JPH02272617A - Position detector - Google Patents

Abstract

PURPOSE:To save power by automatically disconnecting a power supply of a prescribed circuit when an instruction is not issued from a position indicator to a position detecting part within a previously set time interval. CONSTITUTION:When the position indicator 3 is arranged on the outside of the position detecting part 1 of the position indicator 3, radio waves are not received by a receiving circuit 6 and the no reception state is detected by a processor 8. At the time of judging that no radio wave is received within a previously set time (several seconds or several-ten seconds), the processor 8 turns off a power supply switching means 25. Thereby, power is not supplied to a selection circuit 4, a transmitting circuit 5, a receiving circuit 6, and a switching circuit 7. Since only the power supply of a switch driving part in the position detector is disconnected when an input state is not set up, power consumption can be saved.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a position detection device that detects coordinate values on a tablet indicated by a position indicator. The present invention relates to a position detection device that saves power by turning off the power to a control system of a tablet when there is no position indication by a position indicator on the tablet.

[Conventional technology]

It has a position detecting section in which a large number of signal lines are arranged side by side in the X and Y directions at predetermined intervals on a substrate, and a position indicator that indicates an arbitrary position to be measured on the position detecting section. , a position detection device that sequentially drives an X-direction signal line and a Y-direction signal line, and identifies the position of a position indicator by capturing the position of the position indicator using x-y coordinate values.
They are widely used as graphic and character input devices called tablets and digitizers, and small, portable position detection devices have also come to be provided.

Portable position detection devices are powered by batteries so that they can be used even in places where commercial power is not available, and low power consumption is desirable to allow them to be used for long periods of time without replacing batteries. It is rare.

[Problem to be solved by the invention]

In order to prevent wasted battery life and wasteful consumption, conventional methods have been used to automatically turn off the power if no instructions are given after a predetermined period of time, such as 3 or 5 minutes, after the power is turned on. , a power-saving method has been adopted in portable computers that clears all previously entered information. On the other hand, in devices such as word processors that store input information sequentially in memory, the power to the memory is left as is, and only the other circuits and display sections are turned off. A power saving method is adopted in which the stored information is maintained in the state stored in memory.

Even in the above-mentioned position detection device, position information is stored in the memory, so the word processor type power saving method is useful, but when the usage status is further considered,
When inputting figures and characters, there are two cases: continuous input and input information while thinking about the input information.In the latter case, there may be a considerable amount of blank time even during the input operation. In a normal position detection device, if there is no instruction to the position detection unit by the position indicator, all-scanning or all-around scanning in which all signal lines are scanned is repeatedly performed, but one scan The power consumption required for cleaning is, for example, several hundred mW, which is not trivial.

Therefore, an object of the present invention is to automatically input a predetermined signal when there is no instruction from the position indicator to the position detection unit within a preset time interval even during the input to the position detection unit by the position indicator. It is an object of the present invention to provide a position detection device that saves power by turning off the power of the circuit.

[Means to solve the problem]

The present invention includes a position detection section in which a large number of signal lines are arranged side by side in the X direction and Y direction at predetermined intervals on a substrate, and a position indicator for indicating an arbitrary position to be measured on the position detection section. , a switching drive section that sequentially switches and drives the signal lines in the X direction and the signal line in the Y direction, a processing section that captures the position of the position indicator using X-Y coordinate values, and a processing section that captures the position data from this processing section. The position detection device has a power supply for the switching drive unit and a power switch unit that is connected between the switching drive unit and is switched by the processing unit, and the processing unit stores information at a preset time. The present invention is characterized in that when it is detected that the position indicator is not on the position detection section within the vehicle, the operation of the power switch section is controlled at predetermined intervals.

[For production]

By configuring as described above, if the position indicator is not in the input state and the position detection unit cannot confirm the presence of the position indicator, the processing unit turns off only the power to the switching drive unit of the position detection device. Since the power switch section is operated, the power consumption of this switching drive section can be saved, and in a position detection device of the type that is driven by an internal/la battery, battery consumption can be reduced accordingly. In this case, the time required for one all-scanning is about several times,
If this is done once or several times every few hundred fertilizations and the power to the tube is turned off, power consumption can be significantly reduced.

