JP2731356B2 - Position detecting device and position indicator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a position detecting device using radio waves and an improvement of the position pointing device.

[0002]

Prior to this application, the applicant filed Japanese Patent Application No. Sho 61
No. 213970 (refer to Japanese Patent Application Laid-Open No. 63-70326) (hereinafter referred to as the prior application 1), radio waves are exchanged between the position indicator and the tablet to determine the position indicated by the position indicator. A position detection device for obtaining coordinate values was proposed.

[0003] The content of the prior application 1 will be briefly described. An electric wave of a predetermined frequency is transmitted from a loop coil of a tablet, and the electric wave is received by a resonance circuit provided in a position indicator. At this time, a radio wave transmitted from the resonance circuit that has received the radio wave is received by the loop coil to generate an induced voltage. This is repeated by sequentially switching the plurality of loop coils of the tablet, and the coordinate value of the designated position is obtained based on the level of the induced voltage generated in each loop coil.

In this type of position detecting device, in addition to the coordinate value of the designated position, information indicating a state where the designated position to be actually input is specified (pen down state), the type of the position indicator, for example, a pen or a cursor. Or information for changing parameters other than coordinate values, such as the thickness of a line, hue and density (brightness) of a designated position or designated region, depending on software, together with the coordinate value of the designated position. There is a request to enter.

[0005] In the above-mentioned prior application 1, by connecting another capacitor to a coil and a capacitor constituting a resonance circuit via a manual switch, the resonance frequency is slightly changed according to the operation on the switch. The slight change in the resonance frequency is detected as a change in the phase angle, and is used as the above-described various information.

However, in the device of the prior application 1, the range of the detectable phase angle is limited to about −60 ° to + 60 °, and the inductance of the coil and the capacitance of the capacitor change due to a change in ambient temperature and the like. For this reason, the number of information that can be input cannot be increased so much because of the problem that the phase angle at the time of the detection must have a certain width, and in particular, the resonance frequency is continuously varied depending on the pen pressure. However, there is a problem that information other than the pen pressure information cannot be input at all.

Further, as an application of the prior application 1, Japanese Patent Application No. 63-308712 (refer to Japanese Unexamined Patent Application Publication No. 2-155019) (hereinafter referred to as prior application 2) resonates according to the pen pressure. A position indicator having a resonance circuit capable of changing the frequency continuously within a predetermined frequency range and changing the frequency range to one of a plurality of different frequency ranges according to ON / OFF of a side switch. We have proposed a device that can input multiple pieces of pen pressure information for different purposes or pen pressure information and other information using a device.

However, in the above-described apparatus of the prior application 2, since the range of the phase angle with respect to the predetermined frequency is divided into a plurality of different frequency regions according to the on / off of the side switch, the pen pressure can be detected. As the range becomes smaller, the phase angle with respect to one pen pressure when the side switch is turned on and the phase angle with respect to the one pen pressure when the side switch is turned off are completely different, so that the pen pressure information for the phase angle can be corrected. There is a problem that different correction values are required for each.

Further, as an application of prior application 2, Japanese Patent Application No. 4-36508 (hereinafter, referred to as prior application 3) discloses a method in which the center of a resonance frequency is set in advance in accordance with a switch operation. And a position indicator having a resonance circuit whose resonance frequency changes continuously around at least one of the plurality of frequencies according to the pen pressure while changing to any one of the above frequencies. Transmitting a radio wave of a plurality of frequencies to the device, receiving a radio wave reflected from the resonance circuit, detecting a coordinate value and a phase angle of a designated position from the radio wave, and setting the resonance frequency of the resonance circuit to the plurality of frequencies. By determining which of the above, a plurality of pen pressure information or pen pressure information and other information can be input, without reducing the range in which pen pressure can be detected, and It was proposed device capable of easily correcting the pen pressure information for the phase angle.

[0010]

However, in the device of the above-mentioned prior application 3, the center frequencies of the plurality of resonance frequencies that change according to the switch operation do not overlap each other when the resonance frequencies change according to the pen pressure. Since it is necessary to set a plurality of frequencies apart from each other, it is necessary to adjust a plurality of resonance frequencies and to require a wide frequency range.

It is an object of the present invention to input simple information, for example, pen-down information, without requiring an accurate adjustment of the resonance frequency and without any hardware configuration for detecting a change in the phase angle. An object of the present invention is to provide a position detecting device and a position indicator thereof.

It is another object of the present invention to easily input the information, particularly the pen pressure information and other information without requiring a wide frequency range, in which the structure of the position pointer and the adjustment of the resonance frequency are simple. The present invention provides a position detecting device and a position pointing device therefor.

