JP2797457B2 - Location information input device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an input device for inputting position information.

[Prior Art] Conventionally, as a two-dimensional position information input device, an input pen (stylus) is placed on a flat plate (tablet) in which magnetostrictive wires made of a magnetostrictive alloy are arranged in a matrix in the XY directions.
There is known a digitizer for tracking and inputting position information.

[Problems to be Solved by the Invention] By the way, in the conventional position information input device of this type, since the diameter of the magnetostrictive wire and the electromagnetic induction are used, there is no limitation in reducing the arrangement interval of the magnetostrictive wires. Therefore, there is a problem that the input resolution is low. In addition, in the case of handwriting input with a pen, it has been extremely difficult to provide, in addition to position information, density gradation information corresponding to the pen pressure at the time of drawing a point and a line segment. Further, there is no function of copying and outputting the input information immediately after the input of the position information.

The present invention has been made in order to solve the above-described problems, and enhances the resolution of position information input, and at the time of point and line segment input such as handwriting input, can also impart density gradation. It is another object of the present invention to provide a position information input device capable of easily copying input information immediately.

Means for Solving the Problems In order to achieve this object, a position information input device according to the present invention comprises a sheet-like storage battery in which a plurality of storage battery cells are arranged in a matrix, and an anode or cathode current collector of the storage battery. A charging circuit for charging the storage battery, and irradiating a light beam with light beam input means after charging, comprising a sheet-shaped photoconductive switch for inputting position information provided in A discharge circuit for discharging the electric charge of the storage battery through the photoconductive switch, and a measurement circuit for measuring the remaining charge amount of the storage battery after the discharge.

In addition, an optical memory element is formed by using a photoelectric conversion element in place of the photoconductive switch, and a charging circuit for charging the storage battery by irradiating the photoelectric conversion element with a light beam, and discharging the storage battery to a predetermined voltage after charging. Thus, a measuring circuit for measuring the amount of charge by light beam irradiation is provided.

Further, in addition to the above configuration, an activation circuit for performing a matrix scan of the optical memory element is provided, and a light beam is input to the optical memory element in a state where the matrix scan is performed.

Similarly, an optical memory element is constituted by a sheet-like storage battery and a photoelectric conversion element or a photoconductive switch, and the charge of the storage battery is charged or discharged by irradiating the photoelectric conversion element or the photoconductive switch with a light beam.・
A discharge circuit, a measurement circuit for measuring the amount of charge / discharge by light beam irradiation by discharging the charged / discharged storage battery to a predetermined voltage, and monitoring the electromotive force of the storage battery before and after charge / discharge by light beam irradiation. Means.

In addition, an optical memory element is constituted by a sheet-shaped storage battery and a photoelectric conversion element or a photoconductive switch, and is provided on a side opposite to a side where the photoelectric conversion element or the photoconductive switch of the storage battery is located and corresponds to a storage battery cell. And a charging / discharging device that charges or discharges the charge of the storage battery by irradiating a light beam to a conductor whose electrical resistance is selectively variable, a developing electrode in contact with the conductor, and a photoelectric conversion element or a photoconductive switch. A discharge circuit and a charged / discharged storage battery are discharged to a predetermined voltage so that the charged / discharged storage battery is charged / irradiated with light beams.
A measuring circuit for measuring the amount of discharge, a recharging circuit for recharging the storage battery with electric charge corresponding to the amount of charge / discharge obtained by the measurement, and a control circuit for selectively variably controlling the electrical resistance of the conductor. The electric charge of the rechargeable storage battery can be discharged through the developing electrode in cell units by selectively lowering the electric resistance of the conductor.

Further, a pressure-sensitive switch is used in place of the photoelectric conversion element or the photoconductive switch, and the same conductor as described above, a developing electrode, and a discharge circuit that discharges the charge through the pressure-sensitive switch after charging the storage battery. , A measuring circuit for measuring the remaining charged amount of the storage battery after discharging, and a recharging circuit and a control circuit similar to the above, and the electric charge of the storage battery recharged by selectively lowering the electric resistance of the conductor. Can be discharged through the developing electrode in cell units.

