KR102251116B1 - Pen and touch sensing system using the saem - Google Patents

Abstract

The present invention relates to a pen for a touch sensing system, comprising: a guide to which a tip is fixed; A ferrite core inserted into the guide; And first and second elastic bodies disposed between the guide and the ferrite core. The first elastic body has an elastic modulus less than that of the second elastic body.

Description

Pen and touch sensing system using it {PEN AND TOUCH SENSING SYSTEM USING THE SAEM}

The present invention relates to a pen having a double spring and a touch sensing system using the pen.

A user interface (UI) enables communication between a person (user) and various electronic devices, so that a user can easily control the electronic device as desired. Representative examples of user interfaces include keypads, keyboards, mice, on-screen displays (OSDs), and remote controllers with infrared or radio frequency (RF) communication functions. User interface technology continues to develop in the direction of enhancing user sensibility and operational convenience. Recently, user interfaces are evolving into touch UIs, voice recognition UIs, and 3D UIs.

Touch UI is in the trend of being essentially adopted in portable information devices, and furthermore, it is being widely applied to home appliances. The touch UI generates location information by detecting the location of a finger or a pen that is touched on the touch screen.

The touch screen is divided into a touch screen that senses a conductor such as a finger and a touch screen that senses a pen. As an example of the latter touch screen, US Pat. No. 7,903,085 (1988. 11. 22.) discloses a special pen with a built-in resonance circuit, a loop antenna receiving a resonance signal from the pen, and position information of the pen in the signal of the loop antenna. It includes a signal processing unit that extracts (Pen location) and pen pressure information.

Due to the structure of the pen used in the touch sensing system, the pen's writing feel is not good, and the pen may malfunction.

The present invention provides a pen capable of improving the writing feeling of a pen and preventing malfunction of the pen, and a touch sensing system using the same.

A pen for a touch sensing system according to an embodiment of the present invention includes a guide to which a tip is fixed; A ferrite core inserted into the guide; And first and second elastic bodies disposed between the guide and the ferrite core. The first elastic body has an elastic modulus less than that of the second elastic body.
The second elastic body includes a natural or artificial rubber ring, and the first elastic body includes a spring disposed between the ferrite core and the guide through a hole in the rubber ring.
In the pen for a touch sensing system according to another embodiment of the present invention, the second elastic body includes natural or artificial rubber, the rubber is disposed in the inner space of the spring, and one end is inserted into the groove of the ferrite core.
In the pen for a touch sensing system according to another embodiment of the present invention, the first elastic body includes a first spring disposed between the ferrite core and the guide, and the second elastic body is larger than the first spring. And a second spring having a diameter. The first spring is disposed in the inner space of the second spring, one end of the first spring is inserted into the groove of the ferrite core, and the other end of the first spring is inserted into the groove of the guide.
In the pen for a touch sensing system according to another embodiment of the present invention, the first elastic body includes a first spring disposed between the ferrite core and the partition wall, and the second elastic body is disposed between the partition wall and the guide And a second spring to be used. When the tip is in contact with the display panel and pressure is applied to the tip, the first elastic body is compressed, and then the second elastic body is compressed when additional pressure is applied to the tip.
A touch sensing system according to an embodiment of the present invention includes a pen with a built-in resonance circuit; A touch screen including electrodes and an antenna; And a touch driving circuit configured to receive a resonance signal of the pen through the antenna by supplying a resonance induction signal to the electrodes.
The touch driving circuit senses the pen in a first step in which the first elastic body is compressed, and measures the pen pressure of the pen in a second step in which the second elastic body is compressed.
A touch sensing system according to another exemplary embodiment of the present invention is a pen for a touch sensing system in which a tip is moved inside when contacting a substrate of a display panel, comprising: a display panel including electrodes and an antenna; And a pen including a tip contacting the display panel. When the tip is in contact with the display panel and pressure is applied to the tip, the first elastic body is compressed, and then the second elastic body is compressed when additional pressure is applied to the tip.

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In the present invention, the pen spring is a double spring structure to improve the pen's writing feel and prevent the pen from malfunctioning.

1 is a diagram schematically showing a touch sensing system according to an embodiment of the present invention.
2 is a block diagram showing a touch sensing system according to an embodiment of the present invention.
3 is a plan view showing a structure of a touch screen according to the present invention.
4 is a diagram showing an example in which a first touch driving circuit is integrated into a one-chip IC.
5 is a diagram showing one frame period in the touch sensing system of the present invention.
6 is a waveform diagram showing a pen touch sensing operation.
7 is a waveform diagram showing a finger touch sensing operation.
8 is a circuit diagram showing in detail a first touch driving circuit according to an exemplary embodiment of the present invention.
9 is a waveform diagram showing the operation of the first touch driving circuit.
10 is a diagram showing the structure of a pen.
11 is a diagram showing pen pressure data that changes according to the pressure of the pen when a single spring is applied to the pen.
12 is a diagram showing pen pressure data that changes according to the pressure of the pen when first and second elastic bodies having different elastic modulus are applied to the pen.
13A and 13B are views showing a double spring structure of a pen according to a first embodiment of the present invention.
14A and 14B are views showing a double spring structure of a pen according to a second embodiment of the present invention.
15A and 15B are views showing a dual spring structure of a pen according to a third embodiment of the present invention.
16A and 16B are views showing a dual spring structure of a pen according to a fourth embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numbers throughout the specification mean substantially the same elements. In the following description, when it is determined that a detailed description of a known function or configuration related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

Referring to FIG. 1, the touch sensing system of the present invention includes a plurality of XY electrodes (X/Y), an antenna (ANT), and a pen (PEN).