[0013]

According to the present invention, there is provided a position detecting device for detecting, on a tablet, a position indicated by a position indicator having a resonance circuit including at least a coil and a capacitor. Provided with a rectifier circuit for extracting a DC signal from the resonance circuit, a capacitor charged by an output signal of the rectifier circuit, and a load circuit connected to both ends of the capacitor and having an impedance that changes in accordance with an operation. A radio wave transmitting means for transmitting an intermittent radio wave for exciting the resonance circuit with at least two types of transmission durations; and a radio wave reflected from the resonance circuit due to the radio wave transmitted from the radio wave transmission means. And a radio wave transmitted from the radio wave transmitting means with the at least two types of transmission durations. A position detection device provided with operation information identification means for detecting a difference or a ratio of the intensity of radio waves received by the radio wave reception means, detecting a change in impedance of the load circuit from the difference or ratio, and identifying the operation. Suggest.

Further, according to the present invention, in a position detecting device for detecting, on a tablet, a position indicated by a position indicator having a resonance circuit including at least a coil and a capacitor, the position indicator includes a rectifier for extracting a DC signal from the resonance circuit. A tablet, comprising: a circuit, a capacitor charged by an output signal of the rectifier circuit, and a load circuit connected to both ends of the capacitor and connected in series with a switch that is turned on / off according to an operation and a resistance element, A radio wave transmitting means for transmitting an intermittent radio wave for exciting the resonance circuit with at least two types of transmission durations; and a radio wave reflected from the resonance circuit due to the radio wave transmitted from the radio wave transmission means. A radio wave receiving means for receiving the radio wave when the radio wave is transmitted from the radio wave transmitting means with the at least two types of transmission durations. A position provided with operation information identification means for detecting a difference or ratio of the intensity of radio waves received by the radio wave reception means, detecting a change in impedance of the load circuit from the difference or ratio, and identifying an operation on the switch; A detection device is proposed.

Further, according to the present invention, in a position detecting device for detecting, on a tablet, a position indicator of a position indicator having a resonance circuit including at least a coil and a capacitor, the resonance frequency of which changes according to the pen pressure, A rectifier circuit for extracting a DC signal from the resonance circuit, a capacitor charged by an output signal of the rectifier circuit, a switch connected to both ends of the capacitor and turned on / off according to an operation, and a resistor element in series. A load circuit connected to the tablet; a radio wave transmitting means for transmitting an intermittent radio wave for exciting the resonance circuit with at least two types of transmission durations; and a tablet for transmitting the radio wave transmitted from the radio wave transmitting means. Radio wave receiving means for receiving radio waves reflected from the resonance circuit; and transmitting at least two types of radio waves from the radio wave transmitting means. Operation information for detecting a difference or a ratio of the intensity of radio waves received by the radio wave receiving means when transmitted for a continuous time, detecting a change in impedance of the load circuit, and identifying an operation on the switch based on the detected difference or ratio. Identification means, phase difference detection means for detecting a phase difference between a radio wave transmitted from the radio wave transmission means and a radio wave received by the radio wave reception means, and pen pressure detected from the phase difference detected by the phase difference detection means A position detection device provided with a pen pressure information identification unit is proposed.

[0016]

According to the present invention, the radio wave transmitted from the radio wave transmitting means excites the resonance circuit of the position indicator and gives electromagnetic energy to the resonance circuit. At this time, an induced voltage is generated in the resonance circuit of the position indicator, but the level is small immediately after the start of radio wave transmission due to the characteristics of the resonance circuit, increases with time, and starts transmitting the radio wave. Reaches a saturation level after a certain period of time.

At this time, if the impedance of the load circuit is sufficiently large, the output signal of the rectifier circuit flows only to the capacitor and charges it, and the terminal voltage of the capacitor rises with the continuation of radio wave transmission, and after the above-mentioned fixed time, Saturates and reaches a predetermined voltage. Thereafter, even after the transmission of the radio wave is stopped, the predetermined voltage is held at both ends of the capacitor.
After the transmission of the radio wave is stopped, the radio wave is transmitted for a shorter time than the fixed time after waiting until the induced voltage is not attenuated, and the induced voltage does not reach the saturation level.
Therefore, when the radio wave reflected from the resonance circuit is received, the signal strength is higher when the radio wave is continuously transmitted for the predetermined time or more than when the radio wave is continuously transmitted for less than the predetermined time. Be larger.

On the other hand, if the impedance of the load circuit is small, the output signal of the rectifier circuit flows to the capacitor to charge it and also to flow to the load circuit for consumption, so that the terminal voltage of the capacitor is higher than the predetermined voltage. Saturates at low values. Thereafter, when the transmission of radio waves stops, the terminal voltage of the capacitor is discharged through the load circuit and decreases, but the rate of decay is much slower than the rate of decay of the induced voltage of the resonant circuit. The terminal voltage of the capacitor hardly changes even when it waits until it has not attenuated. After the transmission of the radio wave is stopped, the radio wave is continuously transmitted for a shorter time than the fixed time after waiting until the induced voltage is attenuated, but as described above, the terminal voltage of the capacitor is held almost as it is. ,
The load circuit has no effect until the output voltage of the rectifier circuit exceeds the holding voltage, and the induced voltage increases at a speed similar to that when the impedance of the load circuit is sufficiently large. Since the saturation level when the impedance of the load circuit is small is smaller than the saturation level when the impedance is sufficiently large, the saturation level is reached even if the transmission duration is shorter than the above-mentioned fixed time. Therefore, the signal strength when the radio wave reflected from the resonance circuit is received depends on whether the radio wave is continuously transmitted for the predetermined time or more and when the radio wave is continuously transmitted for a time less than the predetermined time. It is almost equal.

