Source: https://insight.rpxcorp.com/pat/US20100060610A1
Timestamp: 2020-02-20 12:10:50
Document Index: 449489085

Matched Legal Cases: ['art.\n4', 'art 411', 'art 421', 'art 411', 'art 411', 'art 421', 'art 421', 'art 411', 'art 421', 'art 411', 'art 411', 'art 421', 'art 421', 'art 411', 'art 421', 'art 411', 'art 411', 'art 421', 'art 511', 'art 521', 'art 511', 'art 521', 'art 511', 'art 521', 'art 511', 'art 511', 'art 511', 'art 521', 'art 511', 'art 521', 'art 511', 'art 521', 'art 521', 'art 611', 'art 621', 'art 611', 'art 621', 'art 611', 'art 621', 'art 611', 'art 611', 'art 621']

Patent US 20100060610A1
1. A sensing circuit for a capacitive touch panel, comprising:
a sensing signal part for generating a sensing signal according to a capacitance of the capacitive touch panel and a noise which is received by the sensing signal part, wherein the capacitance of the capacitive touch panel at a touched condition is different from the capacitance of the capacitive touch panel at an untouched condition;
a reference signal part for receiving the noise and outputting a reference signal, the reference signal part having the same electrical conditions as the sensing signal part; and
an integrator for receiving the sensing signal and the reference signal, subtracting the reference signal from the sensing signal to generate an output signal.
A sensing circuit for a capacitive touch panel is disclosed. By adding a path for a noise to pass through, the noise is differentially processed through two paths which have the same electrical conditions with each other. The noise is then decreased significantly, and a sensing signal can be detected correctly.
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2. The sensing circuit of claim 1, wherein the reference signal part has a capacitance substantially equal to a capacitance of the sensing signal part at the untouched condition.
3. The sensing circuit of claim 1, wherein the reference signal part has a plurality of electrical elements, and the electrical elements are connected in a manner so as to simulate equivalent circuits of the sensing signal part.
4. The sensing circuit of claim 1, wherein the integrator comprises:
a first differential amplifier having an inverting input, a non-inverting input, and an output;
a first resistor having a first end coupled to the sensing signal part and a second end coupled to the inverting input; and
a first capacitor having a first end coupled to the inverting input and a second end coupled to the output.
5. The sensing circuit of claim 4, wherein the integrator further comprises a ground match unit, the ground match unit comprises:
a second resistor having a first end coupled to the reference signal part and a second end coupled to the non-inverting input; and
a second capacitor having a first end coupled to the non-inverting input and a second end coupled to a ground,wherein a resistance of the second resistor is substantially equal to a resistance of the first resistor, and a capacitance of the second capacitor is substantially equal to a capacitance of the first capacitor.
6. The sensing circuit of claim 1, wherein the sensing signal part comprises:
a sensing unit for receiving the noise through a parasitic capacitance, the sensing unit having a first equivalent capacitance or a second equivalent capacitance, wherein the first equivalent capacitance is an equivalent capacitance of the capacitance of the capacitive touch panel at the touched condition and the parasitic capacitance, and the second equivalent capacitance is an equivalent capacitance of the capacitance of the capacitive touch panel at the untouched condition and the parasitic capacitance; and
a sensing signal generating unit coupled to the sensing unit, for generating the sensing signal according to the first equivalent capacitance and the noise or according to the second equivalent capacitance and the noise, andwherein the reference signal part comprises;
a reference unit, for receiving the noise, the reference unit having a third capacitance, wherein the third capacitance simulates the capacitance of the capacitive touch panel at the untouched condition and the parasitic capacitance; and
a reference signal generating unit coupled to the reference unit, for outputting the reference signal according to the third equivalent capacitance and the noise,wherein the reference unit has the same circuits as the sensing unit, and the reference signal generating unit has the same circuits as the sensing signal generating unit.
7. The sensing circuit of claim 6, wherein the sensing signal part further comprises a first filter coupled between the sensing signal generating unit and the integrator for filtering out high-frequency components of the sensing signal generated by the sensing signal generating unit, and the reference signal part further comprises a second filter coupled between the reference signal generating unit and the integrator for filtering out high-frequency components of the reference signal, and the second filter has the same circuits as the first filter.
8. The sensing circuit of claim 6, further comprising:
a first coupling capacitor through which a controlling signal being coupled to the sensing signal generating unit; and
a second coupling capacitor through which the controlling signal being coupled to the reference signal generating unit, wherein a capacitance of the first coupling capacitor is substantially equal to a capacitance of the second coupling capacitor.