The XY electrodes X/Y are divided into an X electrode group and a Y electrode group. The X electrode group includes a plurality of X electrodes. The Y electrode group includes Y electrodes orthogonal to the X electrodes with a dielectric therebetween. The XY electrodes X/Y have substantially the same structure as electrodes formed on a conventional capacitive touch screen. Accordingly, the present invention can implement XY electrodes (X/Y) as electrodes of a touch screen for conventional finger touch sensing.

The XY electrodes X/Y overlap the pixel array of the display panel. The data of the input image is written to the pixels of the pixel array. The XY electrodes X/Y may be embedded in the pixel array. Accordingly, the XY electrodes X/Y may be formed of an electrode material having a high transmittance, for example, Indium Tin Oxide (ITO) so as to transmit light from the pixels.

The XY electrodes X/Y are capacitively coupled to the pen PEN with the capacitance Csx interposed therebetween. The capacitance Csx is a capacitance between the XY electrodes and the pen PEN. The XY electrodes X/Y transmit a resonance induction signal to the pen PEN in an electric field through the capacitance Csx.

The pen (PEN) includes an LC resonant circuit. The LC resonance circuit of the pen (PEN) resonates according to the resonance induction signal received through the capacitance (Csx) to generate a resonance signal. In the LC resonance circuit of the pen (PEN), when the tip of the pen is pressed on the touch screen, the inductance value (L) changes and the resonance frequency changes. Accordingly, a change in the pen pressure of the pen PEN causes a change in the resonance frequency. The resonance signal of the pen (PEN) is transmitted to the antenna (ANT) as a magnetic field through an electromagnetic resonance path.

The antenna ANT receives a resonance signal from the pen PEN. The antenna ANT is formed to surround the XY electrodes X/Y. The touch sensing system of the present invention detects a touch input of a finger through a change in capacitance through XY electrodes (X/Y), and performs a pen touch input using the XY electrodes (X/Y) and an antenna (ANT). To detect.

The touch sensing system of the present invention may be coupled to a display device in various forms. Display devices include Liquid Crystal Display (LCD), Field Emission Display (FED), Plasma Display Panel (PDP), Organic Light Emitting Display (OLED). , It can be implemented based on flat panel display devices such as electrophoresis (EPD). In the following embodiments, a display device as an example of a flat panel display device will be described centering on a liquid crystal display device, but the display device of the present invention is not limited to a liquid crystal display device.

2 and 3, a display device according to an exemplary embodiment of the present invention includes a display panel DIS, a display driving circuit, a touch screen TSP, a touch screen driving circuit, and the like.

A liquid crystal layer is formed between the two substrates in the display panel DIS. The pixel array of the display panel DIS includes pixels formed in a pixel area defined by data lines (D1 to Dm, m is a positive integer) and gate lines (G1 to Gn, n is a positive integer). . Each of the pixels is connected to TFTs (Thin Film Transistor) formed at the intersections of the data lines D1 to Dm and the gate lines G1 to Gn, a pixel electrode charging the data voltage, and a pixel electrode. It includes a storage capacitor (Cst) for maintaining the voltage.

A black matrix, a color filter, and the like are formed on the upper substrate of the display panel DIS. The lower substrate of the display panel DIS may be implemented in a color filter on TFT (COT) structure. In this case, the black matrix and the color filter may be formed on the lower substrate of the display panel DIS. The common electrode to which the common voltage Vcom is supplied may be formed on the upper or lower substrate of the display panel DIS. A polarizing plate is attached to each of the upper and lower substrates of the display panel DIS, and an alignment layer for setting a pretilt angle of the liquid crystal is formed on an inner surface in contact with the liquid crystal. A column spacer is formed between the upper substrate and the lower substrate of the display panel DIS to maintain a cell gap of the liquid crystal cell.

A backlight unit may be disposed under the rear surface of the display panel DIS. The backlight unit is implemented as an edge type or direct type backlight unit and irradiates light to the display panel DIS. The display panel DIS may be implemented in any known liquid crystal mode such as a twisted nematic (TN) mode, a vertical alignment (VA) mode, an in plane switching (IPS) mode, and a fringe field switching (FFS) mode.

The display driving circuit includes a data driving circuit 12, a scan driving circuit 14, and a timing controller 20 to write data of an input image to pixels of the display panel DIS. The data driving circuit 12 converts digital video data RGB of an input image input from the timing controller 20 into an analog positive/negative gamma compensation voltage and outputs a data voltage. The data voltage output from the data driving circuit 12 is supplied to the data lines D1 to Dm. The scan driving circuit 14 selects a line of the display panel DIS in which data is written by sequentially supplying a gate pulse (or scan pulse) synchronous to the data voltage to the gate lines G1 to Gn.

The timing controller 20 inputs timing signals such as a vertical synchronization signal (Vsync), a horizontal synchronization signal (Hsync), a data enable signal (Data Enable, DE), and a main clock (MCLK) input from the host system 40. Receive and synchronize the operation timing of the data driving circuit 12 and the scan driving circuit 14. The scan timing control signal includes a gate start pulse (GSP), a gate shift clock, a gate output enable signal (Gate Output Enable, GOE), and the like. The data timing control signal includes a source sampling clock (SSC), a polarity control signal (Polarity, POL), a source output enable signal (Source Output Enable, SOE), and the like.