Therefore, the strength of the signal received when the radio wave is continuously transmitted for the predetermined time or more is greater than the strength of the signal received when the radio wave is continuously transmitted for the time less than the predetermined time. In this case, it can be determined that the impedance of the load circuit is sufficiently large, and the strength of the signal received when the radio wave is continuously transmitted for the predetermined time or more, and for a time shorter than the predetermined time. When the strength of the signal received when the radio wave is transmitted is substantially equal to the strength of the signal, it can be determined that the impedance of the load circuit is small, whereby the operation on the position indicator is identified.

Further, according to the present invention, the strength of a signal received when a radio wave is continuously transmitted for a predetermined time or more is received when the radio wave is continuously transmitted for a time shorter than the predetermined time. When the signal strength is larger than the signal strength, it can be determined that the impedance of the load circuit is sufficiently large, that is, the switch is off, and the signal strength received when the radio wave is continuously transmitted for the predetermined time or more. When the strength of the signal received when the radio wave is continuously transmitted for a period shorter than the predetermined time is substantially equal to the above, it can be determined that the impedance of the load circuit is small, that is, the switch is on.

According to the present invention, the operation of the switch can be determined in the same manner as described above, and when the writing pressure on the position indicator changes and the resonance frequency of the resonance circuit changes, the phase difference detection means changes the radio wave transmission means. The phase difference between the radio wave transmitted from the radio wave and the radio wave received by the radio wave receiving means is detected, and the pen pressure can be identified by the pen pressure state identifying means from these.

[0022]

FIG. 1 shows a first embodiment of the present invention.
In the figure, 11a is a coil, 11b is a capacitor, 12a is a capacitor, 12b and 12c are diodes, 13 is a capacitor, 14a is a switch, and 14b is a resistor. 21a is an X-axis direction loop coil group, 21b is a Y-axis direction loop coil group, 2
2 is a selection circuit, 23 is an oscillator, 24 is a current driver, 2
5 is a switching connection circuit, 26 is a receiving amplifier, 27 is a detector,
28 is a low-pass filter (LPF), 29 is a sample and hold (S / H) circuit, 30 is an analog / digital (A
/ D) a conversion circuit 31 is a processing device (CPU), which constitutes a tablet B.

The coil 11a and the capacitor 11b are connected in series with each other to constitute a known resonance circuit 11 having a predetermined resonance frequency fo. The capacitor 12a and the diodes 12b and 12c constitute a well-known rectifier circuit 12 and take out a DC signal from the resonance circuit 11. The capacitor 13 is a rectifier circuit 12
Is connected in parallel with the resonance circuit 11 through the
Is charged by the output signal.

The switch 14a and the resistor 14b are connected in series with each other, and the impedance changes according to the operation. In this case, the impedance is infinite (switch-off) according to the on / off operation of the switch 14a and the resistance value of the resistor 14b (switch off). (Switch-on). The load circuit 14 includes the capacitor 1
3 are connected to both ends.

The X-axis direction loop coil group 21a is composed of a plurality of loop coils, here 40 loop coils, which are arranged substantially parallel to each other in the X-axis direction.
2 and each other end is commonly grounded. The Y-axis direction loop coil group 21b is composed of a plurality of loop coils, here 40 loop coils, which are arranged substantially parallel to each other in the Y-axis direction, one end of which is connected to the selection circuit 22 and the other. The ends are commonly grounded. The X-axis direction loop coil group 21a and the Y-axis direction loop coil group 21b constitute the sensing unit 21.

The selection circuit 22 receives the X-axis direction loop coil group 2 according to a predetermined selection signal applied from the processing device 31.
One loop coil is selected from 1a and the Y-axis direction loop coil group 21b.

The oscillator 23 generates an AC signal having the above-mentioned frequency fo and sends it to the current driver 24. The current driver 24 converts the AC signal into a current and sends it to the switching connection circuit 25. The switching connection circuit 25 is a processing device 3
One of the loop coils selected by the selection circuit 22 is switched and connected to the current driver 24 and the receiving amplifier 26 in accordance with a predetermined switching signal added from 1. The reception amplifier 26 amplifies the induced voltage generated in the selected one loop coil and transmitted through the selection circuit 22 and the switching connection circuit 25, and transmits the amplified voltage to the detector 27.

The detector 27 detects the induced voltage generated in the one loop coil, that is, the received signal, and
8 The low-pass filter 28 has the frequency fo described above.
It has a sufficiently lower cutoff frequency, converts the output signal of the detector 27 into a DC signal, and sends it to the S / H circuit 29. The S / H circuit 29 holds a voltage value at a predetermined timing of the output signal of the low-pass filter 28 described above, specifically, a predetermined timing during a reception period, according to the sampling signal applied from the processing device 31. It is sent to the D conversion circuit 30. The A / D conversion circuit 30 converts the output of the S / H circuit 29 from analog to digital and sends it to the processing device 31.