[Operation] According to the apparatus using the above-described photoconductive switch, first, a certain amount of electric energy is stored in each sheet storage battery by an external power supply, and then, from above the photoconductive switch on the sheet storage battery. By irradiating a light beam with a light pen or the like to turn on the photoconductive switch, each sheet storage battery is discharged according to the resistance of the switch and the ON time derived from the intensity of light incident. As a result, a distribution is generated in the amount of charge stored in the sheet-shaped storage battery divided into many. In order to recognize this as an optical latent image, the sheet storage battery is individually discharged to a specified voltage to obtain bitmap information.

Further, in the case of having a developing electrode in addition to the above configuration, based on the bitmap information obtained as described above, the external power supply recharges electric energy corresponding to the amount of electric charge discharged by light irradiation, Each sheet storage battery is individually discharged by controlling the resistance of the conductor for toner development.

Further, in a device provided with means for monitoring the electromotive force of the storage battery before and after charging / discharging by light beam irradiation, it is possible to eliminate the influence of errors due to self-discharge of the storage battery when obtaining bitmap information.

In a device using a pressure-sensitive switch, a certain amount of electric energy is stored in each sheet storage battery by an external power supply,
Thereafter, by turning on the pressure-sensitive switch with the input pen, each sheet-shaped storage battery is discharged according to the resistance value and the ON time of the pressure-sensitive switch. As a result, a distribution occurs in the amount of charge stored in the storage battery. Thereafter, bitmap information is obtained in the same manner, and an operation for toner development is performed.

In addition, in order to perform labeling of points and line segments, it is only necessary to address the input position when inputting position information by input means such as a light beam.

[Examples] Hereinafter, embodiments of the present invention will be described with reference to the drawings.

 1 to 6 show a first embodiment of the present invention.

FIG. 1 is a cross-sectional view of an optical memory element alone in the position information input device, FIG. 1 is an arrangement configuration of the optical memory element, and FIG. 3 is an overall view including an optical memory element, a toner developing electrode unit and an electric circuit in the present input device. FIG. 4 shows the configuration of a conductor (thermistor switch) for individually discharging a storage battery for toner development in the electrode section, and FIG. 5 shows the configuration of each member of the optical memory element alone and the electrode section. FIG. 6 shows a schematic configuration of an optical memory element and an electric circuit in the present input device, respectively.

In FIG. 1, a sheet storage battery 1 and this storage battery 1
Position information input unit 2 comprising a photoconductive switch formed above
(Hereinafter, referred to as an input unit) constitutes the optical memory element 3. The sheet-shaped storage battery 1 includes an anode current collector 4 such as Ni.
, An anode 5 composed of V ₆ O ₁₃ , V ₂ O _5, etc., an electrolyte 6 composed of a polymer electrolyte or the like obtained by mixing LiClO _{4 in} a polyethylene derivative, a cathode 7 composed of a Li—Al alloy, and a cathode And an electric body 8. The input unit 2 composed of a photoconductive switch is
A protective film 9 made of a film such as polyester;
Discharge electrode 10 made of a transparent conductive material such as ITO, TiO ₂ , Z
It is formed from nO, a photoconductive substance 11 such as an organic photoconductive substance. The input is performed by irradiating light from above the protective film 9 as described later. Further, in this embodiment, the input unit (photoconductive switch) 2 is provided on the anode current collector 4, but may be provided on the cathode current collector 8.

A position input sheet member configured by arranging and coupling a plurality of optical memory elements as described above in a matrix in the X and Y directions.
12 is shown in FIG. The member 12 is a protective film 9
And an element portion 13 including a photoconductive switch arranged in a matrix, a sheet storage battery including storage battery cells, a thermistor switch material, and a toner developing electrode (a part of which corresponds to the optical memory element 3 in FIG. 1). And a lead-out electrode 14 composed of a discharge electrode, a cathode current collector, and a heating internal electrode, and a lead-out electrode composed of a discharge electrode, a cathode current collector, and a heating internal electrode.
15 is formed.