The timing controller 20 controls the operating frequency of the display driving circuit and the touch screen driving circuit at a frame rate multiplied by N times by increasing the frame rate at a frequency of the input image frame rate × N (N is a positive integer greater than or equal to 2) Hz. can do. The frame rate of the input video is 60 Hz (1 frame period: 16.67 msec) in the NTSC (National Television Standards Committee) method, and 50 Hz (1 frame period: 20 msec) in the PAL (Phase-Alternating Line) method.

The touch screen TSP includes XY electrodes X1 to Xi and Y1 to Yj and an antenna ANT. At the intersections of the XY electrodes X1 to Xi and Y1 to Yj, touch sensors whose electric charges vary depending on the presence or absence of a conductor such as a finger are formed. The touch sensors detect a touch input according to a change in a capacitance value that changes according to the presence or absence of a touch. The XY electrodes X1 to Xi and Y1 to Yj may be implemented as electrodes used in a conventional capacitive touch screen that senses a touch input of a finger. Therefore, the touch screen (TSP) of the present invention can be simply implemented by adding an antenna (ANT) to the edge of the conventional capacitive touch screen.

The XY electrodes X1 to Xi and Y1 to Yj of the touch screen TSP and the antenna ANT may be bonded to the upper polarizing plate of the display panel DIS or formed between the upper polarizing plate and the upper substrate. In addition, the XY electrodes (X1 to Xi, Y1 to Yj) of the touch screen (TSP) and the antenna (ANT) are built in an in-cell type with a pixel array in the display panel DIS on the lower substrate. Can be. The XY electrodes X1 to Xi and Y1 to Yj of the touch screen TSP and the antenna ANT may be formed on the same plane or different planes. When the touch screen is embedded on the lower substrate together with the pixel array, the XY electrodes X1 to Xi and Y1 to Yj may be implemented by dividing the common electrode of the pixel array.

The touch screen driving circuit includes a first touch driving circuit 30 and a second touch driving circuit 32. The first and second touch driving circuits 30 and 32 may be integrated in one IC chip. Components having the same function in the first and second touch driving circuits 30 and 32 may be shared.

The first touch driving circuit 30 sequentially supplies a resonance induction signal to the XY electrodes X1 to Xi and Y1 to Yj and receives a resonance signal of the pen through the antenna ANT. The first touch driving circuit 30 measures a resonance size for each resonance frequency by converting the resonance signal of the pen received through the antenna ANT into digital data. The first touch driving circuit 30 determines the pen location (XY) by comparing the resonance magnitude of the received resonance signal with a predetermined reference value, and based on the frequency change of the received resonance signal. Measure pen pressure. Pen position and pen pressure information (XY(PEN)) generated from the first touch driving circuit 30 is transmitted to the host system 40.

The second touch driving circuit 32 applies a stimulus signal (or a driving signal) to the touch sensor Cts, and receives electric charges from the touch sensor in synchronization with the stimulus signal. The second touch driving circuit 32 determines a change in capacitance before and after the touch by analyzing the received charge amount, and senses the touch position of the finger based on the change in the capacitance.

The touch sensor Cst may be implemented with self capacitance or mutual capacitance. The second touch driving circuit 32 sequentially supplies a stimulus signal to the X electrodes or XY electrodes X1 to Xi and Y1 to Yj, and in synchronization with the stimulus signal, the power failure before and after the touch of the touch sensor Cts. It detects the change in capacity and converts it into digital data. The second touch driving circuit 32 determines touch position information (XY (FINGER)) of the finger by comparing the digital data with a predetermined reference value. The touch position information XY (FINGER) of the finger generated from the second touch driving circuit 32 is transmitted to the host system 40. The stimulus signal may be generated in various types of signals such as pulses and triangle waves. The second touch driving circuit 32 may be implemented as a touch driving circuit used in an existing capacitive touch screen that senses a finger touch input.

The host system 40 is implemented in any one of a television system, a set-top box, a navigation system, a DVD player, a Blu-ray player, a personal computer (PC), a home theater system, and a phone system to receive an input image. The host system 40 receives pen position and pen pressure information (XY (PEN)) from the first touch driving circuit 30, and touch position information of the finger (XY (FINGER) from the second touch sensor driving circuit 32). )) is received.

The host system 40 converts digital video data RGB of an input image into a format suitable for display on the display panel DIS, including a system on chip (SoC) with a built-in scaler. The host system 40 transmits the timing signals Vsync, Hsync, DE, and MCLK together with the digital video data of the input image to the timing controller 20. In addition, the host system 40 includes the position and pressure information (XY (PEN)) of the pen (PEN) input from the first and second touch driving circuits 30 and 32, and the touch position information (XY (FINGER) Run the application program linked to ).

