TWM526119U - Touch detection apparatus having fingerprint recognition function - Google Patents

Abstract

Touching detection apparatus having fingerprint recognition function comprises a sensing electrode, a mode selection circuit, a touch detection circuit and a fingerprint recognition circuit. The mode selection circuit couples with the sensing electrode. The touch detection circuit and the fingerprint recognition circuit couple with the mode selection circuit. The mode selection circuit selects the touch detection circuit or the fingerprint recognition circuit to couple with the sensing electrode. When the mode selection circuit selects the fingerprint recognition circuit to couple with the sensing electrode, the sensing electrode uses a first resolution to collect the user's fingerprint image data. When the mode selection circuit selects the touch detection circuit to couple with the sensing electrode, the sensing electrode uses a second resolution to detect the touch position. The first resolution is larger than the second resolution.

Description

Touch detection device with fingerprint recognition function

The present invention relates to a touch detection device, and more particularly to a touch detection device with a fingerprint recognition function.

If the mobile device requires an authenticated user, it is common practice to set a specific password. The user must enter the correct password and the electronic device can be used after successful authentication. In recent years, more and more electronic devices have been identified by fingerprint recognition devices. Because the fingerprint has a relatively high degree of singularity, that is, only the fingerprint recognition device needs to record the user's fingerprint, the user does not need to remember the specific password, thereby avoiding the risk of the password being stolen or cracked.

The most common fingerprint identification device is independently installed on the mobile device, for example, on the fixed side of the notebook computer keyboard, or on a fixed position on the back side or the bottom side of the mobile phone. Since the touch detection devices of the mobile device and the touch screen are independent of each other, they must be separately disposed outside the screen of the mobile device, occupying an extra volume of the mobile device, so that the total volume of the mobile device cannot be effectively reduced, and the mobile device is currently light. Thin, short, and small design concepts do not match.

Therefore, the present invention provides a touch detection device with a fingerprint recognition function, which solves the defects that the fingerprint recognition device and the touch detection device must be separately disposed on the mobile device in the prior art, so that the volume of the mobile device cannot be effectively reduced.

One of the technical aspects of the present invention is to provide a touch detection device with a fingerprint recognition function having a sensing electrode, a mode selection circuit, a touch detection circuit and a fingerprint recognition circuit. The mode selection circuit is coupled to the sensing electrode. The touch detection circuit and the fingerprint identification circuit are coupled to the mode selection circuit. The mode selection circuit can be coupled to the touch detection circuit or the fingerprint identification circuit and the sensing electrode. When the mode selection circuit selects the fingerprint identification circuit to be coupled to the sensing electrode, the sensing electrode captures a user fingerprint data at the first resolution. When the mode selection circuit selects the touch detection circuit to be coupled to the sensing electrode, the sensing electrode captures the touch data at the second resolution to perform the touch position detection, wherein the first resolution is greater than the second resolution.

In one embodiment, the sensing electrode further includes a plurality of first axial sensing electrodes arranged along a first axial direction, a plurality of second axial sensing electrodes arranged along a second axial direction and an insulating layer Provided between the first axial sensing electrode strips and the second axial sensing electrodes. Wherein the strips of the first axial sensing electrodes and the strips of the second axial sensing electrodes are insulated from each other and arranged in a cross.

In an embodiment, the electrode width of each of the first axial sensing electrodes and each of the second axial sensing electrodes is 50 μm, and any two adjacent first axes The distance between the sensing electrodes and any two adjacent second axial sensing electrodes was 20 μm.

In an embodiment, the fingerprint identification circuit drives the first axial sensing electrodes and the second axial sensing electrodes according to a mutual capacitance principle to capture the user fingerprint data.

In one embodiment, the fingerprint identification circuit drives the first axial sensing electrodes and the second axial sensing electrodes according to a self-capacitance principle to capture the user fingerprint data. The strips of the first axial sensing electrodes or the strips of the second axial sensing electrodes that are remote from the fingerprint of the user are grounded.

In an embodiment, the mode selection circuit further includes a rudder first switching element respectively disposed between any two adjacent first axial sensing electrodes and between any two adjacent second axial sensing electrodes. When the first switching element between the adjacent first axial sensing electrodes or any two adjacent second axial sensing electrodes is turned on, the two adjacent first axial sensing electrodes or any two adjacent second The axial sensing electrodes form a parallel structure.