〔Example〕

An embodiment of the present invention shown in the drawings will be described below. This embodiment takes as an example a case in which the application is applied to a digitizer that detects a position specified in two dimensions in the X direction and the Y direction, and the position detection unit and position designator are The one published on March 30, 1988 as 1987-70326 is used.

Its main configuration is to connect multiple loop coils in the X direction and Y direction.
A resonant circuit 2 composed of a plurality of position detection units 1 arranged at a predetermined pitch in a direction, and a coil and a capacitor.
A selection circuit 4 comprising a multiplexer etc. that sequentially selects one loop coil from the plurality of loop coils of the position detection unit 1, and a reference wave of a predetermined frequency to be supplied to the loop coil. Transmitting circuit 5 for transmitting
, a receiving circuit 6 that receives the signal from the position indicator 3 via the loop coil, a switching circuit 7 that connects the selected loop coil to the transmitting circuit 5 and the receiving circuit 6, and induction generated in each loop coil. A processing device 8 is provided for determining the designated position of the position n indicator from the voltage.

In FIG. 1, the position detection unit 1 shows only the loop coils in the X direction, and the selection circuit 4 also shows only the selection circuit for these loop coils in the X direction, and these will be described in detail. Each X-direction loop coil 1 of the position detection unit 1
1-1, 11-2, . . . 11-n are each formed into a rectangular pattern so as to have two straight portions located at a predetermined interval in the X direction. One terminal of each of these X-direction loop coils 11-1, 11-2, . 11-2...
The other terminals of the terminals 11-n are connected to the second terminal board 13 in the 1 selection circuit 4. The first terminal board 12 has a first switching element 14, and the second terminal board 13 has a second switching element 15.
are connected to each other in a switchable manner. The first and second switching elements 14 , 15 are switched and controlled by the processing device 8 . The first switching element 14 is connected to the transmission switching element 16 of the switching circuit 7, and the second switching element 15 is connected to the reception switching element 17 of the switching circuit 7. The transmitting switching element 16 and the receiving switching element 17 are linked to each other in the transmitting circuit 5.
and the receiving circuit 6, and this switching is controlled by the processing device 8.

A reference wave as shown in FIG. 2(a) is output from the transmitting circuit 5, and this reference wave is transmitted at preset time intervals as shown in FIG. 2(b). Then, the processing device 8 controls the transmission switching element 16 and the reception switching element 17 of the switching circuit 7. This signal is sequentially sent from the switching circuit 7 to the loop coil of the position detection section 1 via the selection circuit 4, and radio waves are transmitted from the loop coil. The resonant circuit 2 of the position indicator 3 is set in advance to have the same resonance frequency as the reference wave, and when the position indicator 3 is positioned near a desired loop coil, the position indicator 3 will be connected to the loop coil. Upon receiving the radio waves transmitted from the resonant circuit 2, the resonant circuit 2 starts resonating. When the switching circuit 7 is switched to the receiving circuit 6 side in this state, an electromotive force is generated in the loop coil by the radio waves from the position indicator 3 containing the resonant circuit 2 which continues to resonate due to the energy stored in the resonant circuit 2. This electromotive force causes the received waveform to be transmitted to the receiving circuit 6. The waveform of the resonant circuit 2 is as shown in FIG. indicates that when the resonant circuit 2 is in the receiving state, that is, the resonant circuit 2 is in the transmitting state, the resonance energy decreases due to the internal loss of the resonant circuit 2. When the loop coil is in the receiving state, the switching circuit 7 causes the receiving circuit 6 connected to the loop coil to receive a waveform as shown in FIG. 2(d). The loss of transmitted and received energy is smaller as the distance between the loop coil and the position indicator 3 is shorter. You can know the position of 3. That is, assuming that the position indicator 3 is now located above the loop coil 11-3, this loop coil 11-3 and its neighboring loop coils 11-1.11-2.11-4.11-5 ．．
The voltage generated or detected at 1-16 is as shown in FIG. 3, and it can be determined that the position indicator 3 is located above the loop coil 11-3 with the highest voltage.