The XY electrodes X1 to X6 and Y1 to Y6 are the X electrodes X1 to X6 arranged side by side along the x-axis as shown in FIG. 3, and the X electrodes X1 to X6 are arranged side by side along the y-axis. It includes orthogonal Y electrodes Y1 to Y6. The antenna AND may be formed in a region of the bezel (BZ) outside the pixel array in which an image is displayed so that the aperture ratio of the pixels does not decrease. The bezel is a non-display area formed along the edge of the display panel. Since the antenna ANT may be formed on the same layer as the XY electrodes X1 to X6 and Y1 to Y6, the thickness of the display panel DIS does not increase. The first touch driving circuit 30 is connected to the antenna ANT through the antenna pad APAD, and is connected to the XY electrodes X1 to X6 and Y1 to Y6 through the XY pads XYPAD.

The first touch driving circuit 30 is a diagram showing an example integrated into a one chip integrated circuit (IC) as shown in FIG. 4.

Referring to FIG. 4, the one-chip IC includes an analog signal processing unit 100, a digital signal processing unit 200, a micro processor unit (hereinafter referred to as "MPU") 300, an interface circuit 310, and It includes a memory 320.

The digital signal processing unit 200 includes a memory 2. The memory 2 stores the resonance characteristics for each frequency of the received resonance signal, temporarily stores previous data in order to accumulate data in the integrators 214 and 216 shown in FIG. 8, and stores the position and pen pressure determination unit 218. Temporarily save the output data of ).

The microprocessor unit 300 stores the pen position and pen pressure information (XY(PEN)) in the memory 320. The microprocessor unit 300 interpolates the coordinate information of the pen input position in order to convert the resolution of the touch screen (TSP) to the resolution of the display, and executes an additional algorithm for removing noise and improving touch recognition performance. have. The interface circuit 310 transmits the pen position and pen pressure information (XY(PEN)) to the host system 40 through a standard interface.

5 is a diagram showing one frame period in the touch sensing system of the present invention.

Referring to FIG. 5, when the touch screen TSP is embedded in the pixel array of the display panel DIS, one frame period is a display period Tdis, a first touch sensing period Tpen, and a first frame period as shown in (A). It can be time-divided into 2 touch sensing periods (Tfinger).

When the touch screen TSP is embedded in the pixel array of the display panel DIS, the XY electrodes X/Y of the touch screen may serve as common electrodes supplying the common voltage Vcom to the pixels. In this case, the common voltage Vcom is supplied to the XY electrodes X/Y during the display period Tdis, and a stimulus signal or a resonance induction signal is supplied during the touch sensing periods Tpen and Tfinger.

During the display period Tdis, the display driving circuit is driven to write data of the input image to the pixels of the display panel DIS. During the first touch sensing period Tpen, the first touch driving circuit 30 senses the touch position and the pen pressure of the pen on the touch screen TSP. During the second touch sensing period Tfinger, the second touch driving circuit 32 senses the touch position of a conductor such as a finger on the touch screen TSP.

When the touch screen TSP is formed on an upper plate separated from the pixel array of the display panel DIS, there is little electrical coupling between the touch screen TSP and the pixel array. In this case, as shown in (B), the display period Tdis is allocated as one frame period, and the first and second touch sensing periods Tpen and Tfinger may be time-divided within one frame period. The display period Tdis may overlap with the first and second touch sensing periods Tpen and Tfinger.

6 is a waveform diagram showing a pen touch sensing operation.

Referring to FIG. 6, the first touch driving circuit 30 operates in a first touch sensing period Tpen to sequentially supply a resonance induction signal to the XY electrodes Y1 to Yj and X1 to Xi to provide a pen (PEN). ) Induces resonance. The resonant circuit of the pen PEN resonates according to a resonant induction signal input into an electric field through a capacitance Csx to generate a resonant signal. The antenna ANT receives a resonance signal of the pen PEN by a change in the magnetic field. The first touch driving circuit 30 converts the analog resonance signal received through the antenna ANT into digital data, calculates the amplitude and phase of the resonance signal from the digital data, and senses the position of the pen and the pen pressure of the pen.

7 is a waveform diagram showing a finger touch sensing operation.

Referring to FIG. 7, the second touch driving circuit 32 operates in a second touch sensing period Tfinger. In the case of mutual capacitance, the second touch driving circuit 32 sequentially supplies a stimulation signal to the Y electrodes Y1 to Yj, and in synchronization with the stimulation signal, the touch sensor ( Cts) of charges. When a finger is touched on the touch sensor Cts, the second touch driving circuit 32 senses a touch input based on the amount of charge change of the touch sensor Cts before and after the touch. Accordingly, during the second touch sensing period Tfinger, the Y electrodes Y1 to Yj of the Y electrode group operate as Tx channel electrodes supplying the stimulus signal to the touch sensors Cts, and the X electrode of the X electrode group The s X1 to Xi operate as Rx channel electrodes receiving electric charges from the touch sensors Cts.

In the case of self-capacitance, the second touch driving circuit 32 sequentially supplies stimulation signals to the X electrodes X1 to Xi and the Y electrodes Y1 to Yj. In the case of self-capacitance, the second touch driving circuit 32 includes a falling edge time of the stimulus signal before and after the touch through the X electrodes X1 to Xi and the Y electrodes Y1 to Yj, or A touch input is sensed based on a change in a rising edge time.

8 is a circuit diagram showing the first touch driving circuit 30 in detail. 9 is a waveform diagram showing an operation of the first touch driving circuit 30.

8 and 9, the first touch driving circuit 30 includes an analog signal processing unit 100 and a digital signal processing unit 200.