The processing device 31 controls each part of the tablet B, and when transmitting radio waves for a fixed transmission duration, X
Based on the voltage level of the induced voltage obtained from each of the loop coils of the axial loop coil group 21a and the Y-axis loop coil group 21b, the coordinate values of the indicated position of the position indicator A in the X-axis direction and the Y-axis direction are determined. When calculating and calculating the level of the voltage value of the induced voltage obtained from one loop coil of the X-axis direction loop coil group 21a or the Y-axis direction loop coil group 21b when transmitting a radio wave with two types of transmission durations described later. Switch 1 of position indicator A based on change
Identify whether 4a has been turned on.

FIG. 2 shows the flow of processing in the processing device 31, and the operation of the device will be described below in accordance with the flow.

First, the processing device 31 sends information for selecting the _first loop coil, for example, X ₁ of the X-axis direction loop coil group 21 a to the selection circuit 22, and selects the transmission side for the transmission / reception switching circuit 25. the signal to be sent, the loop coil X ₁ to the oscillator 23 supplies a sinusoidal signal of frequency f ₀ to generate a wave of frequency f _0. At this time, when the position indicator A is placed on the tablet B, the radio wave excites the resonance circuit 11, and the frequency f
Generate an induced voltage of _zero .

The processor 31 when sending a signal for selecting the transmission side to the reception switching circuit 25 a predetermined fixed time, and outputs a signal for selecting the reception side, to extinguish a radio wave generated from the loop coil X _1. At this time, the resonance circuit 1 of the position indicator A
The induced voltage generated in 1 is gradually attenuated in accordance with the loss and transmits a radio wave of a frequency f ₀ , but the radio wave excites the above-described loop coil X ₁ in reverse to generate an induced voltage.

When the processing device 31 sends a signal for selecting the receiving side to the transmission / reception switching circuit 25 for a certain period of time, the selection circuit 22 selects the second loop coil, for example, X ₂ , of the X-axis direction loop coil group 21 a. sends the information, send and receive the same radio wave, following the loop coil from the third of the X-axis direction loop coil group 21a to 40 th, for example, are sequentially scanned, select X ₃ to X ₄₀ (all scanning ) To transmit and receive the same radio waves as described above (step S
1).

At this time, the X-axis direction loop coil group 2
Instead of selecting all the loop coils of 1a, it is also possible to select one after another, such as every other coil coil. Further, transmission and reception of radio waves to and from one loop coil may be performed a plurality of times. Furthermore, the transmission time for each loop coil and the reception time for each loop coil must be equal, but the transmission time and the reception time do not necessarily have to be the same.

The induced voltage generated in the loop coils of the X-axis direction loop coil group 21a during the above-mentioned receiving period, that is, the received signal is detected by the detector 27 and converted into a DC signal.
The signal is smoothed by a low-pass filter 28, held at a predetermined timing by an S / H circuit 29, and further sent to a processing device 31 via an A / D conversion circuit 30 as a voltage value.

FIGS. 3A and 3B show examples of waveforms at various parts in the X-axis all-scan operation described above. In FIG. 3, (A) shows a radio wave transmitted from the sensing unit 21 and (B) shows a waveform generated in the resonance circuit 11. (C) is a received signal, and (d) is an output signal of the S / H circuit 29.

Since the output level of the S / H circuit 29 is a value depending on the distance between the position indicator A and the loop coil, the processing device 31 determines whether or not the maximum value is equal to or greater than a predetermined value. To determine whether or not the position indicator A is within the effective reading height of the tablet B (step S2).

The processing device 31 has a position indicator A within the height.
When it is determined that there is a loop coil, the loop coil in the X-axis direction (hereinafter, referred to as a peak coil) for which the maximum value is obtained is extracted from the obtained signal for each loop coil, and its number,
Here stores X ₇ (step S3). If it is determined that there is no position indicator A within the height, the processes of steps S1 and S2 are repeated.

Next, the processing device 31 sequentially scans and selects each loop coil of the Y-axis direction loop coil group 21b to transmit and receive the same radio wave as described above (step S4), and further, similarly to the above, the peak in the Y-axis direction. Extract the coil, its number,
Here stores Y ₅ (step S5). FIG. 4 shows an example of the waveform of each part in the above-described Y-axis all-scan operation, and each signal is the same as in the case of FIG.

Next, the processing device 31 provides the selection circuit 22 with information X for selecting a peak coil in the X-axis direction (or the Y-axis direction).
₇ (or Y ₅ ) and the transmission / reception switching circuit 25
A signal for selecting the transmission side sufficiently long T ₁ sends described later, generates an induced voltage of a frequency f ₀ to the resonant circuit 11 of the position indicator A, then a signal for selecting the reception side receive switching circuit 25 For a certain period of time to generate an induced voltage in the peak coil. Further, the processing unit 31 receive switching circuit 25 sufficiently short time a signal for selecting the transmission side than the time T ₁ to T ₂ is sent, the resonant circuit 11 of the position indicator A
To generate an induced voltage having a frequency f ₀ , and then send a signal for selecting the receiving side to the transmission / reception switching circuit 25 for a certain period of time.
An induced voltage is generated in the peak coil.