In FIG. 3, the same reference numerals as those described above denote the same members, and on the lower surface of the cathode current collector 8 of the storage battery in the element portion 13, a conductor (16) whose electric resistance is selectively variable corresponding to each storage battery cell is provided.
22) and an electrode 23 for toner development in contact with the lower surface of the conductor. The conductor is a thermistor switch, and includes a thermistor material 16, an insulating layer 17, a Y-direction heating element electrode 18, a heating element 19, and an X-direction heating element electrode 20.
, An insulating layer 21 and a thermistor material 22. Note that 24
27 are insulating resists.

The detailed structure of the thermistor switch section is as shown in FIG. 4 so that the heating element located at the intersection of the heating element electrodes in the X and Y directions generates heat, and the resistance of the thermistor section in that portion decreases. It is configured. The shape of each of the above members is as shown in FIG.

Next, the extraction electrode and its electric circuit will be described with reference to FIGS. Controller 30, X, Y
This is for performing a matrix scan with respect to various electrodes in the direction, and a shift register or the like may be used as a configuration means of the switch. In this controller 30, switches 31 and 32 are connected to the anode current collector 4 and the discharge electrode 10.
(Y direction) is switched to the cathode current collector 8 by a switch 33 (X direction).
However, a switch 34 (Y direction) is connected to the heating element electrode 18, and a switch 35 (X direction) is connected to the heating element electrode 20, respectively. The switch 36 and the external power supply 37 constitute a charging circuit for charging the storage battery 1 through the switches 31 and 33, and the discharging resistor 38 is connected to the charge of the storage battery through the switches 32 and 33 and the input unit (photoconductive switch) 2. Configure a discharge circuit to discharge the switch
The resistance (measurement load) 40 constitutes a measurement circuit for measuring the remaining charge amount of the storage battery after discharge (taken out as bitmap information). The switch 41 and the external power supply 42
Constitutes a power supply circuit for generating heat from the heating element 19 via the switches 34 and 35.

Further, the toner spray 43 and the switch 44 located below the toner developing electrode 23 constitute a developing unit for developing the toner on the toner developing electrode 23 via the switch 31. Each switch in the controller 30 is controlled by the CPU 45, and measured data is stored in the memory 46.

In FIG. 6, switches S1, S2,... Correspond to the switch 33, and switches S11, S21,.
, And the switches S12, S22,... Correspond to the switch 32. Also, the measurement was performed by the CPU 45 by connecting the terminals 40
This is done by reading the voltage of

 Next, the operation of the above configuration will be described.

When the switch 36 is turned on for a certain period of time and the switches 31 and 33 are sequentially switched, an external power supply (preferably a constant current power supply)
A specified amount of current is supplied to the sheet storage battery 1 from 37 to store electric energy. Next, all switches 32 and 33 are turned on.
When the input pen 50 that emits a light beam emits light from above the photoconductive switch 2, the switch 2 is turned on, and the intensity of the light beam (the light irradiation intensity increases when the pen is pressed strongly) and The storage battery 1 is discharged through the discharge electrode 10 according to the irradiation time. In this way, a storage amount distribution occurs in the storage battery 1, and an optical latent image is formed.

Next, the switch 39 for reading the optical latent image to the outside as bitmap information is turned on, and the switches 31 and 33 are sequentially switched to measure the remaining charge amount of each storage battery 1 with the load 40. The remaining charge amount thus measured is stored in the memory 46 as bitmap information. According to the above-described operation, an input can be performed in which density gradation is given to a point or a line segment according to the pen pressure at the time of handwriting input with the input pen 50, and the information can be obtained.

Next, based on the held bitmap information, the sheet-like storage battery 1 is charged again by the external power supply 37 with a charge corresponding to a discharge charge amount (= initial charge amount-remaining charge amount). Thereafter, the switches 34 and 35 are sequentially switched by the external power supply 42 to energize the heating element 19, and the heating element 19 is selectively heated to heat the thermistor materials 16 and 22. Lower the resistance. Then, a negative charge is selectively supplied to the developing electrode 23. If switch 44 is turned ON in this state,
The toner is attracted to the developing electrode 23 by the electrophoresis and the electrodeposition effect from the toner spray 43, and the toner is developed.
Thereafter, if a toner transfer sheet (not shown) is supplied and the toner is transferred onto the sheet, a toner image corresponding to the optical latent image is obtained, and the subject becomes possible.