The pen PEN includes an LC parallel resonance circuit in which the inductor L and the capacitor C are connected in parallel. In the resonance circuit of the pen (PEN), when the tip is pressed on the touch screen, the LC value changes and the resonance frequency changes. In FIG. 12,'Ch' connected to the pen (PEN) represents capacitance generated when a human holds the pen (PEN). When the frequency of the resonance induction signal applied to the pen PEN through the capacitance Csx coincides with the resonance frequency of the LC parallel resonance circuit, the pen generates a resonance signal. Therefore, the pen (PEN) does not require a separate power supply connected to the LC parallel resonance circuit. The resonance signal of the pen PEN is received by the antenna ANT.

The resonance induction signal applied to the pen PEN is generated by the digital signal processing unit 200. The resonance induction signal may be generated by the digital signal processing unit 200 in various forms, such as a square wave signal and a sinusoidal wave signal. The digital signal processing unit 200 may generate a resonance induction signal having a desired frequency by combining signals having different periods. In addition, the digital signal processor may change the frequency of the resonance induction signal by changing the period value of the resonance induction signal.

In the LC parallel resonance circuit of the PEN, the inductance varies according to the pressure of the pen. The present invention can determine the pen pressure by using a resonance frequency that changes when the pen pressure occurs.

으로 나타낼 수 있다. 펜의 필압에 따라 공진 주파수(ω)가 변할 수 있다. (A) is an example of a square wave resonance induction signal applied to a pen (PEN) by an electric field through Csx. (A') is an analog signal measured by the antenna ANT when a resonance signal generated from the pen PEN according to the square wave resonance induction signal A is received by the antenna ANT. The resonance signal generated by the pen (PEN) is

It can be represented by The resonance frequency (ω) may change depending on the pen pressure of the pen.

The analog signal processing unit 100 amplifies the analog resonance signal received through the antenna ANT, extracts the resonance signal frequency band of the pen PEN, and outputs the digital resonance signal. To this end, the analog signal processing unit 100 includes an amplifier 110, a band pass filter (hereinafter referred to as "BPF") 112, and an analog to digital converter (hereinafter referred to as "ADC"). ) (114).

The amplifier 110 amplifies the antenna signal by its own gain and transmits it to the BPF 112. (B) is an antenna signal amplified by the amplifier 110. The BPF 112 removes noise from the antenna signal by blocking a frequency band other than the resonance frequency of the LC parallel circuit and extracts the resonance signal. The ADC 114 quantizes the resonance signal input from the BPF 112 and outputs a digital resonance signal.

으로 나타낼 수 있다. S(t)는 공진 신호의 진폭이다. ω는 공진 주파수이고,

는 위상을 의미한다. (C) is a digital resonance signal output from the ADC 114

It can be represented by S(t) is the amplitude of the resonance signal. ω is the resonant frequency,

Means phase.

The digital signal processing unit 200 extracts the real part and the imaginary part when expressing the resonance signal as a complex number from the digital signal input from the analog signal processing unit 100, and calculates the amplitude, that is, the amplitude of the resonance signal based on this. In addition, the digital signal processing unit 200 compares the magnitude of the resonance signal with a predetermined reference value to determine whether the pen is sensed on the touch screen, and at that time, the pen PEN based on the position of the XY electrode to which the resonance signal is applied. Calculate the location coordinates of ). In addition, the digital signal processing unit 200 determines the pen pressure of the pen PEN based on the change in the frequency of the resonance signal of the pen PEN. To this end, the digital signal processing unit 200 includes a resonance induction signal generation unit 230, a digital demodulator 250, and a position and pen pressure determination unit 218.

The resonance induction signal generator 230 generates a resonance induction signal having the same frequency as the resonance frequency of the pen PEN, and sequentially supplies the resonance induction signal to the XY electrodes X1 to Xi and Y1 to Yj. The resonance induction signal generator 230 is composed of a digital circuit having a built-in counter for adjusting the frequency of the resonance induction signal. In such a digital circuit, the frequency control resolution increases as the counter clock increases, but there is a limit because power consumption increases by that amount. In the present invention, the frequency control resolution can be further improved as compared to a method of simply increasing the counter operation clock by increasing the frequency resolution by changing the period of the resonance induction signal every period.

When it is determined that the pen PEN is located on the touch screen TSP based on the position and the output of the pen pressure determination unit 218, the XY electrodes X1 to Xi, Y1 to Yj to which the resonance induction signal is applied at that time The position of the pen PEN may be determined based on the coordinate information of.

The digital demodulator 250 extracts the real part and the imaginary part of the resonance signal from the digital resonance signal and adds the result of removing the high frequency noise n (n is a positive integer greater than or equal to 2) times and supplies it to the position and pen pressure determination unit 218. . To this end, the digital demodulator 250 includes first and second oscillators 206 and 208, first and second multipliers 202 and 204, and first and second low pass filters (hereinafter "LPF"). )) (210, 212), first and second integrators (214, 216), and the like.