The processing device 31 compares the level of the received signal obtained after the transmission time T ₁ , for example, V _1, with the level of the received signal obtained after the transmission time T ₂ , for example, V _2, and will be described later. Thus, the on / off state of the switch 14a is determined (step S6).

Next, the processing device 31 transmits and receives radio waves for a predetermined number, for example, five loop coils centered on the peak coil in the X-axis direction loop coil group 21a. That is, the transmission / reception switching circuit 25
When the transmitting side is selected, the peak coil (coil number X _{7 in this case} ) is always selected.
Only when the receiving side is selected in step 5, scanning and selection (sector scan) are performed sequentially from the smaller number to the larger number (or the larger number) (step S7).

When the X-axis sector scan operation is completed, the processor 31 transmits and receives radio waves for a predetermined number, for example, five loop coils around the peak coil of the Y-axis direction loop coil group 21b. ,On this occasion,
When transmitting a radio wave, that is, when selecting the transmitting side with the transmission / reception switching circuit 25, the peak coil (here, the coil number Y ₅ ) is always selected, and when receiving, ie, when selecting the receiving side with the transmission / reception switching circuit 25, the number is set. Are sequentially scanned and selected (sector scan) from smaller to larger (or larger to smaller) (step S8).

FIG. 5 shows an example of the waveform of each part in the above-described switch determination operation, the X-axis sector scan operation and the Y-axis sector scan operation when the switch 14a is turned off.
FIG. 6 shows an example of the waveform of each part in the above-described switch determination operation, the X-axis sector scan operation, and the Y-axis sector scan operation when the switch 14a is turned on, and each signal is the same as in FIG. It is.

When the X-axis sector scan operation and the Y-axis sector scan operation described above are completed, the processing device 31 determines again whether or not the obtained maximum value of the induced voltage is equal to or greater than a predetermined value. It is determined whether the container A is within the effective reading height of the tablet B (step S9),
When the position indicator A is within the height, the peak coils in the X-axis direction and the Y-axis direction at which the maximum induced voltage is obtained are extracted and stored again (step S10), and further, the X-axis direction and the Y-axis are obtained. For each sector scan in the axial direction, a plurality of, for example, three induced voltages are extracted in descending order of level, and a well-known coordinate calculation as described in the prior application is executed based on these signals. The coordinate values of the designated position in the X-axis direction and the Y-axis direction are obtained (step S11).

Thereafter, as long as the position indicator A stays within the height, the processes of steps S6 to S11 are repeated. If it is determined that the position indicator A is not within the height, the process proceeds to step S1.
It returns to the processing of.

In the X-axis and Y-axis sector scan operations described above, the loop coil for transmitting radio waves is fixed to the peak coil because the position indicator always includes the switch determination operation. By transmitting radio waves from the loop coil closest to the
Is maintained substantially constant, thereby eliminating the influence of the rectifier circuit 12 and the load circuit 14 in the position indicator A so that the coordinate value of the indicated position can be detected accurately as in the case of the prior application. In order to

That is, when the X-axis and Y-axis sector scan operations are performed such that the loop coil is fixed during radio wave transmission and scanning is performed only during reception as in the present embodiment, the resonance circuit 11 always has A signal of the same strength will be generated.
For this reason, the signal strength when the reflected radio wave based on this signal is received by the loop coil depends on the distance between the resonance circuit 11 and the loop coil, and the loop coil closest to the resonance circuit 11 is selected. It becomes maximum when Therefore, by interpolating between the loop coils using the number of the loop coil for which the peak value was obtained in the same manner as in the prior application and the received signal strength when the previous and subsequent loop coils are selected, the coordinate value of the designated position is obtained. Can be determined accurately.

Next, the principle of the above-described switch determination will be described in detail with reference to FIGS.

FIG. 7 shows a load circuit of the position indicator A shown in FIG.
Is shown.

When the position indicator receives a radio wave that has continued for a predetermined time (T ₁ ) as shown in FIG. 8E, the resonance circuit 11 outputs a signal having a waveform as shown in FIG. There occurs, the capacitor 13 signal having a waveform as shown in FIG. 8 (g) is generated (however, T ₁ is the time when the voltage of the resonant circuit 11 is sufficiently saturated when the load resistance R is infinite .).

The voltage at both ends of the capacitor 13 saturates and keeps a constant voltage value after a certain period of time has elapsed since the start of radio wave reception. The value of the saturation voltage depends on the value of the load resistance R, and as shown in FIG. 8 (g), decreases as the value of R decreases. The signal level at both ends of the resonance circuit 11 also saturates as shown in FIG. 8F, but this saturation level also depends on the value of the load resistance R, and decreases as the value of R decreases. The reason is as follows.

