KR0173010B1 - Infrared ray sensor driving circuit of touch screen - Google Patents

Abstract

Infrared sensor driving circuit of the touch screen of the present invention is to sequentially drive the infrared sensor to detect the horizontal position and the vertical position of the touch screen one by one.

According to the present invention, the cathode of the light emitting elements LD ₁₁₁ to LD ₁₂₀ and the light receiving elements PD ₁₁₁ to PD ₁₂₀ of the infrared sensor for detecting the horizontal position and the vertical position of the touch screen 11 are detected. Are commonly connected alternately so that the common control signals CO ₁ and CO ₂ output from the microcomputer 12 are applied, and the cathodes and light-receiving elements of the light emitting elements LD ₂₁₁ to LD ₂₂₀ of the infrared sensor for vertical position detection are applied. The emitters of PD ₂₁₁ to PD ₂₂₀ are alternately connected in common so that the common control signals CO ₃ and CO ₄ output from the microcomputer 12 are applied, and the light emitting elements of the infrared sensor for horizontal and vertical position detection ( On the anodes of LD ₁₁₁ to LD ₁₂₀ (LD ₂₁₁ to LD ₂₂₀ ), the demultiplexer 13 demultiplexes the control signals output from the microcomputer 12 and then sequentially turns them on one by one to light up the light receiving elements PD ₁₁₁ ~. The collectors of PD ₁₂₀ ) (PD ₂₁₁ ~ PD ₂₂₀ ) are connected in common two by one. The multiplexer 14 multiplexes the received light signal and inputs it to the microcomputer 12 so that the infrared sensors detecting the horizontal and vertical positions are sequentially driven one by one, thereby reducing power consumption and extending the service life of the infrared sensor. By installing a large number of infrared sensors on the touch screen by the number of terminals, the touch position of the touch screen can be detected more precisely.

Description

Infrared sensor driving circuit of touch screen

1 is a conventional infrared sensor driving circuit diagram.

2 is an infrared sensor driving circuit diagram of the present invention.

(A)-(n) of FIG. 3 are operation waveform diagrams of each part of FIG.

* Explanation of symbols for main parts of the drawings

11: touch screen 12: micom

13: demultiplexer 14: multiplexer

LD ₁₁₁ ~ LD ₁₂₀ , LD ₂₁₁ ~ LD ₂₂₀ : Light emitting device of infrared sensor

PD ₁₁₁ ~ LD ₁₂₀ , PD ₂₁₁ ~ PD ₂₂₀ : Infrared sensor

The present invention is a touch screen attached to the front of the CRT (Cathode Ray Tube), the touch screen for detecting the pressing position of the CRT screen when the user touches by hand, a plurality of installed on the upper and lower portions of the touch screen horizontal position The present invention relates to a driving circuit of an infrared sensor for detecting and an infrared sensor of a touch screen installed in a plurality of left and right sides of the touch screen to drive an infrared sensor for detecting a vertical position.

A touch screen using a conventional infrared sensor operates all of the infrared sensors, and inputs output signals of the respective infrared sensors.

That is, conventionally, as shown in FIG. 1, the light emitting devices LD ₁₁ to LD _1N and the light receiving device PD of the infrared sensor detecting horizontal positions of the touch screen 1 on the upper and lower portions of the touch screen 1. ₁₁ to PD _1N and light emitting devices LD ₂₁ to LD _2N and light receiving devices PD ₂₁ to PD of the infrared sensor for detecting the vertical position of the touch screen 1 on both left and right sides of the touch screen 1. _2N ) is installed, and each light emitting device LD ₁₁ to LD _1N (LD ₂₁ to LD _2N ) is turned on by applying a power supply B ⁺ , and the light receiving elements PD ₁₁ to PD _1N (PD ₂₁ to PD) are turned on. _The emitter, which is an output terminal of _2N ), was connected to the input terminal of the control unit 2, respectively.

The power supply (B ⁺⁾ as a conventional infrared sensor driving circuit is inputted constructed as is so applied to the light emitting elements of the infrared sensor _{(LD 11 ~ LD 1N) (} LD 21 ~ LD 2N) light-emitting device (LD ₁₁ ~ LD _1N, LD ₂₁ to LD _2N are turned on to emit infrared rays toward the light receiving elements PD ₁₁ to PD _1N and PD ₂₁ to PD _2N .