In an embodiment, the mode selection circuit further groups the first axial sensing electrodes and the second axial sensing electrodes according to the second resolution, and the first switching component in each group is Turning on, such that the first axial sensing electrodes in each group and the second axial sensing electrodes in each group form a parallel structure to simultaneously receive a driving of the touch detecting circuit signal.

In an embodiment, the mode selection circuit further includes a plurality of second switching elements respectively disposed on the first axial sensing electrodes and the touch detection a circuit, and the second axial sensing electrode and the touch detecting circuit, wherein when the mode selecting circuit selects the fingerprint identifying circuit to be coupled to the sensing electrode, the second switching elements are disconnected, And when the mode selection circuit selects the touch detection circuit to be coupled to the sensing electrode, the second switching elements are turned on.

In an embodiment, the mode selection circuit further includes a plurality of third switching elements respectively disposed on the first axial sensing electrodes and the fingerprint identification circuit, and the second axial sensing electrodes and the fingerprint Identifying between the circuits, wherein when the mode selection circuit selects the fingerprint identification circuit to be coupled to the sensing electrode, the third switching elements are turned on, and when the mode selection circuit selects the touch detection circuit to couple the sense When the electrodes are measured, the third switching elements are turned off.

In summary, the technical solution of the present invention has obvious advantages and beneficial effects compared with the prior art. Since the present invention directly uses the sensing electrode for touch detection as the fingerprint recognition electrode, it is not necessary to additionally provide a fingerprint recognition electrode on the mobile device, thereby maximizing the displayable area of the mobile device. Furthermore, since it is not necessary to additionally manufacture the fingerprint recognition electrode, it is not necessary to change the fabrication process of the original electrode, which is quite convenient and cost-effective in the process.

The above description will be described in detail in the following embodiments, and further explanation of the technical solutions of the present invention will be provided.

100‧‧‧Touch detection device

110‧‧‧Sensing electrode

111‧‧‧First axial sensing electrode

112‧‧‧Second axial sensing electrode

113‧‧‧First axial drive line

114‧‧‧Second axial drive line

120‧‧‧ mode selection circuit

121‧‧‧First switching element

122‧‧‧Second switching element

123‧‧‧3rd switching element

130‧‧‧Touch detection circuit

140‧‧‧Fingerprint identification circuit

For the above and other purposes, features, advantages and implementation of this creation The examples can be more clearly understood, and the description of the drawings is as follows: FIG. 1 is a schematic diagram of a touch detection device with a fingerprint recognition function according to an embodiment of the present invention.

2 is an enlarged view of a first axial sensing electrode and a second axial sensing electrode in accordance with a preferred embodiment of the present invention.

Figure 3 is a schematic illustration of a mode selection circuit in accordance with a preferred embodiment of the present invention.

In order to make the description of the present invention more detailed and complete, reference is made to the accompanying drawings and the various embodiments described below. However, the examples provided are not intended to limit the scope of the present invention, and the description of the structure operation is not intended to limit the order in which they are performed. Any device that is recombined by components will produce equal devices. The scope covered by the creation.

The drawings are for illustrative purposes only and are not drawn to the original dimensions. On the other hand, well-known components and steps are not described in the embodiments to avoid unnecessarily limiting the present invention.

The touch detection device with the fingerprint recognition function directly uses the sensing electrode for touch detection as the fingerprint recognition electrode. Therefore, it is not necessary to additionally provide a fingerprint recognition electrode on the mobile device, which can effectively reduce the total volume of the mobile device. . Moreover, since the non-display area for fingerprint recognition is not required to be provided on the mobile device, the displayable area of the mobile device can be maximized. Furthermore, because the sensing electrode for touch detection is directly used as a finger The pattern recognition electrode does not require additional fingerprint identification electrodes, so there is no need to change the original electrode fabrication process, which is quite convenient in the process and saves time and process costs.

FIG. 1 is a schematic diagram of a touch detection device with a fingerprint recognition function according to an embodiment of the present invention. The touch detection device 100 includes a sensing electrode 110, a mode selection circuit 120, a touch detection circuit 130, and a fingerprint recognition circuit 140. The touch detection circuit 130 and the fingerprint identification circuit 140 are coupled to the mode selection circuit 120. The mode selection circuit 120 selects the touch detection circuit 130 or the fingerprint recognition circuit 140 to be coupled to the sensing electrode 110 according to a control signal. When the mode selection circuit 120 selects the touch detection circuit 130 and the sensing electrode 110 to be coupled, the user touch signal captured by the sensing electrode 110 is transmitted to the touch detection circuit 130 through the mode selection circuit 120 for the touch position. Detection. When the mode selection circuit 120 selects the fingerprint identification circuit 140 to be coupled to the sensing electrode 110, the user fingerprint image data captured by the sensing electrode 110 is transmitted to the fingerprint identification circuit 140 through the mode selection circuit 120 for comparison.