9. The sensing circuit of claim 6, wherein the reference unit comprises a capacitor, a capacitance of the capacitor is substantially equal to the parasitic capacitance, and the noise is coupled to the reference unit through the capacitor.
10. The sensing circuit of claim 1, further comprising an amplifying unit coupled to the integrator, for amplifying the output signal generated by the integrator.
11. An electronic apparatus, comprising a capacitive touch panel, the capacitive touch panel comprising the sensing circuit of claim 1, wherein the electronic apparatus is a mobile phone, a digital camera, a Personal Digital Assistant, a notebook, a desktop computer, a television, a Global Positioning System, a vehicle display, an aeronautical display, or a portable DVD player.
12. A sensing circuit for a capacitive touch panel, comprising:
a sensing signal path for generating a sensing signal according to a capacitance of the capacitive touch panel and a noise which is received by the sensing signal path, wherein the capacitance of the capacitive touch panel at a touched condition is different from the capacitance of the capacitive touch panel at an untouched condition;
a reference signal path for receiving the noise and outputting a reference signal, the reference signal path having the same electrical conditions as the sensing signal path; and
a first differential amplifier for receiving the sensing signal and the reference signal, subtracting the reference signal from the sensing signal to generate an output signal.
13. The sensing circuit of claim 12, wherein the reference signal path has a capacitance substantially equal to a capacitance of the sensing signal path at the untouched condition.
14. The sensing circuit of claim 12, wherein the reference signal path has a plurality of electrical elements, and the electrical elements are connected in a manner so as to simulate equivalent circuits of the sensing signal path.
15. The sensing circuit of claim 12, wherein the sensing signal path comprises:
a sensing unit for receiving the noise through a parasitic capacitance, the sensing unit having a first equivalent capacitance or a second equivalent capacitance, wherein the first equivalent capacitance is an equivalent capacitance of the capacitance of the capacitive touch panel at the touched condition and the parasitic capacitance, and the second equivalent capacitance is an equivalent capacitance of the capacitance of the capacitive touch panel at the untouched condition and the parasitic capacitance;
a sensing signal generating unit coupled to the sensing unit, for generating the sensing signal according to the first equivalent capacitance and the noise or according to the second equivalent capacitance and the noise,a first resistor having a first end coupled to the sensing signal generating unit and a second end coupled to an inverting input of the first differential amplifier; and
a first capacitor having a first end coupled to the inverting input of the first differential amplifier and a second end coupled to an output of the first differential amplifier, andwherein the reference signal path comprises;
a reference unit for receiving the signal, the reference unit having a third capacitance, wherein the third capacitance simulates the capacitance of the capacitive touch panel at the untouched condition and the parasitic capacitance;
a reference signal generating unit coupled to the reference unit, for outputting the reference signal according to the third equivalent capacitance and the noise;
a second resistor having a first end coupled to the reference signal generating unit and a second end coupled to a non-inverting input of the first differential amplifier; and
a second capacitor having a first end coupled to the non-inverting input of the first differential amplifier and a second end coupled to a ground,wherein the reference unit has the same circuits as the sensing unit, the reference signal generating unit has the same circuits as the sensing signal generating unit, a resistance of the second resistor is the same as a resistance of the first resistor, and a capacitance of the second capacitor is the same as a capacitance of the first capacitor.
16. The sensing circuit of claim 15, wherein the sensing signal path further comprises a first filter coupled between the sensing signal generating unit and the first end of the first resistor for filtering out high-frequency components of the sensing signal generated by the sensing signal generating unit, the reference signal path further comprises a second filter coupled between the reference signal generating unit and the first end of the second resistor for filtering out high-frequency components of the reference signal, and the second filter has the same circuits as the first filter.
17. The sensing circuit of claim 15, further comprising:
18. The sensing circuit of claim 15, wherein the reference unit comprises a capacitor, a capacitance of the capacitor is substantially equal to the parasitic capacitance, and the noise is coupled to the reference unit through the capacitor.
19. The sensing circuit of claim 12, further comprising an amplifying unit coupled to the first differential amplifier, for amplifying the output signal generated by the first differential amplifier.