When the user touches a predetermined portion of the touch screen 1 in this state, the corresponding light receiving element PD ₁₁ or light receiving elements PD12 to PD _{1N of} infrared rays passing through the contacted portion and the light receiving element PD _21. ) Or the light receiving elements PD ₂ 2 to PD _2N do not receive infrared rays and are turned off, and the control unit 2 uses a touch screen as an output signal of the light receiving elements PD ₁₁ to PD _1N and PD ₂₁ to PD _2N . The contacted vertical position and the horizontal position of (1) are discriminated.

However, the conventional infrared sensor driving circuit as described above continues to apply the power to the infrared sensor to drive the life of the infrared sensor is shortened, a lot of power is consumed, and thus the power supply capacity of the power supply unit must be manufactured largely. The production cost has risen, and the output signal of the light receiving element of the infrared sensor is inputted to the input terminal of the control unit, respectively, so that the number of input terminals of the control unit must be large, and the number of usable infrared sensors is limited to the number of input terminals of the control unit. There were various problems.

Therefore, an object of the present invention is to provide an infrared sensor driving circuit of a touch screen that reduces power consumption and enables input of output signals of a plurality of light receiving elements of an infrared sensor with a small number of input terminals.

Infrared sensor driving circuit of the touch screen of the present invention having this purpose is to detect the contact position while driving a plurality of infrared sensors one by one alternately the cathode of the light emitting element of the infrared sensor for detecting the horizontal position and the vertical position of the touch screen. In addition to connecting two by one, the two cathodes of the light emitting device are sequentially connected in common, and two emitters of the light receiving device of the infrared sensor detecting the horizontal and vertical positions are alternately connected and the collector of the light receiving device Are connected to each other in sequence, and the common connection line of the light emitting element and the light receiving element of the infrared sensor detecting the horizontal position are mutually connected, and the common connection line of the light emitting element and the light receiving element of the infrared sensor detecting the vertical position is mutually connected. By connecting to each other, the microcomputer has a certain period on the common connection line and common control signal. In addition, the control signal is output to the input / output terminal and the detection signal is input, and the multiplexer inputs the detection signal of the light receiving device to the light emitting device which the demultiplexer detects the horizontal and vertical positions. To input to the microcomputer.

Hereinafter, an infrared sensor driving circuit of a touch screen of the present invention will be described in detail with reference to the accompanying drawings of FIGS. 2 and 3.

2 is an infrared sensor driving circuit diagram of the present invention showing an example of a touch screen in which 10 infrared sensors are installed in horizontal and vertical positions, respectively, as shown in FIG. ₁₁₁ ~ LD ₁₂₀ ) and the light receiving elements (PD ₁₁₁ ~ PD ₁₂₀ ) are separated and installed in a row in a horizontal position detection infrared sensor, the light emitting elements (LD ₂₁₁ ~ LD ₂₂₀ ) and on the left and right of the touch screen 11 and Infrared sensor for vertical position detection, in which the light receiving elements PD ₂₁₁ to PD ₂₂₀ are installed in a row, and common control signals CO ₁ and CO ₂ (CO ₃ and CO ₄ ) having opposite pulse phases. A microcomputer 12 for outputting at a time interval and outputting a control signal to the input / output terminals I / O ₁ to I / O ₃ and inputting a detection signal to determine a contact position of the touch screen 10; The light emitting elements LD ₁₁₁ to LD ₁₂ after demultiplexing the control signal outputted by ₀ ) (LD ₂₁₁ to LD ₂₂₀ ) is applied to the microcomputer 12 by multiplexing the demultiplexer 13 to be turned on and the detection signal of the light receiving elements (PD ₁₁₁ ~ PD ₁₂₀ ) (PD ₂₁₁ ~ PD ₂₂₀ ). And a multiplexer (14), wherein the cathodes of the light emitting elements LD ₁₁₁ to LD ₁₂₀ and the emitters of the light receiving elements PD ₁₁₁ to PD _{120 of} the horizontal position detection infrared sensor are alternately connected in common to the common control signal. (CO ₁ , CO ₂ ) is applied, and the cathodes of the light emitting elements LD ₂₁₁ to LD ₂₂₀ of the infrared sensor for vertical position detection and the emitters of the light receiving elements PD ₂₁₁ to PD ₂₂₀ are alternately connected in common. A control signal (CO ₃ , CO ₄ ) is applied, the anode of the light emitting elements (LD ₁₁₁ ~ LD ₁₂₀ ) (LD ₂₁₁ ~ LD ₂₂₀ ) of the infrared sensor for horizontal and vertical position detection and the light receiving elements (PD ₁₁₁ ~ PD ₁₂₀₎ Collectors (PD ₂₁₁ to PD ₂₂₀ ) are connected to the demultiplexer 13 and the multiplexer 14 by connecting two in common. It was.