The saturation voltage at both ends of the capacitor 13 is determined by the voltage induced by the received radio wave.
3 and the load resistance R from the capacitor 13
Is determined by the balance with the power consumed by the current flowing through the power supply. That is, a voltage value at which the charged power and the consumed power are equal is the saturation voltage value.

When the capacitor 13 and the load resistor R are not connected in the position indicator circuit, a voltage having a waveform as shown in FIG. the output voltage of the rectifier circuit 12 when connecting the R, i.e. the voltage v _c across the capacitor 13 will be clipped in the vicinity of the initial voltage v _c0 as shown in FIG. 9 (i), at both ends of the resonant circuit 11 The voltage is also clipped at the corresponding voltage.

At this time, the voltage v _c across the capacitor 13
Is ΔΔ after one cycle of the radio wave as shown in FIG.
v _c only to rise. Since the amount of increase per cycle is smaller as the terminal voltage of the capacitor 13 is higher, the terminal voltage of the capacitor 13 is gradually increased when radio waves are continuously received, and approaches a constant voltage (saturation voltage). . If the initial voltage v _c0 is the same in FIG. 9 (i), to become smaller as the voltage increase amount Delta] v _c less the value of the load resistor R becomes higher saturation voltage has a small value of the load resistor R low.

Next, already charged capacitor 13 is sufficiently, as shown in FIG. 10 (g), operation when the terminal voltage v _c reaches the saturation voltage value corresponding to the value of the load resistance R at that time Will be described. However, here, as shown in FIG. 10E, the radio wave is continuously transmitted from the tablet B for the time T ₁ , and after the voltage of the resonance circuit 11 is sufficiently attenuated, the time T
₂ (T sufficiently shorter than ₁₎ by continuously shall be transmitted.

[0057] When the radio wave is sent continuously from the tablet B for the time T _1, since the terminal voltage v _c of the capacitor 13 has reached the saturation voltage value, as shown in FIG. 10 (f), the resonant circuit The voltage across the terminal 11 rises faster than the case shown in FIG. 8F (when the terminal voltage of the capacitor starts from zero). However, when the voltage rises to the above-mentioned constant level (the level at which the output voltage of the rectifier circuit 12 reaches the terminal voltage of the capacitor 13), the signal is clipped.
At this time, the signal level (saturation level) decreases as the load resistance R decreases, as shown in FIG.

Similarly, when a radio wave is continuously transmitted from the tablet B for the time T ₂ , the voltage at both ends of the resonance circuit 11 rises earlier than in the case shown in FIG. since when the value is sufficiently large to exit the radio wave transmitted before reaching the saturation level, only reach lower signal levels than when a radio wave is sent continuously by the time T _1.

Meanwhile, since the value of the load resistor R reaches the saturation level so far sufficiently small when time T ₂ ends, and when the radio wave is sent continuously for a time T _1, continues for time T ₂ Thus, a signal of substantially the same level is generated in the resonance circuit 11 when the radio wave is transmitted. The difference between the more signal level even if does not reach the saturation level, the value of the load resistance R smaller when the radio wave is sent continuously by the time T ₂ are small.

Since the signal level in the resonance circuit 11 described above is reflected in the level of the received signal in the tablet B, the level of the received signal detected after continuously transmitting radio waves for the time T ₁ and the level of the received signal for the time T ₂ The value of the load resistance R can be detected by comparing (or taking a difference) with the level of the received signal detected after the radio wave is continuously transmitted.

In the position indicator A shown in FIG. 1, the resistance of the load circuit 14 changes between the value of the resistor 14b and infinity in accordance with the on / off of the switch 14a. _{by 1,} comparing V ₂ (or a difference), it is possible to detect the on-off switch 14a.

As described above, according to the present embodiment, it is only necessary to add a rectifier circuit, a capacitor and a load circuit to the position indicator, and these do not affect the resonance frequency of the resonance circuit. The structure of the device and the adjustment of the resonance frequency are simplified, and it is only necessary to detect a level change at one frequency. Therefore, a hardware structure for detecting a change in phase angle without requiring a wide frequency range is required. The operation to the switch of the position indicator can be identified without any need for the operation.

FIG. 11 shows a second embodiment of the present invention. Here, an example is shown in which pen pressure information can be input together with switch information in the first embodiment. That is, in the figure,
11c is a variable capacitor, 32 is a synchronous detector, 33
Is a low-pass filter, 34 is a sample and hold (S / H)
A circuit, 35 is an analog / digital (A / D) conversion circuit, and 36 is a processing device.

The variable capacitor 11c is a position indicator A
The capacitance value changes according to the pen pressure applied to the coil 11a, and is connected in series with the coil 11a to form a resonance circuit 11 '. Here, the resonance circuit 11 'operates at a phase angle 60 of the frequency fo when no pen pressure is applied.
The phase angle is set to a frequency detected as °, for example, by gradually applying a maximum of 500 g of pen pressure,
It is assumed that it is set so that it can be continuously changed up to 60 °.