20. An electronic apparatus, comprising a capacitive touch panel, the capacitive touch panel comprising the sensing circuit of claim 12, wherein the electronic apparatus is a mobile phone, a digital camera, a Personal Digital Assistant, a notebook, a desktop computer, a television, a Global Positioning System, a vehicle display, an aeronautical display, or a portable DVD player.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/095,214, filed Sep. 8, 2008.
The present invention generally relates to a sensing circuit, and more particularly to a sensing circuit for a capacitive touch panel.
Applications of conventional touch panels are widely used, for example, mobile phones, touch screens for public information, automatic teller machines (ATMs) and so on. The intuitive operations of a touch panel can be substituted for the functions of a keyboard and a mouse; therefore, the touch panel is quite convenient in use.
Please refer to FIG. 1 and FIG. 2. FIG. 1 and FIG. 2 illustrate two types of capacitive touch panels 150, 250 for detecting a touch position. In FIG. 1, the capacitive touch panel 150 comprises a plurality of sensing lines in the X-axis direction and in the Y-axis direction, that is, the sensing lines X1-X4 and Y1-Y4. Each of the sensing lines X1-X4 and Y1-Y4 has a plurality of sensing electrodes (not shown). The sensing capacitance of each sensing electrode is represented as CSENSE. When no touch event occurs, the sensing capacitance CSENSE is zero. When a touch event occurs, the sensing capacitance CSENSE is not zero. The capacitive touch panel 150 in FIG. 1 detects the touch position by sequentially scanning each of the sensing lines X1-X4 and Y1-Y4. As shown in FIG. 1, the scanning sequence is from the sensing line X1 to the sensing line X4, and then from the sensing line Y1 to the sensing line Y4. When the intersection point of the sensing line X4 and the sensing line Y1 is touched, for example, the touch position can be detected by a change of the sensing capacitance CSENSE.
In the other sensing method, sensing lines in only one direction are scanned, and a stimulating signal is inputted to sensing lines in the other direction. As shown in FIG. 2, the capacitive touch panel 250 also comprises a plurality of sensing lines in the X-axis direction and in the Y-axis direction, that is, the sensing lines X1-X4 and Y1-Y4. The scanning sequence is from the sensing line X1 to the sensing line X4, and the stimulating signal is sequentially inputted from the sensing line Y1 to the sensing line Y4. That is, the stimulating signal is inputted to the sensing line Y1, and the scanning sequence is from the sensing line X1 to X4. Then, the stimulating signal is inputted to the sensing line Y2, and the scanning sequence is from the sensing line X1 to X4. The rest processes can be done in the same manner. A sensing capacitance CTRANS represents a coupling capacitance between the sensing line X1 and the sensing line Y1. The sensing capacitance CTRANS has different values at the intersection point of the sensing line X1 and the sensing line Y1 being touched or untouched. Similar to FIG. 1, the touch position can be detected by a change of the sensing capacitance CTRANS.
Please refer to FIG. 3. FIG. 3 illustrates a block diagram of a conventional sensing circuit 100. The sensing circuit 100 comprises a sensing unit 102 (a sensing electrode), a sensing signal generating unit 104, and an integrator 106. The sensing unit 102 has the sensing capacitance CSENSE as shown in FIG. 1 or the sensing capacitance CTRANS as shown in FIG. 2 to indicate that a touch event has occurred or not. When the capacitive touch panel 150 in FIG. 1 or the capacitive touch panel 250 in FIG. 2 is touched, the sensing capacitance of the sensing unit 102 is changed. The sensing signal generating unit 104 generates a sensing signal according to the change of the sensing capacitance. The sensing signal is a voltage signal and inputted to the integrator 106 to be integrated. Finally, the integrator 106 outputs an integrated result, and the touch position can be determined by the integrated result.
However, regardless if it is the capacitive touch panel 150 in FIG. 1 or the capacitive touch panel 250 in FIG. 2, there exists a problem that a noise affects the sensing signal. As it is known from the prior arts, the sensing unit 102 is disposed on a sensing electrode substrate (not shown), and the sensing signal generating unit 104 and the integrator 106 are disposed on an array substrate of a liquid crystal display panel (not shown). A common electrode (not shown) is disposed between the sensing electrode substrate and the array substrate of the liquid crystal display panel for providing a required voltage level when the liquid crystal display panel operates. When the liquid crystal display panel operates, a common voltage provided by the common electrode is not clear. That is, the common voltage has the noise. For example, the noise is generated when a source bus of the liquid crystal display panel is driven to be pre-charged. In addition, the noise is also generated when switches of the liquid crystal display panel are turned on and off. The noise enters the sensing circuit 100 in FIG. 3, causing the sensing circuit 100 to fail to detect the touch position or resulting in detection errors.