The sensing electrode 110 further includes a plurality of first axial sensing electrodes 111 arranged along a lateral direction (for example, an X-axis direction), and a plurality of second axial axes arranged along a longitudinal direction (for example, a Y-axis direction). The sensing electrode 112, wherein the first axial sensing electrode 111 and the second axial sensing electrode 112 are arranged to cross each other, and a transparent insulation is disposed between the first axial sensing electrode 111 and the second axial sensing electrode 112. The layer is used to electrically isolate the first axial sensing electrode 111 and the second axial sensing electrode 112, and thus the first axial sensing electrode 111 and the second axial sensing electrode 112 are insulated from each other and arranged in a cross arrangement. Each of the first axial sensing electrodes 111 is coupled to a first axial driving line 113 for coupling to the mode selection circuit 120 through the first axial driving line 113. Each of the second axial sensing electrodes 112 is coupled to a second axial driving line 114 for coupling to the mode selection circuit 120 through the second axial driving line 114. In a preferred embodiment, since the sensing electrode 110 needs to simultaneously perform touch position detection and fingerprint image data capture, in order to obtain a certain resolution of the captured fingerprint image data, in a preferred implementation In the example, as shown in the enlarged view of FIG. 2, the electrode width W of the first axial sensing electrode 111 and the second axial sensing electrode 112 of the present invention is preferably 50 μm, and between any two adjacent electrodes. The pitch d is preferably 20 μm.

On the other hand, when the touch position detection is performed, for example, the touch position detection is performed in a mutual capacitance manner, usually, the drive signal is sequentially sent to drive one of the axial sensing electrodes, and the other axial sense is received one by one. The sensing signal on the electrode is used to complete the addressing of each interlaced point, so the resolution of the sensing electrode affects the scan detection time. In order to avoid a decrease in the touch response speed due to the increased sensitivity of the sensing electrode resolution obtained by capturing the fingerprint image data, in a preferred embodiment, the present invention provides a plurality of first switching elements in the mode selection circuit 120. The plurality of sensing electrodes adjacent to each other in the same axial direction are connected in parallel to each other as a single sensing electrode, and the resolution of the sensing electrode 110 is changed, and the first resolution used in fingerprint recognition is converted into the second resolution used in touch detection. The rate, wherein the first resolution is greater than the second resolution, to improve the touch response speed when performing touch position detection.

3 is a schematic diagram of a mode selection circuit according to a preferred embodiment of the present invention, wherein the second axial sensing electrode 112 is changed. The resolution is described as an example, however, the same switching circuit configuration can also be used to switch the first axial sensing electrode 111. According to the embodiment, a first switching element 121 is disposed between the two adjacent second axial driving lines 114, so that the first switching element 121 is turned on when the touch position detection is performed, so that the two adjacent second axial senses are The measuring electrodes 112 form a parallel structure together as a sensing electrode, and simultaneously receive the driving signal transmitted by the touch detecting circuit 130 to adjust the resolution of the second axial sensing electrode 112 from the first resolution used for fingerprint recognition. Transform to a smaller second resolution to increase the touch response speed. In one embodiment, taking a sensing electrode having a width of 400 μm as an example, since the electrode width of each second axial sensing electrode 112 is 50 μm and the spacing between the electrodes is 20 μm, five second axes will be used. A pair of sensing electrodes 112 are formed in a parallel structure to collectively function as a sensing electrode, and the resolution is converted from a first resolution used for fingerprint recognition to a smaller second resolution. Therefore, the plurality of second axial sensing electrodes 112 are grouped in a group of five second axial sensing electrodes 112, and the first switching element 121 in each group is turned on, so that the group The five second axial sensing electrodes 112 are formed in parallel to form a sensing electrode, and are coupled to the touch detecting circuit 130 through a second switching component 122. Therefore, the touch detection circuit 130 can simultaneously transmit the driving signal to the same group of five parallel second sensing electrodes 112 through the second switching element 122 for touch position detection. The number of the second axial sensing electrodes 112 connected in parallel is not limited to the embodiment, and may be adjusted according to actual use conditions.