When labeling the position information of points and line segments, an index corresponding to a time axis may be added when inputting with the input pen 50.
What is necessary is just to determine in advance the timing of switching sequentially between 2, 33 and address the input position.

If the input pen 50 emits ink along with light, the input can be performed while viewing the ink image on the protective film 9.

 Next, a second embodiment of the present invention will be described.

This embodiment is different from the photoconductive switch 2 in the above embodiment.
Instead, a photoelectric conversion element is used. FIG. 7 is a diagram corresponding to FIG. 1 according to the present embodiment.

In FIG. 1, an optical memory element 103 includes a sheet-shaped storage battery 1 and an input unit 102 formed of a photoelectric conversion element formed on the storage battery 1.
, A transparent electrode 10, and a photoelectric conversion element 111 made of n-Si and p-Si. Other configurations are the same as in the first embodiment. In this embodiment, first, the external power supply 37 and the switch 3
The discharge end voltage of the sheet-shaped storage battery 1 is kept constant by a charge / discharge circuit composed of the load 6, 39 and the load 40. Next, the storage battery 1 is charged by irradiating the photoelectric conversion element 111 with the light beam input pen 50 while the switches 32 and 33 are turned on. As a result, a distribution of the charge accumulation amount occurs in the storage battery 1, and an optical latent image is formed. The following operation is the same as described above.

 Next, a third embodiment of the present invention will be described.

This embodiment is different from the second embodiment in that the ON / OFF state of the optical memory element is set to a high-speed matrix scan state, and a light beam is input to this optical memory element. That is, when the light beam is input, the switches 32 and 33 are turned on in the above-described embodiment. Instead, the switches 32 and 33 are set to a state in which the matrix scan is performed. In this way, the timing of the ON state of each optical memory element can be grasped on the time axis, so that the position information when light enters can be recognized by the XY coordinate values.

 Next, a fourth embodiment of the present invention will be described.

In the present embodiment, the electromotive force of the sheet storage battery before and after light emission or light charging in the first or second embodiment is monitored. The configuration of this embodiment is the same as that described above, and the operation will be described with reference to FIGS. 8 (a) and 8 (b). These figures show the profiles of the electromotive force of the sheet storage battery.

FIG. 8 (a) shows a case where a light-charge type memory element using a photoelectric conversion element is used. Irradiation is performed at time t0, discharge is started at time t1 to measure the amount of stored electricity, and time t2. The discharge is terminated by. By the way, the electromotive force E0 of the storage battery before light charging is usually not strictly constant because of self-discharge. Therefore, in the present embodiment, the electromotive force E0 before light charging is monitored, and after the electromotive force E1 rises, if the discharge end voltage at the time of performing the discharge for measurement is set to E0, the discharge end voltage is set to E0. (At t2) can be set accurately. Therefore, the storage battery can be individually discharged to the specified voltage, and correct bitmap information can be obtained.

FIG. 8 (b) shows a case where a photo-discharge type memory element using a photoconductive switch is used, in which the entire surface is charged at time t0, irradiated with light at time t1, and measured and discharged at time t2. Discharge is stopped at t3. Here is the time immediately before light charging
The electromotive force E0 at t0 is monitored. After being promoted to electromotive force E1,
The electromotive force is reduced to the E2 level by light irradiation. Next, assuming that the end voltage of the measurement discharge is E0, the time t3 can be set accurately, and correct information can be obtained.

 Next, a fifth embodiment of the present invention will be described.

In this embodiment, a pressure-sensitive switch and a normal input pen are used in place of the above-described photoconductive switch, photoelectric conversion element, and light beam input pen.