Therefore, there is a need to solve the above-mentioned problem that the noise affects the sensing signal.
A primary objective of the present invention is to provide a sensing circuit for a capacitive touch panel. By adding a path for a noise to pass through, the noise is differentially processed through two paths which have the same electrical conditions with each other. The noise is then decreased significantly, and a sensing signal can be detected correctly therefore.
The sensing circuit for the capacitive touch panel according to the present invention comprises a sensing signal part, a reference signal part, and an integrator. The sensing signal part generates a sensing signal according to a capacitance of the capacitive touch panel and a noise which is received by the sensing signal part. The capacitance of the capacitive touch panel at a touched condition is different from the capacitance of the capacitive touch panel at an untouched condition. The reference signal part receives the noise and outputs a reference signal. The reference signal part has the same electrical conditions as the sensing signal part. The integrator receives the sensing signal and the reference signal, and it subtracts the reference signal from the sensing signal to generate an output signal.
The sensing circuit for the capacitive touch panel according to the present invention comprises a sensing signal path, a reference signal path, and a first differential amplifier. The sensing signal path generates a sensing signal according to a capacitance of the capacitive touch panel and a noise which is received by the sensing signal path. The capacitance of the capacitive touch panel at a touched condition is different from the capacitance of the capacitive touch panel at an untouched condition. The reference signal path receives the noise and outputs a reference signal. The reference signal path has the same electrical conditions as the sensing signal path. The first differential amplifier receives the sensing signal and the reference signal, and it subtracts the reference signal from the sensing signal to generate an output signal.
FIG. 1 and FIG. 2 illustrate two types of capacitive touch panels for detecting a touch position;
FIG. 3 illustrates a block diagram of a conventional sensing circuit;
FIG. 4 illustrates a functional block diagram according to a sensing circuit of the present invention;
FIG. 5 illustrates a circuit diagram according to a first embodiment shown in FIG. 4;
FIG. 6 illustrates a circuit diagram according to a second embodiment shown in FIG. 4; and
FIG. 7 illustrates a diagram of an electronic apparatus comprising a capacitive touch panel.
Please refer to FIG. 4. FIG. 4 illustrates a functional block diagram according to a sensing circuit 400 of the present invention. The sensing circuit 400 is capable of decreasing influence of a noise SNOISE generated by a common electrode 440 in a capacitive touch panel (not shown). The sensing circuit 400 basically comprises a sensing signal part 411, a reference signal part 421, and an integrator 406. The sensing signal part 411 generates a sensing signal ST according to a capacitance of the capacitive touch panel and the noise SNOISE which is received by the sensing signal part 411. The capacitance of the capacitive touch panel at a touched condition is different from the capacitance of the capacitive touch panel at an untouched condition. The reference signal part 421 receives the noise SNOISE and outputs a reference signal SNOISE′. The reference signal part 421 is simulated to have the same electrical conditions as the sensing signal part 411. The integrator 406 receives the sensing signal ST and the reference signal SNOISE′. The function of the integrator 406 is to integrate a difference between signals fed to two inputs of the integrator 406. As a result, the integrator 406 subtracts the reference signal SNOISE′ from the sensing signal ST to generate an output signal SOUT.
The reference signal part 421 has a capacitance substantially equal to a capacitance of the sensing signal part 411 at the untouched condition. The sensing signal part 411 and the reference signal part 421 have the same electrical conditions. This means that the reference signal part 421 has a plurality of electrical elements, and the electrical elements are connected to simulate equivalent circuits of the sensing signal part 411 so that both the reference signal part 421 and the sensing signal part 411 have approximately the same electrical characteristics, such as resistance, capacitance, and so on. The objective of the above-mentioned is to make the noise SNOISE pass through the same circuits so that noise values inputted to the integrator 406 are the same after the noise SNOISE passes the sensing signal part 411 and the reference signal part 421, respectively.
In order to be clearly understood, the following will describe differences between the prior arts and the present invention. Please refer to FIG. 5. FIG. 5 illustrates a circuit diagram according to a first embodiment shown in FIG. 4. This embodiment is a sensing circuit 500 utilized in a capacitive touch panel where scan lines are sequentially scanned from one direction to the other direction. A sensing signal part 511 comprises a sensing unit 512 and a sensing signal generating unit 514. A reference signal part 521 comprises a reference unit 522 and a reference signal generating unit 524.