In addition, the second switching element 122 disposed between each of the second axial driving lines 114 and the touch detection circuit 130 may be configured according to the second axial sensing electrode. The grouping condition of 112 turns on the corresponding second switching element 122, so that the touch detection circuit 130 can transmit the driving signal to the second axial sensing electrode 112 connected in parallel in the same group through the second switching element 122. In addition, in order to cope with the change of the resolution of the sensing electrode, the present invention performs coordinate transformation in a proportional manner to locate the touch position. For example, a touch panel having 1000 second axial sensing electrodes 112 is taken as an example. If the positions of the 1000 second axial sensing electrodes 112 are respectively 1 to 1000, and then the 5 second axial sensing electrodes 112 are grouped as a group, the coordinate transformation is performed in a ratio of 5:1. Therefore, the new sensing electrode position will be 1~200.

On the other hand, each of the second axial driving lines 114 and the fingerprint identification circuit 140 further has a third switching element 123, so that the first switching element 121, the second switching element 122 and the third switching element 123 can be switched. The second axial sensing electrode 112 is coupled to the contact detecting circuit 130 or the fingerprint identifying circuit 140. For example, when the first switching element 121 and the second switching element 122 are turned on to turn off the third switching element 123, the second axial sensing electrode 112 is coupled to the contact detecting circuit 130 for touch position detection. On the other hand, when the third switching element 123 is turned on and the first switching element 121 and the second switching element 122 are turned off, the second axial sensing electrode 112 is coupled to the fingerprint identification circuit 140 for comparison of fingerprint image data. In other words, the mode selection circuit 120 can change the resolution of the sensing electrode 110 to increase the touch when the touch position detection is performed, in addition to the touch detection circuit 130 or the fingerprint identification circuit 140 and the sensing electrode 110. reaction speed.

In a preferred embodiment, the present invention drives the sensing electrode 110 to capture fingerprint image data in a mutual capacitance manner. Sensing the electrode 111 in the first axial direction In the sensing electrode structure facing the fingerprint of the user's finger, when the mutual capacitance mode is driven, the first axial sensing electrodes 111 are sequentially driven, and the sensing on the second axial sensing electrode 112 is received one by one. The signal, because the capacitance is inversely proportional to the distance, when the user's finger is placed on the first axial sensing electrode 111, the portion of the ridge that is in contact with the first axial sensing electrode 111 has a large capacitance. The partial capacitance of the groove is small, and the fingerprint identification circuit 140 can sense the fingerprint image data by receiving the sensing signal on the second axial sensing electrode 112 to distinguish the capacitance. In another embodiment, the present invention can also use the self-capacitance method to capture fingerprint image data. In the self-capacitance driving mode, the first axial sensing electrodes 111 are sequentially driven, and the second axial sense is sensed. The measuring electrode 112 is grounded. Accordingly, the fingerprint identifying circuit 140 can sense a fingerprint by receiving the first axial sensing electrode 111 and the second axial sensing electrode 112, that is, the magnitude of the capacitance between the groundings. video material.

In addition, please refer to FIG. 1 again. In an embodiment, the fingerprint image capturing region may be defined in the sensing electrode 110 in advance. The fingerprint image capturing area may be defined in any part of the sensing electrode 110. When the mobile device is triggered, the fingerprint capture area is correspondingly displayed on the defined position of the touch panel, and the mode selection circuit 120 selects the fingerprint identification circuit 140 and the sensing electrode 110 to be coupled, and the user can The finger is pressed against the fingerprint image capturing area on the touch panel, and the fingerprint image data of the user is captured by the sensing electrode 110, and then sent to the fingerprint identification circuit 140 for comparison by the mode selection circuit 120, and is turned on when the fingerprint is correct. The operational function of the mobile communication device. When the mobile communication device is turned on, the mode selection circuit 120 The touch detection circuit 130 and the sensing electrode 110 are coupled to perform touch position detection.

Accordingly, the integrated fingerprint identification device of the present invention directly uses the sensing electrode for touch detection as a fingerprint recognition electrode, and does not need to additionally provide a fingerprint recognition electrode on the mobile device, since it can be removed for fingerprint identification. Non-display area, thus maximizing the displayable area of the mobile device. Furthermore, since no additional fingerprint recognition electrodes are required, the original electrode fabrication process does not need to be changed, which is quite convenient in the process and saves process cost.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and any person skilled in the art can make various changes and refinements without departing from the spirit and scope of the present invention. The scope is subject to the definition of the scope of the patent application attached.

