact point 50 (key0) for operation and then presses the switch contact point 51 (key1) for operation within a predetermined period, the input key code of PLAY/FF will come into effect as shown in Rows (E) of
When the user presses, for example, the switch contact point 54 (key4) for operation and the switch contact point 53 (key3) for operation within a predetermined period, the input key code of REW will come into effect by the microcomputer 80 as shown in Rows (F) of
As described in the above, when the user serially touches by the finger an arbitrary number of key tops from the switch contact points 50 to 54, complete touch will be effected simply by sliding the finger along the longitudinal direction X1 of the slit portion 40 or along the counter direction X2. Moreover, only a limited number of switch contact points 50 to 54 for operation can afford selection of various functions as listed in
The present invention is by no means limited to the foregoing embodiments and permits various modifications.
The microcomputers 80 and 84 shown in
The input device 18 shown in
The input device of the present invention can be applicable not only to such an electronic apparatus for replaying music or music information, but also to a recording and reproducing apparatus for music information. The input device of the present invention still can be applicable not only to recording and reproducing of music information, but also to recording and reproducing apparatus of image and audio information, or to reproducing apparatus of image and audio information.
The input device of the present invention can still further be applicable to electronic apparatus of other types or in other fields besides the applications described above. For example, applying the input device to a touch pad intended for character input will allow the user to proceed current input operation while confirming the locus of the input operation finished immediately before or a few seconds before. Thus a character of much strokes such as some kinds of Chinese characters can be input while confirming a relative positioning of a radical, and input error will be avoidable.
According to the embodiment of the present invention, conventional problems can be overcome by employing the feedback based on the visual sense in place of that based on the tactual sense.
A display using the feedback based on such visual effect is composed of a thin plate or thin film provided on the switch, which exhibiting the color change in response to the user's operation and more specifically to the motion of the switch. Such color change automatically recovers the initial state immediately after or within a proper delay period after the completion of the input operation, so that sufficient opportunities for confirming the input operation and enjoying the visual effects are given to the user.
By providing such chromatic mechanism to an input device such as a keyboard, touch switch or touch pad so as to be added to the top surface thereof or integrated with the input device, the color change upon the input operation will be obtained.
Employing a highly transparent material for the input device, in addition to such chromatic mechanism, allows the mechanism to be placed on the display device, which results in functional integration of the input and display devices and down sizing of the electronic apparatus.
The intentional introduction of the local difference in the chromatic effect to an area exhibiting the chromatic function can sufficiently provide the user with amusement in the operation.
If such chromatic mechanism is made detachable so as to allow the user to exchange it to his or her own taste, the user can also show the individuality.
Number | Date | Country | Kind |
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P11-272810 | Sep 1999 | JP | national |
This application is a continuation of application Ser. No. 09/662,879, filed on Sep. 15, 2000 now U.S. Pat. No. 6,690,362.
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Number | Date | Country | |
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20040080490 A1 | Apr 2004 | US |
Number | Date | Country | |
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Parent | 09662879 | Sep 2000 | US |
Child | 10684460 | US |