The sensing unit 512 has a sensing capacitance which is represented as CSENSE. When the capacitive touch panel is untouched, the sensing capacitance CSENSE of the sensing unit 512 is zero. When the capacitive touch panel is touched, the sensing capacitance CSENSE is not zero. In addition, the sensing unit 512 further has a parasitic capacitance. The parasitic capacitance is an equivalent capacitance between a common electrode 540 and a sensing electrode substrate (not shown), and it is represented as CPAR1. A noise SNOISE of the common electrode 540 is coupled to the sensing unit 512 through the parasitic capacitance CPAR1.
The sensing unit 512 receives the noise SNOISE through the parasitic capacitance CPAR1. The sensing unit 512 has a first equivalent capacitance or a second equivalent capacitance. The first equivalent capacitance is an equivalent capacitance of the capacitance of the capacitive touch panel at the touched condition (i.e. the sensing capacitance CSENSE) and the parasitic capacitance CPAR1. The second equivalent capacitance is an equivalent capacitance of the capacitance of the capacitive touch panel at the untouched condition (i.e. the sensing capacitance CSENSE is zero) and the parasitic capacitance CPAR1. The sensing signal generating unit 514 is coupled to the sensing unit 512. The sensing signal generating unit 514 generates a sensing signal ST according to the first equivalent capacitance and the noise SNOISE or according to the second equivalent capacitance and the noise SNOISE.
There are two parts of signals at a node 1 in FIG. 5. One part is generated by a control signal VTOGGLE (such as a square wave), and the other part is generated by the noise SNOISE. The control signal VTOGGLE is an added signal for reacting the touched condition or the untouched condition (i.e. the sensing capacitance CSENSE). That is, the control signal VTOGGLE is utilized to transform the first equivalent capacitance or the second equivalent capacitance into a signal change so as to indicate that the capacitive touch panel is touched or untouched. The control signal VTOGGLE is coupled to the sensing signal generating unit 514 through a first coupling capacitor CC1. In another aspect, the noise SNOISE is coupled thereto through the parasitic capacitance CPAR1 so that generates an S1NOISE at the node 1. The S1NOISE is obtained by the following equation (1):
S 1  NOISE = S NOISE  ( C PAR   1 C PAR   1 + C C   1 + C SENSE ) ( 1 )
The noise SNOISE passes through the sensing signal part 511, in addition, the present invention establishes the other path for the noise SNOISE of the common electrode 540 to pass through. The reference unit 522 receives the noise SNOISE and has a third equivalent capacitance. The third capacitance simulates the capacitance of the capacitive touch panel at the untouched condition and the parasitic capacitance CPAR1. That is, the third equivalent capacitance is equal to the second equivalent capacitance of the sensing unit 512. Therefore, the reference unit 522 has a capacitor CPAR2 to simulate the parasitic capacitance CPAR1. The noise SNOISE is coupled to the reference unit 522 through the capacitor CPAR2. As mentioned above, the parasitic capacitance CPAR1 is the equivalent capacitance between the common electrode 540 and the sensing electrode substrate. The parasitic capacitance CPAR1 can be obtained by measuring. In contrast, the capacitor CPAR2 is an added capacitor which has the same capacitance as the parasitic capacitance CPAR1.
