KR101589762B1 - Touch position detection apparatus and method of detecting touch position - Google Patents

Abstract

A contact position detecting apparatus according to an embodiment of the present invention includes: a contact detecting unit for contacting an object; A first process of estimating a contact position of the object with respect to the entire contact-position detectable region of the contact detection unit, a second process of detecting a contact position of the object in a limited area including the contact position estimated by the first process, 2 processing; .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a contact position detecting apparatus and a contact position detecting method,

The present invention relates to a contact position detecting device and a contact position detecting method.

A contact position detecting device and a contact position detecting method are applied variously to a display device, a portable device, and the like. For example, such a contact position detecting device or a contact position detecting method can be advantageously applied to a contact input device such as a touch screen or a touch pad.

The present invention provides a contact position detecting device and a contact position detecting method capable of detecting a contact position quickly and accurately.

A contact position detecting apparatus according to an embodiment of the present invention includes: a contact detecting unit for contacting an object; A first process of estimating a contact position of the object with respect to the entire contact-position detectable region of the contact detection unit, a second process of detecting a contact position of the object in a limited area including the contact position estimated by the first process, 2 processing; .

The contact position detecting device according to the embodiment includes a contact detecting unit including at least one first array electrode arranged in a first direction and at least one second array electrode arranged in a second direction, the object being in contact with the object; A first processing unit for performing a first process for detecting a contact position of the object from signals received from the first array electrode and the second array electrode; and a second processing unit for inputting a signal to the first array electrode, And a second processing unit for performing a second process of receiving a signal output from the second array electrode corresponding to a signal input to the first array electrode and detecting a contact position of the object, A control unit that selectively performs the control; .

A contact position detecting method according to an embodiment of the present invention includes: performing a first process of estimating a contact position of an object with respect to an entire contact position detectable region of a contact detecting unit to which an object contacts; Performing a second process of detecting a contact position of the object in a limited area including a contact position estimated by the first process; .

The contact position detecting method according to the embodiment includes at least one first array electrode arranged in a first direction and at least one second array electrode arranged in a second direction, A first process of detecting a contact position of the object from a signal received from the first array electrode and the second array electrode, a second process of inputting a signal to the first array electrode, And a second process for detecting a contact position of the object by receiving a signal output from the second array electrode in response to the first process and selectively performing the first process and the second process.

According to the contact position detecting device and the contact position detecting method according to the embodiment, there is an advantage that the contact position can be detected quickly and accurately.

Further, according to the contact position detecting device and the contact position detecting method according to the embodiment, current consumption can be reduced.

1 is a block diagram showing a contact position detecting apparatus according to an embodiment of the present invention.
2 is a block diagram showing a first processing section of the contact position detecting apparatus shown in Fig.
3 is a block diagram showing a second processing unit of the contact position detecting device shown in Fig.
4 is a block diagram showing another example of the contact position detecting device according to the embodiment of the present invention.
Figs. 5 and 6 are views for explaining the contact position detection in the contact position detecting device shown in Fig. 4. Fig.
7 is a view for explaining a plurality of contact position detection in the contact position detecting device according to the embodiment of the present invention.
8 is a block diagram showing another example of the contact position detecting device according to the embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a block diagram showing a contact position detecting device according to an embodiment of the present invention, FIG. 2 is a block diagram showing a first processing section of the contact position detecting device shown in FIG. 1, Fig. 7 is a block diagram showing a second processing unit of the contact position detecting device. Fig.

The contact position detecting apparatus according to an embodiment of the present invention may include a contact detecting unit 100 and a controller 200. [ An object may contact the contact sensing unit 100. The touch sensing unit 100 may include a first array electrode 110 and a second array electrode 120. The control unit 200 may include a first processing unit 210 and a second processing unit 220.

The first array electrode 110 may include at least one electrode arranged in a first direction with respect to the entire contact-detectable region of the contact detection unit 100. The second array electrode 120 may include at least one electrode arranged in a second direction with respect to the entire contact-detectable region of the contact detection unit 100. Here, the second direction indicates a direction different from the first direction. The first direction and the second direction may be embodied as an example perpendicular to each other, and the first direction and the second direction may be arbitrary angles not perpendicular to each other

The control unit 200 performs a first process of estimating a contact position of an object with respect to the entire contact-position detectable region of the contact detection unit 100, a first process of estimating a contacted position of the object, And a second process of detecting the contact position of the object in the second process.