In the infrared sensor driving circuit of the touch screen of the present invention configured as described above, the common control signals CO ₁ and CO ₂ in which the microcomputers 12 have opposite phases are shown in FIGS. 3A and 3B. For example, if five common control signals (CO ₁ , CO ₂ ) are output for a predetermined time, that is, when 10 infrared sensors are installed in horizontal and vertical positions, respectively, (c) and ( As shown in d), the common control signals CO ₃ and CO ₄ having mutually opposite phases are output, and when a predetermined time elapses, the common control signals CO ₁ and CO ₂ are repeated.

The microcomputer 12 outputs a control signal to the input / output terminals I / O ₁ to I / O ₃ , and demultiplexes the output control signal to the output terminals OT ₁ to OT ₅ . As shown in (e) to (i) of FIG. ₃ , a pulse signal having a width of one cycle of the common control signals CO ₁ to CO ₄ is output, and the output pulse signal is in the horizontal direction and the touch screen 11. Light emitting elements of the infrared sensor for detecting the vertical direction (LD ₁₁₁ , LD ₁₁₂ , LD ₂₁₁ , LD ₂₁₂ ) (LD ₁₁₃ , LD ₁₁₄ , LD ₂₁₃ , LD ₂₁₄ ) (LD ₁₁₅ , LD ₁₁₆ , LD ₂₁₅ , LD ₂₁₆ ) ( LD ₁₁₇ , LD ₁₁₈ , LD ₂₁₇ , LD ₂₁₈ ) are sequentially applied to the anodes of LD ₁₁₉ , LD ₁₂₀ , LD ₂₁₉ , LD ₂₂₀ , so that the light emitting device PD ₁₁₁ (PD ₁₁₂ ) (PD ₁₁₃ ) (PD ₁₁₄ ) (PD ₁₁₅ ) (PD ₁₁₆ ) (PD ₁₁₇ ) (PD ₁₁₈ ) (PD ₁₁₉ ) (PD ₁₂₀ ) (PD ₂₁₁ ) (PD ₂₁₂ ) (PD ₂₁₃ ) (PD ₂₁₄ ) (PD ₂₁₅ ) (PD ₂₁₆ ) (PD ₂₁₇ (PD ₂₁₈ ) (PD ₂₁₉ ) (PD ₂₂₀ ) is sequentially turned on.

In this way, the light emitting elements of the infrared sensor LD ₁₁₁ and LD ₁₁₂ (LD ₁₁₃ and LD ₁₁₄ ) (LD ₁₁₅ and LD ₁₁₆ ) (LD ₁₁₇ and LD ₁₁₈ ) (LD ₁₁₉ and LD ₁₂₀ ) (LD ₂₁₁ and LD ₂₁₂ ) ( LD ₂₁₃ , LD ₂₁₄ ) (LD ₂₁₅ , LD ₂₁₆ ) (LD ₂₁₇ , LD ₂₁₈ ) (LD ₂₁₉ , LD ₂₂₀ ) are sequentially turned on, the light receiving element of the infrared sensor detecting the horizontal and vertical direction (PD ₁₁₁₎ (PD ₁₁₂ ) (PD ₁₁₃ , PD ₁₁₄ ) (PD ₁₁₅ , PD ₁₁₆ ) (PD ₁₁₇ , PD ₁₁₈ ) (PD ₁₁₉ , PD ₁₂₀ ) (PD ₂₁₁ , PD ₂₁₂ ) (PD ₂₁₃ , PD ₂₁₄ ) (PD ₂₁₅ , PD ₂₁₆ ) (PD ₂₁₇ , PD ₂₁₈ ) (PD ₂₁₉ , PD ₂₂₀ ) sequentially receive the light as shown in (j) to (n) of FIG. 3, and the light receiving elements PD ₁₁₁ and PD ₁₁₂ (PD ₁₁₃ ). (PD ₁₁₄ ) (PD ₁₁₅ , PD ₁₁₆ ) (PD ₁₁₇ , PD ₁₁₈ ) (PD ₁₁₉ , PD ₁₂₀ ) (PD ₂₁₁ , PD ₂₁₂ ) (PD ₂₁₃ , PD ₂₁₄ ) (PD ₂₁₅ , PD ₂₁₆ ) (PD ₂₁₇ , The multiplexer 14 multiplexes the received signals of the PD ₂₁₈ (PD ₂₁₉ , PD ₂₂₀ ) to receive the light receiving elements PD ₁₁₁ (PD ₁₁₂ ) at the input / output terminals I / O ₁ to I / O ₃ of the microcomputer 12. (PD ₁₁₃ ) (PD ₁₁₄ ) (PD ₁₁₅ ) (PD ₁₁₆ ) (PD ₁₁₇ ) (PD ₁₁₈ ) (PD ₁₁₉ ) (PD ₁₂₀ ) (PD ₂₁₁ ) (PD ₂₁₂ ) PD ₂₁₃ , PD ₂₁₄ , PD ₂₁₅ , PD ₂₁₆ , PD ₂₁₇ , PD ₂₁₈ , PD ₂₁₉ , PD ₂₂₀ .