이라 할 때, (D)는

으로 나타낼 수 있다. The first oscillator 206 inputs the oscillation signal D having the same frequency and phase as the frequency of the resonance signal to the first multiplier 202 in order to extract the real part of the resonance signal. 12 and 14, (C)

When we say this, (D) is

It can be represented by

이라 하고 (D)를

이라 할 때, 제1 승산기(202)의 출력(E)는

으로 나타낼 수 있다. 제1 LPF(210)는 제1 승산기(202)의 출력(E)에서 고주파 노이즈를 제거하여 직류 성분(DC)을 제1 적분기(214)에 공급한다. 제1 LPF(210)의 출력(F)는 (E)를

이라 할 때

으로 나타낼 수 있다. The first multiplier 202 detects an envelope of a real part in the received resonance signal. The first multiplier 202 multiplies the received resonance signal C by the oscillation signal D from the first oscillator 206 and outputs the result E. (C)

And (D)

In this case, the output E of the first multiplier 202 is

It can be represented by The first LPF 210 removes high-frequency noise from the output E of the first multiplier 202 and supplies a direct current component DC to the first integrator 214. The output (F) of the first LPF 210 is (E)

When I say this

It can be represented by

로 나타낼 수 있다.The first integrator 214 sums up the real part (In-Phase, I) data input from the first LPF 210 n times and supplies the result to the position and pen pressure determination unit 218. If the data is added 1024 times in the first integrator 214, (G) is

It can be expressed as

이라 할 때, 제2 발진기(208)의 출력은

으로 나타낼 수 있다. 제2 승산기(204)는 수신된 공진 신호에서 허수부의 포락선을 검출한다. 제2 승산기(204)는 수신된 공진 신호(C)와 제2 발진기(208)로부터의 발진신호를 곱하여

을 출력한다. 제2 LPF(212)는 제2 승산기(204)의 출력(K)에서 고주파 노이즈를 제거하여 직류 성분(DC)을 제2 적분기(216)에 공급한다. 제2 LPF(212)의 출력은

로 나타낼 수 있다.The second oscillator 208 inputs an oscillating signal equal to the frequency of the resonance signal and delayed by 90° to extract the imaginary part of the resonance signal to the second multiplier 204. (C)

In this case, the output of the second oscillator 208 is

It can be represented by The second multiplier 204 detects the envelope of the imaginary part from the received resonance signal. The second multiplier 204 multiplies the received resonance signal C by the oscillation signal from the second oscillator 208

Prints. The second LPF 212 removes high-frequency noise from the output K of the second multiplier 204 and supplies a direct current component DC to the second integrator 216. The output of the second LPF 212 is

It can be expressed as

로 나타낼 수 있다.The second integrator 216 adds the data of the imaginary part (Quadrature, Q) received from the second LPF 212 n times and supplies the result to the position and pen pressure determination part 218. If the imaginary part data is added 1024 times in the second integrator 216, (H) is

It can be expressed as

으로 계산된다. I_sum은 제1 적분기(214)에 의해 누적된 공진 신호의 실수부(In-phase)이고 Q_sum은 제2 적분기(216)에 의해 누적된 공진 신호의 허수부(Quadrature, Q)이다. The position and pen pressure determination unit 218 calculates a root mean square (RMS) of data input from the first and second integrators 214 and 216 to determine the size and resonance frequency of the resonance signal. The effective value is

Is calculated as. I _sum is the real part (In-phase) of the resonance signal accumulated by the first integrator 214 and Q _sum is the imaginary part (Quadrature, Q) of the resonance signal accumulated by the second integrator 216.

The position and pen pressure determination unit 218 compares the magnitude of the resonance signal with a predetermined reference value and determines that the pen is positioned on the touch screen TSP when the magnitude of the resonance signal is greater than the reference value, and at that time, a resonance induction signal is applied. The pen position information is output based on the coordinates of the XY electrode. The position and pressure determination unit 218 calculates the pen pressure of the pen PEN based on the change in the resonance frequency and outputs pen pressure information. In FIG. 8, PL is position data of the pen, and PP is pressure data of the pen.

The first and second oscillators 206 and 208 may be implemented as a digital pulse generator capable of changing an output frequency, for example, a numerically controlled oscillator (NCO).

10 is a diagram showing the structure of a pen (PEN).

Referring to FIG. 10, a pen (PEN) is attached to a guide (guide) 53 to which a tip 51 is fixed, a spring 52 installed in the guide 53, a ferrite core (55), and a guide (53). It includes a wound coil 54, and an LC resonant circuit 56 connected to the coil 54. The tip 51 is made of a conductor such as metal. The coil 54 is an inductor L connected to the LC resonant circuit 56.

The guide 53 is manufactured in a cylindrical shape, and a spring 51 and a ferrite core 55 are inserted therein. A part of the ferrite core 55 is inserted into the guide 73. When the tip 51 is pressed by external pressure, the spring 52 and the guide 53 move along the tip 51, and the ferrite core 55 moves with the elastic restoring force of the spring 52. When the ferrite core 55 moves, the overlapped area with the coil 54 increases, thereby increasing the magnetic flux density. An increase in magnetic flux density results in an increase in inductance. Accordingly, when the tip is subjected to pressure, the frequency of the resonance signal output from the LC resonance circuit 56 is changed, so that the pen pressure of the pen can be measured.

Spring 52 is generally composed of only a single spring. However, in this case, the pen's writing feeling and pressure measurement may become inaccurate. In the case of using a single spring, a spring with a large modulus of elasticity should be used to widen the pen pressure measurement range. When the elastic modulus of the spring 52 is large, the spring 52 is compressed only when a strong pressure is applied to the tip of the pen, so that the writing feeling felt by the user is not smooth.