For example, the controller 200 may determine a contact position of an object in contact with the touch sensing unit 100 from a signal received from the first array electrode 110 and the second array electrode 120, And a first processing unit 210 that performs processing. The controller 200 receives a signal from the first array electrode 110 and a signal from the second array electrode 120 in response to a signal input to the first array electrode 110, And a second processing unit 220 for performing a second process of detecting a contact position of an object contacted to the contact sensing unit 100.

The first processing unit 210 includes a first arraying unit 211 for receiving a signal from the first arraying electrode 110 and a second arraying unit 212 for receiving a signal from the second arraying electrode 120 And a second array processor 212 for scanning the capacitance change of the touch sensor 100 and detecting an object touching the touch sensor 100. [ And a first contact position detection unit 213 for estimating a contact position of the first contact position.

The second processing unit 220 includes a first arraying unit 221 for inputting a signal to the first arraying electrode 110 and a second arraying unit 221 for receiving signals inputted to the first arraying electrode 110, A second array processor 222 for receiving a signal output from the electrode 120 and a second array processor 222 for generating a signal having a predetermined frequency to provide an input signal to the first array processor 221, And a second contact position detection unit 223 for detecting a change in the output signal of the second array electrode 120 from the signal received at the contact detection unit 100 and detecting the contact position of the object contacted to the contact detection unit 100 have.

Here, the first arrangement processing unit 211 included in the first processing unit 210 and the second arrangement processing unit 221 included in the second processing unit 220 may be implemented as one component. The second arrangement processor 212 included in the first processor 210 and the second arrangement processor 222 included in the second processor 220 may be implemented as one component.

The contact position detecting device according to the embodiment of the present invention performs a first process of detecting a contact position of an object contacted to the contact sensing unit 100 through the first process unit 210, And to perform a second process of detecting the contact position of the object in the limited area including the estimated contact position.

Further, the contact position detecting device according to the embodiment may be configured to selectively perform the first process and the second process, instead of sequentially performing the first process and the second process. That is, it is possible to detect the contact position of the object contacted to the contact sensing unit 100 only through the second process without the first process. Further, it is also possible to detect the contact position of the object contacted to the contact sensing unit 100 through only the first process without the second process.

The contact position detecting device according to the embodiment of the present invention can detect the contact position of the object contacted to the contact detecting part 100 through only the first process when the contact position of the object contacting the contact detecting part 100 is one. The contact position can be accurately detected. Therefore, the second processing may be performed only when the contact position detected through the first processing is two or more, so that the plurality of contact positions can be accurately and quickly detected. A plurality of contact position detection methods will be described later in more detail.

4 is a block diagram showing another example of the contact position detecting device according to the embodiment of the present invention.

4, the contact position detecting apparatus according to the embodiment of the present invention includes a contact detecting unit 400 having a plurality of thermal sensing electrodes 401 and a plurality of row sensing electrodes 402 . A heat processing unit 403 may be connected to the plurality of thermal sensing electrodes 401 and a row processing unit 404 may be connected to the plurality of row sensing electrodes 402. The contact position detecting apparatus according to the embodiment may include a first capacitance measurement unit 420, a second capacitance measurement unit 430, a control circuit unit 408, and a central processing unit 409. The second capacitance measuring unit 430 may include a signal generating unit 406 and a signal receiving unit 407. Reference numeral 411 denotes a communication bus.

The contact position detection in the contact position detecting device according to the embodiment will be described with reference to Figs. 5 and 6. Fig.

First, as shown in FIG. 5, the contact position detecting apparatus according to the embodiment can detect the contact position of an object contacting the contact detecting unit 400 using the first capacitance measuring unit 420.

The first capacitance measurement unit 420 may include a switch unit 505, a charge amount sensing unit 506, and a signal generation unit 507. The first capacitance measurement unit 420 may detect the contact position of an object contacted to the contact sensing unit 400 under the control of the central processing unit 409 and the control circuit unit 408. [ The switch unit 505 can select the connection between the heat processing unit 403 and the row processing unit 404. The thermal processing unit 403 receives a signal from the plurality of thermal sensing electrodes 401 and the row processing unit 404 can receive signals from the plurality of row sensing electrodes 402. Reference numeral 501 denotes a thermo-sensing electrode whose capacitance is changed by contact of an object, and reference numeral 502 denotes parasitic capacitance formed on the thermo-sensing electrode. In addition, reference numeral 503 denotes a row sensing electrode whose capacitance is changed by the contact of an object, and 504 denotes a parasitic capacitance formed on the row sensing electrode.