That is, at time t ₁ , the microcomputer 12 outputs the common control signal CO ₁ at low potential as shown in (a) of FIG. 3, and demultiplexer as shown in (e) of FIG. 3. 13 is when the output pulse signal of the high-potential, a light-emitting element (LD ₁₁₁₎ of an infrared sensor for detecting a horizontal position are lit up, the light-receiving element the light of the light emitting element (LD ₁₁₁₎ (PD ₁₁₁₎ is a third-degree As shown in (j), the multiplexer 14 multiplexes the received signal of the light receiving element PD ₁₁₁ and inputs it to the microcomputer 12.

At the time t ₂ , the microcomputer 12 outputs the common control signal CO ₂ at low potential as shown in (b) of FIG. 3, and demultiplexer (e) as shown in (e) of FIG. 3. 13 outputs a pulse signal of high potential, the light emitting element LD ₁₁₂ of the infrared sensor detecting the horizontal position is turned on, and the light receiving element PD ₁₁₁ receives light from the light emitting element LD _{112 as} shown in FIG. As shown in j), the multiplexer 14 multiplexes the received signal of the light receiving element PD ₁₁₂ and inputs it to the microcomputer 12. As such, the microcomputer 12 times t ₁ to t _10. As shown in (a) and (b) of FIG. ₃ , the demultiplexer 13 is connected to the control signal output from the microcomputer 12 while alternately outputting the common control signals CO ₁ and CO ₂ . As shown in (e) to (i), a light emitting element LD ₁₁₁ that detects a horizontal position by generating a pulse signal LD ₁₁₁ (LD ₁₁₂ ) (LD ₁₁₃ ) (LD ₁₁₄ ) (LD ₁₁₅ ) (L D ₁₁₆ ) (LD ₁₁₇ ) (LD ₁₁₈ ) (LD ₁₁₉ ) (LD ₁₂₀ ) are sequentially turned on, and the light emitting element LD ₁₁₁ (LD ₁₁₂ ) (LD ₁₁₃ ) (LD ₁₁₄ ) (LD ₁₁₅ ) (LD ₁₁₆ ) (LD ₁₁₇ ) (LD ₁₁₈ ) (LD ₁₁₉ ) (LD ₁₂₀ ) light receiving element PD ₁₁₁ (PD ₁₁₂ ) (PD ₁₁₃ ) (PD ₁₁₄ ) (PD ₁₁₅ ) (PD ₁₁₆ ) (PD ₁₁₇ ) (PD ₁₁₈ ) (PD ₁₁₉ ) (PD ₁₂₀ ) multiplexed by the multiplexer 14 and then sequentially input to the microcomputer 12, the micom 12 is in contact with the touch screen 11 horizontal position Will be detected.

When the detection of the contacted horizontal position of the touch screen 11 is completed in this manner, the microcomputer 12 stores the common control signal CO _{3 at} time t ₁₁ as shown in FIG. 3C. As shown in (e) of FIG. 3, when the demultiplexer 13 outputs a high potential pulse signal, the light emitting device LD ₂₁₁ of the infrared sensor detecting the vertical position is turned on, and the light emitting device The light receiving element PD ₂₁₁ receives the light of the LD ₂₁₁ as shown in FIG. 3 (j), and the multiplexer 14 multiplexes the light receiving signal of the light receiving element PD ₂₁₁ to the microcomputer 12. Will be entered.