The synchronous detector 32 synchronously detects the output signal of the receiving amplifier 26 with the AC signal from the oscillator 23 and sends out a signal having a level corresponding to the phase difference between them to the low-pass filter 33. The low-pass filter 33 has a cutoff frequency sufficiently lower than the frequency fo, converts the output signal of the synchronous detector 32 into a DC signal, and sends it to the S / H circuit 34. S / H
The circuit 34 holds the voltage value of the output signal of the low-pass filter 33 at a predetermined timing according to the sampling signal applied from the processing device 36, and the A / D conversion circuit 3
Send to 5. The A / D conversion circuit 35 is the S / H circuit 3
4 is converted from analog to digital into a processing unit 36.
Send to

The processing device 36 controls each part of the tablet B, and when transmitting a radio wave for a fixed transmission duration, X
Based on the voltage level of the induced voltage obtained from each of the loop coils of the axial loop coil group 21a and the Y-axis loop coil group 21b, the coordinate values of the indicated position of the position indicator A in the X-axis direction and the Y-axis direction are determined. When calculating and calculating the level of the voltage value of the induced voltage obtained from one loop coil of the X-axis direction loop coil group 21a or the Y-axis direction loop coil group 21b when transmitting a radio wave with two types of transmission durations described later. Switch 1 of position indicator A based on change
It is determined whether or not 4a is turned on, and the pen pressure is detected based on the signal level corresponding to the phase difference.

FIG. 12 shows the flow of processing in the processing device 36. After the coordinate calculation, the first processing is performed except that the pen pressure is detected from the signal level corresponding to the phase difference.
This embodiment is the same as that of FIG. In addition,
The changes in the levels of the transmission signal and the reception signal are the same as in the first embodiment.

As described above, according to this embodiment, just as in the first embodiment, it is only necessary to add a rectifier circuit, a capacitor, and a load circuit to the position indicator. Since the resonance frequency is not affected, the configuration of the position indicator and the adjustment of the resonance frequency are simplified, and a wide frequency range is not required since only a level change at one frequency need be detected. Can be identified and the pen pressure can be simultaneously detected.

[0069]

As described above, according to the present invention, it is only necessary to add a rectifier circuit, a capacitor and a load circuit to the position indicator, and these do not affect the resonance frequency of the resonance circuit. Since the configuration of the position indicator and the adjustment of the resonance frequency are simplified, and it is only necessary to detect a level change at one frequency, a wide frequency range is not required, and a change in the phase angle can be detected. The operation to the position indicator can be identified without any hardware configuration.

Further, according to the present invention, it is only necessary to add a rectifier circuit, a capacitor and a load circuit to the position indicator.
In addition, since these do not affect the resonance frequency of the resonance circuit, the configuration of the position indicator and the adjustment of the resonance frequency are simplified, and only the level change at one frequency needs to be detected. The operation of the switch of the position indicator can be identified without requiring any of the above and without any hardware configuration for detecting a change in the phase angle.

Further, according to the present invention, it is only necessary to add a rectifier circuit, a capacitor and a load circuit to the position indicator.
In addition, since these do not affect the resonance frequency of the resonance circuit, the configuration of the position indicator and the adjustment of the resonance frequency are simplified, and a wide frequency range can be obtained because only the level change for one frequency needs to be detected. The operation of the switch of the position indicator can be identified without any need, and the pen pressure can be simultaneously detected.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of a position detection device and a position indicator thereof according to the present invention.

FIG. 2 is a flowchart of processing in the processing apparatus of the first embodiment.

FIG. 3 is a diagram showing an example of a waveform of each unit in an X-axis all scan operation.

FIG. 4 is a diagram showing an example of a waveform of each part in a Y-axis all scan operation.

FIG. 5 shows a switch determination operation when a switch is turned off,
FIG. 4 is a diagram illustrating an example of waveforms of respective units in an X-axis sector scan operation and a Y-axis sector scan operation.

FIG. 6 shows a switch determination operation when the switch is turned on,
FIG. 4 is a diagram illustrating an example of waveforms of respective units in an X-axis sector scan operation and a Y-axis sector scan operation.

FIG. 7 is a diagram showing the load circuit in the position indicator in FIG. 1 replaced with a load resistor.

8 is a diagram showing an example of a waveform of each part of the position indicator shown in FIG. 7 when the capacitor is not charged.

9 is a diagram illustrating an example of an output voltage waveform of the rectifier circuit when the rectifier circuit and the capacitor are not connected and when the capacitor is connected in the position indicator illustrated in FIG. 7;

FIG. 10 when the capacitor is sufficiently charged
Showing an example of the waveform of each part of the position indicator shown in FIG.

FIG. 11 is a block diagram showing a second embodiment of the position detecting device and the position indicator of the present invention.

FIG. 12 is a flowchart of processing in the processing apparatus of the second embodiment.

[Explanation of symbols]

11, 11 '... resonance circuit, 11a ... coil, 11b ... capacitor, 11c ... variable capacitance capacitor, 12 ... rectifier circuit, 12a ... capacitor, 12b, 12c ... diode, 13 ... capacitor, 14 ... load circuit, 14a ... switch, 14b: resistance, 21: sense unit, 21a: X-axis direction loop coil group, 21b: Y-axis direction loop coil group,
22 ... selection circuit, 23 ... oscillator, 24 ... current driver,
25 switch connection circuit, 26 reception amplifier, 27 detector, 28, 33 low-pass filter, 29, 34 sample-hold circuit, 30, 35 analog-digital conversion circuit, 31, 36 processing device, 32 ... Synchronous detector.