The signals received in the heat processing unit 403 and the row processing unit 404 are transmitted to the charge amount sensing unit 506 through the switch unit 505. [ The charge amount sensing unit 506 uses the signal provided from the signal generating unit 507 to calculate the amount of charge change in each of the column sensing electrodes 401 and the row sensing electrodes 402 of the contact sensing unit 400 Can be detected. That is, the charge amount sensing unit 506 can detect a capacitance change in each of the thermal sensing electrodes 401 and the row sensing electrodes 402. The contact position of the object contacting the contact sensing unit 400 can be detected.

According to the embodiment, it is also possible to implement the case where the switch unit 505 is not applied. In this case, the shared path of the capacitance measurement circuit which does not operate so as to prevent the error caused by the interference of the hetero- Impedance can be maintained.

6, the contact position detecting apparatus according to the embodiment can detect the contact position of an object contacting the contact detecting unit 400 by using the second capacitance measuring unit 430 .

The second capacitance measurement unit 430 may detect the contact position of an object contacting the contact sensing unit 400 under the control of the central processing unit 409 and the control circuit unit 408. [ The second capacitance measuring unit 430 may include a signal generating unit 406 and a signal receiving unit 407. The signal generator 406 may include a filter 603 and a first signal generator 604. The signal receiving unit 407 may include an amplifier 605, a first filter 606, a mixer 607, a second filter 608, and an ADC 609.

The arbitrary signal generated in the first signal generator 604 may be transmitted to the row processor 404. The arbitrary signal generated by the first signal generator 604 may be a signal of a predetermined frequency band. At this time, a signal from which the outer band of the generated signal is removed by the filter 603 can be input to the row processor 404, thereby removing noise. The signals input to the row processing unit 404 may be input to the plurality of row sensing electrodes 402. Reference numeral 601 denotes a mutual capacitance in which the capacitance is changed by contact of an object, and 602 denotes a parasitic capacitance formed in both terminals of the mutual capacitance 601.

An arbitrary signal generated in the signal generator 406 is input to the plurality of row sensing electrodes 402 through the row processor 404. In addition, signals are received from the plurality of thermal sensing electrodes 401 corresponding to the signals input to the plurality of row sensing electrodes 402. The signals received from the plurality of thermal sensing electrodes 401 may be transmitted to the signal receiving unit 407 through the thermal processing unit 403. [ The amplification unit 605 amplifies the signal received from the thermal processing unit 403. The signal transmitted from the heat processing unit 403 is a signal transmitted according to the change of the mutual capacitance 601. The value of the mutual capacitance 601 may be changed depending on whether the object is in contact with the mutual capacitance 601 or not.

The first filter 606 can remove an out-of-band frequency signal of the signal amplified by the amplifier 605, thereby removing noise. The mixer 607 is for frequency modulation of the input signal and the second filter 608 may be implemented as an anti-aliasing filter for analog-to-digital conversion. The second signal generator 610 is an arbitrary signal generator for performing an intended frequency conversion and detects a change in the mutual capacitance 601 from a signal received from the plurality of thermal sensing electrodes 401 . Accordingly, it is possible to detect the contact position of the object in contact with the contact sensing unit 400.

The contact position detecting device according to the embodiment of the present invention may be configured such that when the contact position of the object touching the contact detecting part 400 is one, It is possible to accurately detect the contact position of the object contacting the portion 400. Therefore, only when the contact position detected by the first capacitance measurement unit 420 is two or more, the second capacitance measurement unit 430 performs the contact position detection, And can be quickly detected. A plurality of contact position detection methods will be described with reference to Fig. 7 is a view for explaining a plurality of contact position detection in the contact position detecting device according to the embodiment of the present invention.

For example, as shown in FIG. 7, assume that the touch sensing unit 400 has an object touch at two points T1 (R2, C2) and T2 (R3, C3). According to the contact position detecting method according to the embodiment, first, the contact position can be detected through the first capacitance measurement unit 420. At this time, contact of the object to R2 and R3 can be detected from a change in capacitance detected at the plurality of row sensing electrodes R1, R2, R3, R4, and R5. In addition, contact of an object with C2 and C3 can be detected from a change in capacitance detected by the plurality of thermal sensing electrodes C1, C2, C3, C4, and C5. From this, two contact positions of T1 (R2, C2) and T2 (R3, C3) can be detected. However, an error may occur in which (R2, C3) or (R3, C2) is detected as a contact position from the change detection of the capacitance.