When a single spring is used, the pen pressure data PP linearly increases in proportion to the pressure applied to the tip 51 of the pen as shown in FIG. 11. In FIG. 11, the x-axis is the pen pressure (gf), and the y-axis is the pen pressure data. The difference between the pen pressure data A immediately before the tip 51 comes into contact with the substrate and the pen pressure data B at the moment when the tip 51 comes into contact with the substrate is not significant. Since the data difference between the data A and B is small and there is a deviation between the data, it is difficult to set a threshold value for determining whether the pen is in contact. The threshold value is generally determined as data at the moment of contact contact (B), but when there is data deviation, this threshold value may cause malfunction of the touch sensing system. For example, if data deviation occurs while the threshold is set to data (B), the data (C) is misrecognized as the data at the moment of contact, and the data (B) is misrecognized as the data just before the contact, and the tip 51 Before contacting this substrate, a resonance signal may be generated from the pen.

In the present invention, the spring 52 uses first and second elastic bodies having different elastic modulus to improve the pen's writing feel and prevent the pen from malfunctioning.

12 is a diagram showing pen pressure data that changes according to the pressure of the pen when first and second elastic bodies having different elastic modulus are applied to the pen. In FIG. 12, the x-axis is the distance (μm) that the tip 51 moves, and the y-axis is the pen pressure (gf).

Referring to FIG. 12, the spring 52 of the present invention includes a first elastic body having a first elastic modulus and a second elastic body having a second elastic modulus. The second modulus of elasticity is higher than the first modulus of elasticity.

The pen pressure of the present invention is divided into a first step (S1) of sensing the pen and a second step (S2) of measuring the pen pressure.

The first step (S1) is a pen sensing section when the tip 51 moves from m to n immediately after contacting the substrate. The first step (S1) is a section in which the first elastic body having a low elastic modulus is compressed. In the first step S1, when the distance of the tip 51 changes, the pen pressure changes to a low slope. The user can feel a soft writing feeling because the tip 51 of the pen moves up to a certain distance n with a small pressure. Accordingly, in the first step S1, a state in which the pen is in contact with the substrate is sensed and the user feels a smooth change in the pen pressure, thereby improving the writing feel.

The second step S2 is a section in which the pen pressure changes to a high slope when the tip 51 moves further than the first step S1. The second step (S2) is a section in which the second elastic body having a high elastic modulus is compressed. The second step (S2) is a section in which the pen pressure data is extracted and the pen pressure is measured. Since the pen pressure data is not extracted in the first step S1, the pen pressure of the pen is measured only in the second step S2. In the second stage structure, an elastic body having a large elastic modulus is used, and in the second stage (S2), the pen pressure changes sharply according to a change in the distance of the tip 51, so the pen pressure change can be divided into several stages to express the pen pressure change sensitively. .

After the tip 51 contacts the substrate, the pen pressure starts to be measured after the tip 51 moves up to a certain distance n. Therefore, if a threshold value for discriminating whether the pen is in contact is set between the first step (S1) and the second step (S2), it is possible to accurately determine whether the pen is in contact with the substrate even if there is a deviation in pen pressure data.

13A to 16 are views showing a double spring structure of a pen according to an embodiment of the present invention.

13A and 13B, the double spring structure includes first and second elastic bodies 73 and 74 installed between the ferrite core 71 and the guide 72.

The first elastic body 73 may be made of a spring having a small elastic modulus. One end of the first elastic body 73 is inserted into the groove 71a of the ferrite core 71, and the other end of the first elastic body 73 is inserted into the groove of the guide 72.

The second elastic body 74 may be made of a natural or artificial rubber ring having a high elastic modulus. The first elastic body 73 is disposed between the ferrite core 71 and the guide 72 through a hole in the rubber ring.

When the tip 51 is in contact with the substrate and pushed into the inside of the pen, the first elastic body 73 is compressed until the first step (S1), and when the tip 51 moves further, the second step (S2) is The elastic body 74 is compressed. In the present invention, the pen is sensed in the first step (S1) in which the first elastic body 73 is compressed, and the pen pressure of the pen is measured in the second step (S1) in which the second elastic body 74 is compressed.

14A and 14B, the double spring structure includes first and second elastic bodies 73 and 75 installed between the ferrite core 71 and the guide 72.

The first elastic body 73 may be made of a spring having a small elastic modulus. The first elastic body 73 is disposed between the guide 72 and the ferrite core 71.

The second elastic body 75 may be made of natural or artificial rubber having a high elastic modulus. The second elastic body 75 is disposed in a space inside the spring of the first elastic body 73. One end of the second elastic body 75 is inserted into the groove of the first elastic body 73.

When the tip 51 is in contact with the substrate and pushed into the inside of the pen, the first elastic body 73 is compressed until the first step (S1), and when the tip 51 moves further, the second step (S2) is The elastic body 75 is compressed. In the present invention, the pen is sensed in the first step S1 in which the first elastic body 72 is compressed, and the pen pressure of the pen is measured in the second step S1 in which the second elastic body 75 is compressed.

15A and 15B, the double spring structure includes first and second elastic bodies 73 and 76 installed between the ferrite core 71 and the guide 72.

The first elastic body 73 may be made of a spring having a small elastic modulus. One end of the first elastic body 73 is inserted into the groove of the ferrite core 71, and the other end of the first elastic body 73 is inserted into the groove of the guide 72.