At the time t ₁₂ , the microcomputer 12 outputs the common control signal CO ₄ at low potential as shown in (d) of FIG. 3, and demultiplexer (e) as shown in (e) of FIG. 3. When 13) outputs a high potential pulse signal, the light emitting element LD ₂₁₂ of the infrared sensor is turned on, and the light receiving element PD ₂₁₂ receives the light of the light emitting element LD _{212 as} shown in FIG. As described above, the multiplexer 14 multiplexes the received signal of the light receiving element PD ₂₁₂ and inputs the received signal to the microcomputer 12. Thus, the microcomputer 12 has a third degree at time t ₁₂ to t ₂₀ . (c) As shown in (d), the demultiplexer 13 generates the demultiplexer 13 according to the control signal output from the microcomputer 12 while alternately outputting the common control signal CO ₃ and CO ₄ . As shown in (i), a light emission signal LD ₂₁₁ (LD ₂₁₂ ) (LD ₂₁₃ ) (LD ₂₁₄ ) (LD ₂₁₅ ) (LD ₂₁₆ ) (LD ₂₁₇ ) (LD) which generates a pulse signal and detects a horizontal position. ₂₁₈ ) ( LD ₂₁₉ ) (LD ₂₂₀ ) is turned on sequentially, and the light emitting element LD ₂₁₁ (LD ₂₁₂ ) (LD ₂₁₃ ) (LD ₂₁₄ ) (LD ₂₁₅ ) (LD ₂₁₆ ) (LD ₂₁₇ ) (LD ₂₁₈ ) (LD ₂₁₉ ) ) (light receiving element _{(PD 211) (PD 212)} (PD 213) (PD 214) (PD 215) (PD 216) (PD 217) (PD 218) (PD 219) for receiving light of the LD ₂₂₀₎ (PD _The multiplexer 14 multiplexes the received signal of the signal ₂₂₀ and sequentially inputs it to the microcomputer 12 so that the microcomputer 12 detects the vertical position of the touch screen 11.

As described in detail above, the present invention sequentially operates a plurality of infrared sensors installed in the horizontal and vertical directions of the touch screen using a demultiplexer and a multiplexer one by one, and detects the contacted horizontal and vertical positions of the touch screen. In addition, the service life of the infrared sensor can be extended, and a large number of infrared sensors can be installed on the touch screen with a limited number of input terminals, so that the touch position of the touch screen can be detected more precisely.

Claims (2)

An infrared sensor for horizontal position detection, in which the light emitting devices LD ₁₁₁ to LD ₁₂₀ and the light receiving devices PD ₁₁₁ to PD ₁₂₀ are installed in a row, respectively, on the upper and lower portions of the touch screen 11 and the touch screen 11. The light emitting elements LD ₂₁₁ to LD ₂₂₀ and the light receiving elements PD ₂₁₁ to PD ₂₂₀ are separated on the left side and the right side to be installed in a line, and the vertical position detection infrared sensor and the control signal are demultiplexed. Demultiplexer 13 to be applied to ₁₁₁ to LD ₁₂₀ (LD ₂₁₁ to LD ₂₂₀ ) and a multiplexer 14 to multiplex and output detection signals of the light receiving elements PD ₁₁₁ to PD ₁₂₀ (PD ₂₁₁ to PD ₂₂₀ ). And common control signals (CO ₁ , CO ₂ ) and common control signals (CO ₃ , CO ₄ ) having opposite phases to each other at predetermined time intervals, and the light emitting devices LD ₁₁₁ to LD ₁₂₀ (LD ₂₁₁ ). The light receiving elements PD ₁₁₁ to PD _{120 which} are sequentially turned on one by one by applying to LD ₂₂₀ and multiplexed by the multiplexer 14. Infrared sensor driving circuit of the touch screen, characterized in that consisting of a microcomputer 12 for determining the contact position of the touch screen 11 by the detection signal of (PD ₂₁₁ ~ PD ₂₂₀ ). The method of claim 1, wherein the cathodes of the light emitting elements LD ₁₁₁ to LD ₁₂₀ of the infrared sensor for horizontal position detection and the emitters of the light receiving elements PD ₁₁₁ to PD ₁₂₀ are alternately connected in common to control common signals CO ₁ and CO. ₂ ) are connected to each other, and the cathodes of the light emitting devices LD ₂₁₁ to LD ₂₂₀ and the emitters of the light receiving devices PD ₂₁₁ to PD _{220 of the} vertical position detection infrared sensor are alternately connected in common to the common control signal CO _3. , CO ₄ ) to be applied, the anode of the light emitting elements LD ₁₁₁ ~ LD ₁₂₀ (LD ₂₁₁ ~ LD ₂₂₀ ) and the light receiving elements PD ₁₁₁ ~ PD ₁₂₀ (PD ₂₁₁ ) of the infrared sensor for horizontal and vertical position detection. ~ PD ₂₂₀ ) is the infrared sensor driving circuit of the touch screen, characterized in that the configuration is connected to the demultiplexer 13 and the multiplexer 14 by sequentially connecting two in common.