Therefore, according to the embodiment, it is possible to additionally perform contact position detection using the second capacitance measurement unit 430 in order to prevent such an error from occurring. However, when performing the contact position detection using the second capacitance measurement unit 430, contact position detection is performed on a limited area without performing detection on the entire area of the contact detection unit 400 . That is, since a change in electrostatic capacitance has already been detected in R2, R3, C2, and C3 via the first capacitance measurement unit 430, a signal is input only to C2 and C3, The actual contact position can be accurately and quickly detected.

According to the embodiment of the present invention, an advantage of the capacitance measurement method is that it is possible to determine whether or not the contact is at a high speed by performing line scanning instead of coordinate scanning with respect to the contact point while maintaining high resistance to external impact. Also, by performing coordinate scanning by applying an input signal and an output signal only to a local region with respect to a predicted contact position, it is possible to realize a contact position detecting apparatus and a contact position detecting method having agile reaction speeds.

According to the embodiment of the present invention, the movement of the contact coordinates is repeated by repeating the contact position measurement process in the first capacitance measurement unit 420 and the contact position measurement process in the second capacitance measurement unit 430 You can trace. Through this measurement process, the gesture of the contact point can be analyzed quickly and accurately. At this time, as described above, according to the embodiment of the present invention, a plurality of contact coordinates can be purified and quickly detected.

According to the embodiment of the present invention, when the contact input does not occur for a predetermined time, only contact position detection using the first capacitance measurement unit 420 among the contact detection methods can be performed. By controlling in this way, power consumption can be reduced. If contact input does not occur for a predetermined period of time during the contact position detection using only the first capacitance measurement unit 420, contact position detection is performed only for one of the heat processing unit and the row processing unit Can be controlled. According to the embodiment, the power consumption can be further reduced.

8 is a block diagram showing another example of the contact position detecting device according to the embodiment of the present invention.

The contact position detecting apparatus according to the embodiment may further include a switching unit 801 as shown in Fig. The switching unit 801 may select the first capacitance measurement unit 420 or the second capacitance measurement unit 430 to be connected to the thermal processing unit 403 and the row processing unit 404.

In the above embodiment, the touch sensing unit 400 includes the thermal sensing electrode 401 and the row sensing electrode 402. However, according to the modified embodiment, the thermal processing unit 403 and the row processing unit 404 may be implemented to be included in the contact sensing unit 400.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood that various modifications and applications are possible. For example, each component specifically shown in the embodiments can be modified and implemented. It is to be understood that all changes and modifications that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

100 ... Contact sensing unit 110 ... First array electrode
120 ... second array electrode 200 ... control unit
210 ... First processing unit 211 ... First arrangement processing unit
212 ... second arrangement processing section 213 ... first contact position detection section
220 ... second processing section 221 ... first arrangement processing section
222 ... second arrangement processing section 223 ... second contact position detection section
400 ... Contact sensing part 401 ... Thermal sensing electrode
402 ... row sensing electrode 403 ... heat processing unit
404 ... a row processor 406 ... a signal generator
407 ... signal receiving section 408 ... control circuit section
409 ... Central processing unit 411 ... Communication bus
420 ... first capacitance measuring unit 430 ... second capacitance measuring unit

Claims (17)