100‧‧‧Touch detection device

110‧‧‧Sensing electrode

111‧‧‧First axial sensing electrode

112‧‧‧Second axial sensing electrode

113‧‧‧First axial drive line

114‧‧‧Second axial drive line

120‧‧‧ mode selection circuit

130‧‧‧Touch detection circuit

140‧‧‧Fingerprint identification circuit

Claims (9)

A touch detection device with a fingerprint identification function includes at least: a sensing electrode; a mode selection circuit coupled to the sensing electrode; a touch detection circuit coupled to the mode selection circuit; and a fingerprint identification circuit, The mode selection circuit is coupled to the sensing circuit, wherein the mode selection circuit selects one of the touch detection circuit and the fingerprint identification circuit to be coupled to the sensing electrode, wherein the mode selection circuit selects the fingerprint identification circuit to couple the sensing In the case of an electrode, the sensing electrode captures a user fingerprint data at a first resolution, and when the mode selection circuit selects the touch detection circuit to couple the sensing electrode, the sensing electrode has a second resolution The touch data is captured for touch position detection, wherein the first resolution is greater than the second resolution. The touch detection device of the fingerprint identification function of claim 1, wherein the sensing electrode further comprises: a plurality of first axial sensing electrodes arranged along a first axial direction; and a plurality of second axial senses Measuring electrodes are arranged along a second axial direction; and an insulating layer is disposed between the first axial sensing electrode strips and the second axial sensing electrodes, wherein the first axial directions The sensing electrodes and the strips of second axial sensing electrodes are insulated from each other and arranged in a cross. Touch detection device with fingerprint identification function as claimed in claim 2 The electrode width of each of the first axial sensing electrodes and each of the second axial sensing electrodes is 50 μm, and between any two adjacent first axial sensing electrodes, and any two phases The distance between adjacent second axial sensing electrodes is 20 μm. The touch detection device of the fingerprint identification function of claim 2, wherein the fingerprint identification circuit drives the first axial sensing electrodes and the second axial sensing electrodes according to a mutual capacitance principle Capture the user's fingerprint data. The touch detection device with the fingerprint recognition function of claim 2, wherein the fingerprint identification circuit drives the first axial sensing electrodes and the second axial sensing electrodes according to a self-capacitance principle The user fingerprint data is captured, wherein the strips of the first axial sensing electrodes or the strips of the second axial sensing electrodes that are remote from the user fingerprint are grounded. The touch detection device with the fingerprint recognition function of claim 2, wherein the mode selection circuit further comprises a plurality of first switching elements respectively disposed on any two adjacent first axial sensing electrodes, and any two phases Adjacent to the second axial sensing electrodes, wherein any two adjacent first axial sensing electrodes or any two adjacent second axial sensing electrodes are turned on, the two adjacent The first axial sensing electrode or any two adjacent second axial sensing electrodes form a parallel junction Structure. The touch detection device with the fingerprint recognition function of claim 6, wherein the mode selection circuit groups the first axial sensing electrodes and the second axial sensing according to the second resolution Electrodes, the first switching elements in each group are turned on such that the first axial sensing electrodes in each group and the second axial sensing electrodes in each group form a parallel structure To simultaneously receive a driving signal of the touch detection circuit. The touch detection device of the fingerprint identification function of claim 2, wherein the mode selection circuit further comprises a plurality of second switching elements respectively disposed on the first axial sensing electrodes and the touch detecting circuit, And the second axial sensing electrodes and the touch detection circuit, wherein when the mode selection circuit selects the fingerprint identification circuit to be coupled to the sensing electrodes, the second switching elements are turned off, and when When the mode selection circuit selects the touch detection circuit to be coupled to the sensing electrode, the second switching elements are turned on. The touch detection device of the fingerprint identification function of claim 2, wherein the mode selection circuit further comprises a plurality of third switching elements respectively disposed on the first axial sensing electrodes and the fingerprint identification circuit, and Between the second axial sensing electrodes and the fingerprint identification circuit, wherein the third switching element is turned on when the mode selection circuit selects the fingerprint identification circuit to be coupled to the sensing electrode, and When the mode selection circuit selects the touch detection circuit to be coupled to the sensing electrode, the third switching elements are turned off.