A detailed explanation of the above-mentioned configuration and operation is given in the above-mentioned Japanese Patent Laid-Open No. 63-70326, so it will be omitted here.

In this embodiment, the power terminal 21 includes a processing device 8,
and a central processing unit (CPU) consisting of a microcomputer, etc. that analyzes and processes the position information from the processing device.
22, and a backlight 24 of a display 23 connected to the CPU 22 and configured with a liquid crystal panel or the like that displays information input to the position detection unit 1 by the position indicator 3.
are directly connected, but the selection circuit 4 and the transmission circuit 5
, the receiving circuit 6 and the switching circuit 7 are connected to the power switch means 25.
It is connected to the power supply terminal 21 via. The power switch means 25 is connected to the processing device 8 so that the processing device 8 turns on and off the power switch means 25 . 26 is a memory that stores position information detected by the CPU 22.

Next, the operation of this device will be explained according to the flowchart shown in FIG. While information is being written onto the position detecting section 1 by the position indicator 3, the information is stored in the memory 26 in the same manner as in the prior art (step 1). Now, when the position indicator 3 is outside the detection range of the position detection section 1, the reception circuit 6 does not receive radio waves.

Since this can be detected in the processing device 8, the processing device 8
When the processing device 8 determines that there is no received radio wave for a preset time 5, for example, from several seconds to several seconds (step 2
), the processing device 8 turns off the power switch means 25 (
Step 3). As a result, power is no longer supplied to the selection circuit 4, transmission circuit 5, reception circuit 6, and switching circuit 7 (step 4).The power supply is cut off to a degree that does not increase the time difference between inputting coordinates and detecting the coordinates. 1, for example, for several tens to hundreds of hours, and then the processing device 8 turns on the power switch means 25 again (step 5). By turning on the power to the selection circuit 4, transmission circuit 5, reception circuit 6, and switching circuit 7, the coordinate input is detected again (
Step 6) If the receiving circuit 6 receives radio waves, it enters the normal operation of step 1. If the receiving circuit 6 still does not receive radio waves, the circuit power is cut off in step 3 and the received radio waves are confirmed. Repeat this loop until there is.

FIG. 5 shows a detailed embodiment of the power switch means 25. In this embodiment, two fl!s having equal absolute values and opposite polarities are used. It is designed to provide a source of energy. That is, the input terminal 31 of the signal indicating the presence or absence of received radio waves from the processing device 8 has first and second field effect transistors (
FET) is connected to each gate of 32.33.

The sources of the first and second FETs 32 and 33 are connected to the +V input side of the power supply, and the drain of the first FET 32 is connected to the +V output side. 2nd FET3
The drain of FET 3 is connected to the third FET 36 through the first and second resistors 34 and 35, each having the same resistance value and connected in series.
connected to the source. The input side of the power supply (-) is also connected to the source of the third FET 36. 3rd FE
The gate of T36 is connected to the connection point of the first and second resistors 34.35, and the drain thereof is connected to the -V output side.

Therefore, when a voltage of 10 V is applied to the input terminal 31, there is no conduction between the sources and drains of the first and second FETs 32 and 33, and therefore the gate-drain of the third FET 36 does not conduct.
Since the sources are also at the same potential and there is no conduction between the source and drain of the third FET 36, the power source 10 is not supplied to the circuit connected to its output side. Next, input terminal 31
When Ov is applied to the first and second F E T32.
33 sources and drains are electrically conductive, and the first and second
The gate of the third FET 36 also becomes OV due to the resistance voltage division of the resistors 34 and 35, and the source and drain of the third FET 36 are also conductive. Therefore, when there is no received signal, the processing device 8
The power can be turned on and off by outputting +V voltage from the processing device 8 and outputting Ov from the processing device 8 when there is a received signal. If the power supply voltage is 5V, this power switch means can directly use the existing digital integrated circuit for the power supply.