A contact detecting unit for contacting an object;
A first process of estimating a contact position of the object with respect to the entire contact-position detectable region of the contact detection unit, a second process of detecting a contact position of the object in a limited area including the contact position estimated by the first process, 2 processing;
And the contact position detecting device. 2. The apparatus according to claim 1,
At least one first array electrode arranged in a first direction with respect to the entire contact-position detectable region;
At least one second array electrode arranged in a second direction with respect to the entire contact-position detectable region;
And the contact position detecting device. 3. The apparatus of claim 2,
A first processing unit for performing a first process of estimating a contact position of the object from signals received from the first array electrode and the second array electrode;
A second process for inputting a signal to the first array electrode and receiving a signal outputted from the second array electrode in correspondence with the signal inputted to the first array electrode to detect a contact position of the object; 2 processor;
And the contact position detecting device. The image processing apparatus according to claim 3,
A first arrangement processor for receiving signals from the first array electrodes;
A second arrangement processor for receiving signals from the second array electrodes;
A first contact position detecting unit that scans a capacitance change of the touch sensing unit from the signals received by the first arrangement processing unit and the second arrangement processing unit and estimates a contact position of the object;
And the contact position detecting device. The image processing apparatus according to claim 3,
A first arrangement processor for inputting a signal to the first array electrode;
A second arrangement processor for receiving signals output from the second array electrodes corresponding to signals input to the first array electrodes;
Wherein the first array processing unit generates a signal having a predetermined frequency to provide an input signal to the first array processing unit and detects a change in the output signal of the second array electrode from the signal received by the second array processing unit, A second contact position detecting unit;
And the contact position detecting device. A touch sensing unit including at least one first array electrode arranged in a first direction and at least one second array electrode arranged in a second direction, the object being in contact with the object;
A first processing unit for performing a first process for detecting a contact position of the object from signals received from the first array electrode and the second array electrode; and a second processing unit for inputting a signal to the first array electrode, And a second processing unit for performing a second process of receiving a signal output from the second array electrode corresponding to a signal input to the first array electrode and detecting a contact position of the object, A control unit that selectively performs the control;
And the contact position detecting device. The apparatus according to claim 6, wherein the first processing unit estimates a contact position of the object with respect to the entire contact-position detectable region of the contact detection unit, and the second processing unit includes a contact position estimated by the first processing unit And detects the contact position of the object in a limited area. The image processing apparatus according to claim 6,
A first arrangement processor for receiving signals from the first array electrodes;
A second arrangement processor for receiving signals from the second array electrodes;
A first contact position detecting unit that scans a capacitance change of the touch sensing unit from the signals received by the first arrangement processing unit and the second arrangement processing unit and estimates a contact position of the object;
And the contact position detecting device. 7. The image processing apparatus according to claim 6,
A first arrangement processor for inputting a signal to the first array electrode;
A second arrangement processor for receiving signals output from the second array electrodes corresponding to signals input to the first array electrodes;
Wherein the first array processing unit generates a signal having a predetermined frequency to provide an input signal to the first array processing unit and detects a change in the output signal of the second array electrode from the signal received by the second array processing unit, A second contact position detecting unit;
And the contact position detecting device. Performing a first process of estimating a contact position of an object with respect to an entire contact-position-detectable region of a contact-sensing unit that is in contact with an object;
Performing a second process of detecting a contact position of the object in a limited area including a contact position estimated by the first process;
And detecting the contact position. 11. The method of claim 10,
The contact detection unit may include at least one first array electrode arranged in a first direction with respect to the entire contact-position detectable region; And at least one second array electrode arranged in a second direction with respect to the entire contact-position detectable region,
The step of performing the first processing may include estimating a contact position of the object from signals received from the first array electrode and the second array electrode,
Wherein the step of performing the second processing includes the steps of inputting a signal to the first array electrode, receiving a signal output from the second array electrode in correspondence with a signal input to the first array electrode, Is detected. 12. The method according to claim 11, wherein in the performing the first process, a capacitance change of the touch sensing unit is scanned from a signal received from the first array electrode and the second array electrode, and a contact position of the object is estimated Contact position detection method. The method according to claim 11, wherein in the performing the second process, a signal having a predetermined frequency is generated to provide an input signal to the first array electrode, and a change in an output signal And detects a contact position of the object. A touch sensing device comprising at least one first array electrode arranged in a first direction and at least one second array electrode arranged in a second direction,
A first process of detecting a contact position of the object from signals received from the first array electrode and the second array electrode,
And a second process of inputting a signal to the first array electrode and receiving a signal output from the second array electrode corresponding to a signal input to the first array electrode to detect a contact position of the object,
And selectively performs the first process and the second process. 15. The method according to claim 14, wherein the first process estimates the contact position of the object with respect to the entire contact-position detectable region of the contact detection unit, and the second process includes the contact position estimated by the first process And detecting a contact position of the object in a limited area. 15. The method of claim 14, wherein, in performing the first process, a capacitance change of the touch sensing unit is scanned from a signal received from the first array electrode and the second array electrode, and a contact position of the object is estimated Contact position detection method. 15. The method of claim 14, wherein in the performing the second process, a signal having a predetermined frequency is generated to provide an input signal to the first array electrode, and a change in an output signal from a signal output from the second array electrode And detects a contact position of the object.

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