The reference signal generating unit 524 has the same circuits as the sensing signal generating unit 514, and the reference signal generating unit 524 outputs a reference signal SNOISE′ according to the third equivalent capacitance of the reference unit 522 and the noise SNOISE. The reference signal generating unit 524 has an added second coupling capacitor CC2. In addition to being coupled to the sensing signal generating unit 514 through the first coupling capacitor CC1, the control signal VTOGGLE is also coupled to the reference signal generating unit 524 through the second coupling capacitor CC2. Accordingly, the electrical conditions of the reference signal part 521 are the same as the electrical conditions of the sensing signal part 511. The noise SNOISE passes through both the reference signal part 521 and the sensing signal part 511. A capacitance of the second coupling capacitor CC2 is substantially equal to a capacitance of the first coupling capacitor CC1. Thus, an S2NOISE at a node 2 is:
S 2  NOISE = S NOISE  ( C PAR   2 C PAR   2 + C C   2 )
The capacitance of the capacitor CPAR2 is substantially equal to the parasitic capacitance CPAR1, the capacitance of second coupling capacitor CC2 is substantially equal to the capacitance of the first coupling capacitor CC1, therefore:
S 2  NOISE = S NOISE  ( C PAR   1 C PAR   1 + C C   1 )
A signal difference inputted to two inputs of the integrator 506 is:
S 1  NOISE - S 2  NOISE =  S NOISE  ( C PAR   1 C PAR   1 + C C   1 + C SENSE - C PAR   1 C PAR   1 + C C   1 ) =  S NOISE  [ - C par   1 × C sense ( C PAR   1 + C C   1 + C SENSE ) × ( C PAR   1 + C C   1 ) ] ( 2 )
Comparing the S1NOISE of the conventional sensing circuit in the equation (1) with the (S1NOISE−S2NOISE) in the equation (2) of the first embodiment of the present invention, it is obtained that the noise in the equation (2) is decreased by a multiple of
[ C SENSE ( C PAR   1 + C C   1 ) ] .
The noise SNOISE can be eliminated to increase sensitivity of the sensing circuit 500 after the integrator 506 integrates.
The sensing signal part 511 preferably comprises a first filter 518 coupled between the sensing signal generating unit 514 and the integrator 506 for filtering out high-frequency components of the sensing signal ST generated by the sensing signal generating unit 514. In order to simulate the sensing signal part 511, the reference signal part 521 preferably comprises a second filter 528 coupled between the reference signal generating unit 524 and the integrator 506. The second filter 528 has the same circuits as the first filter 518, and the second filter 528 filters out high-frequency components of the reference signal SNOISE′.
In the present embodiment, the first filter 518 comprises a third resistor R3 coupled between the sensing signal generating unit 514 and the integrator 506, and a third capacitor C3 coupled between the integrator 506 and a ground. The second filter 528 comprises a fourth resistor R4 coupled between reference signal generating unit 524 and the integrator 506, and a fourth capacitor C4 coupled between the integrator 506 and a ground. In order to make the first filter 518 and the second filter 528 have the same circuits, a resistance of the third resistor R3 is substantially equal to a resistance of the fourth resistor R4, and a capacitance of the third capacitor C3 is substantially equal to a capacitance of the fourth capacitor C4.
The integrator 506 comprises a first differential amplifier 532, a first resistor R1, and a first capacitor C1. The first differential amplifier 532 has an inverting input (−), a non-inverting input (+), and an output 4. The first resistor R1 is coupled between the sensing signal part 511 and the inverting input (−). The first capacitor C1 is coupled between the inverting input (−) and the output 4. In order to make the two paths that the noise SNOISE passes through before being inputted to the two inputs of the first differential amplifier 532 the same, the integrator 506 further comprises a ground match unit 536. The ground match unit 536 is utilized to make the circuits inputted to the non-inverting input (+) the same as the circuits inputted to the inverting circuits (−). The ground match unit 536 comprises a second resistor R2 and a second capacitor C2. A resistance of the second resistor R2 must be designed the same as a resistance of the first resistor R1, and a capacitance of the second capacitor C2 must be designed the same as a capacitance of the first capacitor C1. The second resistor R2 is coupled between the reference signal part 521 and the non-inverting input (+) of the first differential amplifier 532. The second capacitor C2 is coupled between the non-inverting input (+) of the first differential amplifier 532 and a ground.
The sensing signal part 511, the first resistor R1 of the integrator 506 and the first capacitor C1 of the integrator 506 together constitute one complete path for the sensing signal ST to pass through. The sensing signal ST is generated according to the touched condition and the noise SNOISE or according to the untouched condition and the noise SNOISE. The path can be regarded as a sensing signal path 510. The reference signal part 521, the second resistor R2 of the integrator 506 and the second capacitor C2 of the integrator 506 together constitute the other path for the noise SNOISE to pass through. The other path can be regarded as a reference signal path 520. The reference signal path 520 simulates the sensing signal path 510 so as to have the same electrical conditions as the sensing signal path 510.
The output 4 of the integrator 506 can be coupled to an amplifying unit 530 for amplifying an output signal SOUT generated by the integrator 506. The amplifying unit 530 comprises a second differential amplifier 534, a fifth resistor R5, and a sixth resistor R6. The second differential amplifier 534 comprises an inverting input (−), a non-inverting input (+), and an output 3. The non-inverting input (+) is coupled to the output 4 of the integrator 506. The fifth resistor R5 is coupled between the inverting input (−) of the second differential amplifier 534 and a ground. The sixth resistor R6 is coupled between the inverting input (−) of the second differential amplifier 534 and the output 3.