FIG. 6 shows another detailed embodiment of the power switch means 25. In this embodiment, there are five voltage values +Vl.
, +V2. -V3. -V4. -V5. That is, a sixth FET42 whose gate is connected to the input terminal 31 and whose source is connected to the +5V input terminal 41, and a resistor connected in series with the same resistance value from the drain of this sixth FET42. 7th FE whose source is connected via 43.44
T45 outputs the power of vl. 7th
The source of FET45 is connected to the +V1 input terminal, and its drain is connected to the +v1 input terminal. 8th and 9th FET4 with similar connection configuration
6.49 and resistor 47.48 to output +V2 power, 10th and 11th F E T51.54 and resistor 52.53 Qi V3 (7) to output power,
12th and 13th F E T55.58 and resistor 56.
57 to output -v4 power, 14th and 15th FET59.63 and resistor 61.62 to output -v4 power.
It is designed to output power. The output voltage is set by each resistor 43.44:47.48;52.53;56.57
;Resistance voltage division ratio of 61.62! I! Ill do it.

This circuit can also directly use existing digital integrated circuits for power supplies. Note that in this embodiment, vl
and vl are positive voltages, ■3 to ■5 are FET51゜52
; 55.58: I am trying to extract the Mavenous voltage by changing the polarity of 59.63, but the FE
By changing the polarity of T, plus and minus can be set arbitrarily.

The circuit of the power switch means 25 described above uses FETs through which almost no current flows through their gates, so if FETs with low on-resistance between drain and gate are used, the power consumption in these circuits can be reduced. rare.

In the above-mentioned embodiment, the position detection section 1 is merely an example, and the present invention can be applied to any type of coordinate input device that performs scanning. In the case of an electromagnetic induction type coordinate input device of the type in which the 1 position indicator detects the ff1l field from the loop coil, the power may be turned on and off when the position indicator cannot detect a signal. Furthermore, if the power terminals of the backlights 1-24 of the display 23 are connected to the output side of the power switch means 25, the backlight 24 can save power.

〔Effect of the invention〕

As described above, the position detecting device of the present invention connects the power switch section, which is switched and operated by the processing section, between the power supply for the switching section and the switching section, and the processing section operates at a preset time. When it is detected that the position indicator is not on the position detection part within the vehicle, the power switch part is controlled to be turned off at predetermined intervals. Therefore, when the position detecting section cannot confirm the presence of the position indicator, that is, when it is not in the input state, only the power to the switching drive section of the position detecting device is turned off, and the power consumption of this switching drive section can be saved. In a battery-powered position detection device, battery consumption can be reduced accordingly.

Also, if scanning is performed once or several times every few hundred liters, and the power is turned off in between,
Compared to the conventional case where scanning is repeated continuously, the size can be significantly reduced, for example, by several tens of minutes.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention, and FIG.
Figures (a) to (d) are diagrams showing the timing of signal transmission and reception and their waveforms, Figure 3 is a diagram showing the power waveform generated in the loop coil in the vicinity of the position indicator, and Figure 4 is a diagram showing its operation. FIG. 5 is a circuit diagram showing a specific embodiment of the power switch means, and FIG. 6 is a circuit diagram showing another embodiment of the power switch means. In the drawings, 1 is a position detection section, 2 is a resonant circuit, 3 is a position indicator, 4 is a selection circuit, and 5 is a transmission circuit. 6 is a receiving circuit, 7 is a switching circuit, 8 is a processing device, 11-1
．． 11-2...11-n are X-direction loop coils. 21 is a power supply terminal, 22 is a CPU, 23 is a display,
24 is a backlight, 25 is a power switch means, and 26 is a memory. Figure 1 Figure 1 Figure

Claims (1)

[Claims] (1) A position detection section in which a large number of signal lines are arranged side by side in the X and Y directions at predetermined intervals on a substrate, and a position indicator on this position detection section that indicates an arbitrary position to be measured. , a switching drive unit that sequentially switches and drives the signal line in the X direction and the signal line in the Y direction, a processing unit that captures the position of the position indicator using X-Y coordinate values, and a position from this processing unit. A position detection device having a storage unit for storing data, the position detection device having a power switch unit connected between a power source for the switching drive unit and the switching drive unit and switched by the processing unit, the processing unit A position detection device characterized in that when it is detected that the position indicator is not on the position detection unit within a preset time, the operation of the power switch unit is controlled at predetermined intervals.