FIG. 9 shows a sectional configuration of the pressure-sensitive memory element according to the present embodiment, and FIG. 10 shows an overall configuration of the input device. As shown in these figures, in the present embodiment, the pressure-sensitive memory element 203 includes the sheet-shaped storage battery 1 and an input unit 202 including a pressure-sensitive switch, and the input unit 202 includes the protective film 9 and the white background agent. 212, a discharge electrode 10, and a pressure-sensitive switch 211. The sheet storage battery 1 has a plurality of storage cells arranged and coupled in a matrix in the same manner as described above, and an input unit 202 is provided for each cell. The element portion 213 is composed of the pressure-sensitive memory element 203 having the above configuration, thermistor materials 16 and 22 for individual discharge for toner development, and the developing electrode 23. input. Other configurations are the same as those described above.

The operation of the present embodiment is similar to that of the above-described discharge type memory element, in which a predetermined amount of electric energy is first stored in the sheet storage battery 1 by ON / OFF of each switch of the charge / discharge circuit. Then, the electric charge is discharged through the discharge electrode 10 by pressing the pressure-sensitive switch 211 with the input pen 250. Hereinafter, the operation is the same as that described above, and the description is omitted. With this input device, the same effect as in the previous embodiment can be obtained.

[Effects of the Invention] As described above, according to the present invention, the charge and discharge of the storage battery is performed by irradiating light with a light beam input pen, using an optical memory element including a sheet storage battery and a photoconductive switch or a photoelectric conversion element. By inputting position information to obtain bitmap information, it is easy to increase the resolution of the input position, and it is also possible to impart density gradation to the data of point and line segment inputs. it can.

By inputting a light beam in a state where the optical memory element is scanned in a matrix, it is possible to label input information.

Further, by monitoring the electromotive force before and after charging / discharging of the storage batteries, accurate input information can be reproduced even if the charging / discharging characteristics of the individual storage batteries are different.

Further, in the case where the storage battery is provided with a developing electrode for individually discharging each cell, the optical latent image by the input pen can be easily copied on the spot.

Further, a pressure-sensitive switch is used in place of the photoconductive switch or the photoelectric conversion element, and the storage battery includes a developing electrode that individually discharges each cell.
It is possible to impart density gradation to the data of the line segment input, and it is possible to easily copy the pressure-sensitive latent image on the spot.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of an optical memory element used alone in a position information input device according to an embodiment of the present invention, FIG. 2 is a plan view showing an arrangement configuration of the optical memory element, and FIG. FIG. 4 is an overall configuration diagram including a toner development electrode unit and an electric circuit. FIG. 4 is a configuration diagram of a conductor (thermistor switch) for individually discharging a storage battery for toner development in the electrode unit. a) to (m) are plan views showing the shape of an optical memory element alone and each member of an electrode portion, FIG. 6 is a schematic configuration diagram of an optical memory element and an electric circuit in the input device, and FIG. 8 (a) and 8 (b) are cross-sectional views of an optical memory element according to an embodiment, FIGS. 8 (a) and 8 (b) are diagrams showing profiles of electromotive force of a sheet storage battery, and FIG. 9 is a pressure-sensitive memory element used in a fifth embodiment of the present invention. Sectional view of single unit, No. 10
FIG. 1 is an overall configuration diagram of a position information input device in the case of this embodiment. DESCRIPTION OF SYMBOLS 1 ... Sheet storage battery, 2 ... Position information input part which consists of a photoconductive switch, 3 ... Optical memory element, 11 ... Photoconductive substance, 12 ... Sheet member for position input, 13 ... Element part, 1
6,22: Thermistor material (conductor), 19: Heating element, 23 ...
… Electrode for toner development, 31, 32, 33, 36, 39… switch, 37
... external power supply, 38 ... discharge resistor, 40 ... resistance (measurement load), 45 ... CPU, 46 ... memory, 50 ... light beam input pen, 102 ... position information consisting of photoelectric conversion elements Input section, 1
03: Optical memory element, 111: Photoelectric conversion element, 202: Position information input section consisting of pressure sensitive switch, 203: Pressure sensitive memory element, 211: Pressure sensitive switch, 213: Element section, 250 ...
Input pen.