A switch SW1 of the sensing signal generating unit 514 is utilized to switch different scan lines. Each of the scan lines comprises a plurality of sensing units 512. The remaining elements including the integrator 506, the first filter 518, the reference unit 522, the reference signal generating unit 524, the ground match unit 536, the second filter 528, and the amplifying unit 530 are shared by all the scan lines.
In practical circuit arrangements, the sensing signal generating unit 514, the first filter 518, the reference signal part 521, the integrator 506, and the amplifying unit 530 are usually disposed on the array substrate of the liquid crystal display panel or disposed apart from the array substrate of the liquid crystal display panel. As mentioned above, each sensing unit 512 is a sensing electrode in the capacitive touch panel and disposed on the sensing electrode substrate.
Please refer to FIG. 6. FIG. 6 illustrates a circuit diagram according to a second embodiment shown in FIG. 4. This embodiment is a sensing circuit 600 utilized in a capacitive touch panel where scan lines in only one direction are scanned and a stimulating signal is inputted to scan lines in the other direction. A sensing signal part 611 comprises a sensing unit 612 and a sensing signal generating unit 614. A reference signal part 621 comprises a reference unit 622 and a reference signal generating unit 624.
When the capacitive touch panel is touched, the sensing unit 612 has a sensing capacitance which is represented as CTRANS. A capacitance of the capacitive touch panel at an untouched condition, that is, the capacitance that the reference unit 622 simulates the capacitance of the capacitive touch panel at the untouched condition is represented as CTRANS′. In addition, the sensing unit 612 further has parasitic capacitances. The parasitic capacitances are equivalent capacitances between a common electrode 640 and a sensing electrode substrate (not shown), and represented as CPAR3 and CPAR5. A noise SNOISE of the common electrode 640 is coupled to the sensing unit 612 through the parasitic capacitance CPAR3.
The sensing unit 612 receives the noise SNOISE through the parasitic capacitance CPAR3. The sensing unit 612 has a first equivalent capacitance or a second equivalent capacitance. The first equivalent capacitance is an equivalent capacitance of the capacitance of the capacitive touch panel at a touched condition (i.e. the sensing capacitance CTRANS), the parasitic capacitance CPAR3, and the parasitic capacitance CPAR5. The second equivalent capacitance is an equivalent capacitance of the capacitance of the capacitive touch panel at the untouched condition (i.e. the capacitance CTRANS′), the parasitic capacitance CPAR3, and the parasitic capacitance CPAR5. The sensing signal generating unit 614 is coupled to the sensing unit 612. The sensing signal generating unit 614 generates a sensing signal ST according to the first equivalent capacitance and the noise SNOISE or according to the second equivalent capacitance and the noise SNOISE.
There are two parts of signals at a node 5 in FIG. 6. One part is generated by a control signal VTOGGLE (such as a square wave), and the other part is generated by the noise SNOISE. The control signal VTOGGLE is an added signal for reacting the touched condition or the untouched condition (i.e. the sensing capacitance CTRANS). That is, the control signal VTOGGLE is utilized to transform the first equivalent capacitance or the second equivalent capacitance into a signal change so as to indicate that the capacitive touch panel is touched or untouched. The control signal VTOGGLE is directly inputted to the sensing unit 612 and the sensing signal generating unit 614. In another aspect, the noise SNOISE is coupled thereto through the parasitic capacitance CPAR3 so that generates an S5NOISE at the node 5. The S5NOISE is obtained by the following equation (3):
S 5  NOISE = S NOISE  ( C PAR   3 C PAR   3 + C TRANS ) ( 3 )
The noise SNOISE passes through the sensing signal part 611, in addition, the present invention establishes the other path for the noise SNOISE of the common electrode 640 to pass through. The reference signal 622 receives the noise SNOISE and has a third equivalent capacitance. The third capacitance simulates the capacitance of the capacitive touch panel at the untouched condition (CTRANS′), the parasitic capacitance Cpar3, and the parasitic capacitance CPAR5. That is, the third equivalent capacitance is equal to the second equivalent capacitance of the sensing unit 612. Therefore, the reference unit 622 has capacitors CPAR4, CPAR6 to simulate the parasitic capacitances CPAR3, CPAR5, respectively. The noise SNOISE is coupled to the reference unit 622 through the capacitor CPAR4. As the first embodiment shown in FIG. 5, the capacitors CPAR4, CPAR6 are added capacitors which have the same capacitances as the parasitic capacitances CPAR3, CPAR5, respectively.