Claims (7)

(57) [Claims] 1. A position detecting device for detecting, on a tablet, an indicated position of a position indicator having a resonance circuit including at least a coil and a capacitor, the position indicator includes: a rectifier circuit for extracting a DC signal from the resonance circuit; A capacitor that is charged by an output signal of the rectifier circuit, and a load circuit that is connected to both ends of the capacitor and that changes impedance according to an operation; and that the tablet has the resonance circuit with at least two types of transmission durations. Radio wave transmitting means for transmitting intermittent radio waves to be excited; radio wave receiving means for receiving radio waves reflected from the resonance circuit due to the radio waves transmitted from the radio wave transmitting means; and radio waves from the radio wave transmitting means. The strength of radio waves received by the radio wave receiving means when transmitted with the at least two types of transmission durations A position detecting device for detecting an operation information identifying means for detecting a difference or a ratio of the degrees and detecting a change in impedance of the load circuit from the detected difference or ratio to identify the operation. 2. A position detecting device for detecting, on a tablet, an indicated position of a position indicator having a resonance circuit including at least a coil and a capacitor, the position indicator includes: a rectifier circuit for extracting a DC signal from the resonance circuit; A capacitor that is charged by an output signal of the rectifier circuit, and a load circuit that is connected to both ends of the capacitor and that is connected in series with a switch and a resistance element that are turned on and off in accordance with an operation, wherein the tablet has at least Radio wave transmitting means for transmitting intermittent radio waves for exciting the resonance circuit with two types of transmission durations; and radio waves for receiving radio waves reflected from the resonance circuit due to the radio waves transmitted from the radio wave transmission means Receiving means, and when the radio wave is transmitted from the radio wave transmitting means with the at least two types of transmission durations, Operation information identifying means for detecting a difference or ratio of the intensity of radio waves received by the receiving means, detecting a change in impedance of the load circuit from the difference or ratio, and identifying an operation on the switch; Position detection device. 3. A position detecting device for detecting, on a tablet, a pointed position of a position indicator having a resonance circuit including at least a coil and a capacitor, the resonance frequency of which changes in accordance with pen pressure, wherein the position indicator includes a resonance circuit. A rectifier circuit for extracting a DC signal from the rectifier circuit, a capacitor charged by an output signal of the rectifier circuit, a load connected to both ends of the capacitor and connected in series with a switch and a resistance element that are turned on / off according to an operation. And a tablet, the tablet includes: a radio wave transmitting unit that transmits an intermittent radio wave that excites the resonance circuit with at least two types of transmission duration times; and the tablet that transmits the resonance signal due to the radio wave transmitted from the radio wave transmitting unit. A radio wave receiving means for receiving a radio wave reflected from a circuit; Operation information identification means for detecting a difference or a ratio of the intensity of radio waves received by the radio wave reception means when transmitted, and thereby detecting a change in impedance of the load circuit to identify an operation on the switch. A phase difference detecting means for detecting a phase difference between a radio wave transmitted from the radio wave transmitting means and a radio wave received by the radio wave receiving means; and a pen pressure for detecting pen pressure from the phase difference detected by the phase difference detecting means. A position detecting device provided with information identification means. 4. A first intensity of a radio wave received by a radio wave receiving unit when a radio wave is transmitted from a radio wave transmitting unit with a predetermined first transmission duration time, and the first intensity is sufficiently shorter than the first transmission duration time. The second intensity of the radio wave received by the radio wave receiving means when the radio wave is transmitted from the radio wave transmitting means with the second transmission duration time is compared, and the first intensity and the second intensity are substantially the same. 4. The position detecting device according to claim 1, further comprising operation information identification means for detecting a change in impedance of the load circuit depending on whether or not the operation exists, and identifying operation. 5. A resonance circuit including at least a coil and a capacitor, a rectifier circuit for extracting a DC signal from the resonance circuit, a capacitor charged by an output signal of the rectifier circuit, and a capacitor connected to both ends of the capacitor for operation. And a load circuit whose impedance changes according to the position indicator. 6. A resonance circuit including at least a coil and a capacitor, a rectifier circuit for extracting a DC signal from the resonance circuit, a capacitor charged by an output signal of the rectifier circuit, and a capacitor connected to both ends of the capacitor for operation. A position indicator comprising: a load circuit in which a switch that is turned on / off in response thereto and a resistance element are connected in series. 7. A resonance circuit including at least a coil and a capacitor, the resonance frequency of which changes according to the pen pressure, a rectifier circuit for extracting a DC signal from the resonance circuit, a capacitor charged by an output signal of the rectifier circuit, A position indicator comprising a switch connected to both ends of the capacitor and turned on / off in response to an operation, and a load circuit in which a resistance element is connected in series.