Claims (6)

(57) [Claims] 1. An optical memory device comprising: a sheet-like storage battery in which a plurality of storage battery cells are arranged in a matrix; and a sheet-like photoconductive switch for inputting positional information provided on an anode or a cathode current collector of the storage battery. And a charging circuit for charging the storage battery, a discharge circuit for discharging the charge of the storage battery through the photoconductive switch by irradiating a light beam by light beam input means after charging, and A position information input device, comprising: a measurement circuit for measuring a remaining charge amount of a storage battery. 2. An optical memory device comprising: a sheet-like storage battery in which a plurality of storage battery cells are arranged in a matrix; and a sheet-like photoelectric conversion element for inputting positional information provided on an anode or a cathode current collector of the storage battery. And a charging circuit for charging the storage battery by irradiating the photoelectric conversion element with a light beam by a light beam input unit, and discharging the storage battery to a predetermined voltage after charging to reduce a charge amount by the light beam irradiation. A position information input device, comprising: a measurement circuit for measuring. 3. An optical memory device comprising: a sheet-like storage battery in which a plurality of storage battery cells are arranged in a matrix; and a sheet-like photoelectric conversion element for inputting positional information provided on an anode or a cathode current collector of the storage battery. And a charging circuit for charging the storage battery by irradiating the photoelectric conversion element with a light beam by a light beam input unit, and discharging the storage battery to a predetermined voltage after charging to reduce a charge amount by the light beam irradiation. A position information input device comprising: a measurement circuit for measuring; and a starting circuit for causing the optical memory element to perform a matrix scan, and wherein a light beam is input to the optical memory element in a state where the matrix is scanned. 4. A sheet-like storage battery in which a plurality of storage cells are arranged in a matrix, and a sheet-like photoelectric conversion element or photoconductive switch for inputting positional information provided on an anode or a cathode current collector of the storage battery. A charge / discharge circuit for charging or discharging the storage battery by irradiating the photoelectric conversion element or the photoconductive switch with a light beam by a light beam input means; And a means for monitoring the electromotive force of the storage battery before and after charging / discharging by the light beam irradiation by discharging the storage battery to a predetermined voltage. A position information input device, characterized in that: 5. A sheet-shaped storage battery in which a plurality of storage cells are arranged in a matrix, and a sheet-shaped photoelectric conversion element or a photoconductive switch for inputting positional information provided on an anode or a cathode current collector of the storage battery. And an optical memory element, and a conductor whose electrical resistance is selectively variable corresponding to the storage battery cell provided on the side opposite to the side where the photoelectric conversion element or the photoconductive switch of the storage battery is located,
A developing electrode in contact with the conductor; a charging / discharging circuit for charging or discharging the storage battery by irradiating the photoelectric conversion element or the photoconductive switch with a light beam by a light beam input means; A measuring circuit for measuring the amount of charge / discharge by irradiating the light beam by discharging the storage battery to a predetermined voltage; and a circuit for recharging the storage battery with a charge corresponding to the amount of charge / discharge obtained by the measurement. A charge circuit, and a control circuit for selectively variably controlling the electric resistance of the conductor, and selectively lowering the electric resistance of the conductor to develop the recharged electric charge of the storage battery in units of cells. A position information input device characterized in that discharge can be performed through an electrode. 6. A sheet-shaped storage battery in which a plurality of storage cells are arranged in a matrix, a sheet-shaped pressure-sensitive switch for inputting positional information provided on an anode or a cathode current collector of the storage battery, A conductor which is provided on the side opposite to the side where the pressure-sensitive switch is located, and which has a variable electric resistance selectively corresponding to the storage battery cell, a developing electrode in contact with the conductor, and a charge for charging the storage battery; Circuit, a discharge circuit for discharging the charge of the storage battery through the pressure-sensitive switch after charging, a measurement circuit for measuring the remaining charge amount of the storage battery after discharge, and a charge circuit corresponding to the remaining charge amount obtained by this measurement. A recharging circuit for recharging the battery, and a control circuit for selectively variably controlling the electrical resistance of the conductor. Position information input device, characterized in that the adapted to discharge through the developing electrode a charge of the battery cell by cell.