The reference signal generating unit 624 has the same circuits as the sensing signal generating unit 614, and the reference signal generating unit 624 outputs a reference signal SNOISE′ according to the third equivalent capacitance of the reference unit 622 and the noise SNOISE. In addition to being inputted to the sensing unit 612 and the sensing signal generating unit 614 directly, the control signal VTOGGLE is also inputted to the reference unit 622 and the reference signal generating unit 624. Accordingly, the electrical conditions of the reference signal part 621 are the same as the electrical conditions of the sensing signal part 611. The noise SNOISE passes through both the reference signal part 621 and the sensing signal part 611. Thus, an S6NOISE at a node 6 is:
S 6  NOISE = S NOISE  ( C PAR   4 C PAR   4 + C TRANS ′ )
The capacitance of the capacitor CPAR4 is substantially equal to the capacitance of the parasitic capacitance CPAR3, therefore:
S 6  NOISE = S NOISE  ( C PAR   3 C PAR   3 + C TRANS ′ )
A signal difference inputted to two inputs of the integrator 606 is:
S 5  NOISE - S 6  NOISE =  S NOISE  ( C PAR   3 C PAR   3 + C TRANS - C PAR   3 C PAR   3 + C TRANS ′ ) =  S NOISE  [ C PAR   3 × C TRANS ′ - C PAR   3 × C TRANS ( C PAR   3 + C TRANS ) × ( C PAR   3 + C TRANS ′ ) ] ( 4 )
Comparing the S5NOISE of the conventional sensing circuit in the equation (3) with the (S5NOISE-S6NOISE) in the equation (4) of the second embodiment of the present invention, it is obtained that the noise is decreased by a multiple of
[ C TRANS ′ - C TRANS ( C PAR   3 + C TRANS ′ ) ] .
The noise SNOISE can be eliminated to increase sensitivity of the sensing circuit 600 after the integrator 606 integrates.
In the practical circuits, a first filter 618, a second filter 628, the integrator 606, a ground match unit 636, and an amplifying unit 630 are the same as the first embodiment shown in FIG. 5, and are not repeated herein.
As the first embodiment shown in FIG. 5, the sensing signal part 611, a seventh resistor R7 of the integrator 606 and a seventh capacitor C7 of the integrator 606 together constitute one complete path for the sensing signal ST to pass through. The sensing signal ST is generated according to the touched condition and the noise SNOISE or according to the untouched condition and the noise SNOISE. The path can be regarded as a sensing signal path 610. The reference signal part 621, the eighth resistor R8 of the integrator 606 and the eighth capacitor C8 of the integrator 606 together constitute the other path for the noise SNOISE to pass through. The other path can be regarded as a reference signal path 620. The reference signal path 620 simulates the sensing signal path 610 so as to have the same electrical conditions as the sensing signal path 610.
By adding the reference signal path for the noise to pass through in the present invention, the noise is inputted to the two inputs of the differential amplifier through the sensing signal path and the reference signal path which have the same electrical conditions. After the differential amplifier subtracts the noise which passes through the two paths, the noise component in the sensing signal can be decreased significantly. As a result, the output of the differential amplifier only remains the sensing signal which is generated by the sensing signal generating unit, and the sensing signal can be detected correctly so that sensitivity and accuracy of the sensing circuits are increased.
Please refer to FIG. 7. FIG. 7 illustrates a diagram of an electronic apparatus 700 comprising a capacitive touch panel 750. The capacitive touch panel 750 comprises one of the sensing circuits 400, 500, and 600. The capacitive touch panel 750 comprising one of the sensing circuits 400, 500, and 600 can be a part of the electronic apparatus 700. The electronic apparatus 700 comprises the capacitive touch panel 750 and a power supply 740. The power supply 740 is coupled to the capacitive touch panel 750 for providing power for the capacitive touch panel 750. The electronic apparatus is a mobile phone, a digital camera, a Personal Digital Assistant, a notebook, a desktop computer, a television, a Global Positioning System, a vehicle display, an aeronautical display, or a portable digital video disc (DVD) player.
US 8,305,360 B2