The second elastic body 76 may be made of a spring having a high elastic modulus. The spring of the second elastic body 76 has a larger diameter than the spring of the first elastic body 73. The spring of the first elastic body 73 is disposed in a space inside the spring of the second elastic body 76.

When the tip 51 is in contact with the substrate and pushed into the inside of the pen, the first elastic body 73 is compressed until the first step (S1), and when the tip 51 moves further, the second step (S2) is The elastic body 76 is compressed. In the present invention, the pen is sensed in the first step S1 in which the first elastic body 72 is compressed, and the pen pressure of the pen is measured in the second step S1 in which the second elastic body 76 is compressed.

16A and 16B, the double spring structure separates the first and second elastic bodies 73 and 77 installed between the ferrite core 71 and the guide 72, and the elastic bodies 73 and 77. It includes a partition (78).

The first elastic body 73 may be made of a spring having a small elastic modulus. The first elastic body 73 is disposed between the ferrite core 71 and the partition wall 78 in the guide 72. The partition wall 78 separates the first elastic body 73 and the second elastic body 77 and is not fixed. The partition wall 78 may be made of various materials such as metal and plastic. One end of the first elastic body 73 is inserted into the groove of the ferrite core 71 and the other end is in contact with the partition wall 78.

The second elastic body 77 may be made of a spring having a high elastic modulus. The second elastic body 77 is disposed between the ferrite core 71 and the partition wall 78 in the guide 72. One end of the second elastic body 77 is inserted into the groove of the guide 72 and the other end is in contact with the partition wall 78.

It will be appreciated by those skilled in the art through the above description that various changes and modifications can be made without departing from the technical idea of the present invention. Accordingly, the technical scope of the present invention should not be limited to the content described in the detailed description of the specification, but should be determined by the claims.

DIS: Display panel TSP: Touch screen
12: data driving circuit 14: scan driving circuit
20: timing controller 30: first touch drive circuit
32: second touch drive circuit 40: host system
50: wiring 71: ferrite core
72: guide 73: first elastic body
74, 75, 76, 77: second elastic body 78: partition wall

Claims (9)

delete A guide to which the tip is fixed;
A ferrite core inserted into the guide; And
Including first and second elastic bodies disposed between the guide and the ferrite core,
The first elastic body has an elastic modulus less than that of the second elastic body,
The second elastic body comprises a natural or artificial rubber ring,
The first elastic body pen for a touch sensing system including a spring disposed between the ferrite core and the guide through the hole of the rubber ring. A guide to which the tip is fixed;
A ferrite core inserted into the guide; And
Including first and second elastic bodies disposed between the guide and the ferrite core,
The first elastic body has an elastic modulus less than that of the second elastic body,
The first elastic body includes a spring disposed between the ferrite core and the guide,
The second elastic body comprises natural or artificial rubber,
The pen for a touch sensing system in which the rubber is disposed in the inner space of the spring and one end is inserted into the groove of the ferrite core. A guide to which the tip is fixed;
A ferrite core inserted into the guide; And
Including first and second elastic bodies disposed between the guide and the ferrite core,
The first elastic body has an elastic modulus less than that of the second elastic body,
The first elastic body includes a first spring disposed between the ferrite core and the guide,
The second elastic body includes a second spring having a larger diameter than the first spring,
The first spring is disposed in the inner space of the second spring,
A pen for a touch sensing system in which one end of the first spring is inserted into a groove of the ferrite core, and the other end of the first spring is inserted into a groove of the guide. In a pen for a touch sensing system in which a tip is moved inside when contacting a display panel,
A guide to which the tip is fixed;
A ferrite core inserted into the guide;
First and second elastic bodies disposed between the guide and the ferrite core; And
And a partition wall separating the first elastic body and the second elastic body,
The first elastic body has an elastic modulus less than that of the second elastic body,
The first elastic body includes a first spring disposed between the ferrite core and the partition wall,
The second elastic body includes a second spring disposed between the partition wall and the guide,
A pen for a touch sensing system in which the second elastic body is compressed when pressure is further applied to the tip after the first elastic body is compressed when the tip is in contact with the display panel and pressure is applied to the tip. delete A pen with a built-in resonance circuit;
A touch screen including electrodes and an antenna; And
A touch driving circuit for receiving a resonance signal of the pen through the antenna by supplying a resonance induction signal to the electrodes,
The pen,
A guide to which the tip is fixed;
A ferrite core inserted into the guide; And
Including first and second elastic bodies disposed between the guide and the ferrite core,
The first elastic body has an elastic modulus less than that of the second elastic body,
The touch driving circuit senses the pen in a first step in which the first elastic body is compressed, and measures the pen pressure of the pen in a second step in which the second elastic body is compressed. A display panel including electrodes and an antenna; And
Including a pen including a tip contacting the display panel,
The pen,
A guide to which the tip is fixed;
A ferrite core inserted into the guide; And
Further comprising first and second elastic bodies disposed between the guide and the ferrite core,
The first elastic body has an elastic modulus less than that of the second elastic body,
A touch sensing system in which the second elastic body is compressed when pressure is applied to the tip after the first elastic body is compressed when the tip is in contact with the display panel and pressure is applied to the tip. The method of claim 8,
A touch sensing system further comprising a touch driving circuit configured to sense the pen in a first step in which the first elastic body is compressed, and measure a pen pressure of the pen in a second step in which the second elastic body is compressed.

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