TWI602086B - Touch control device and operation method thereof - Google Patents

Description

Touch device and its operation method

The present invention relates to a touch device, and more particularly to a touch panel device and a method of operating the same.

Current portable computers are generally equipped with multi-touch panels that can be used to sense multiple gestures to assist the user in performing various operations. However, in some specific operating situations/requirements, the user may need a mouse to perform this specific operation. In this case, the multi-touch panel cannot completely replace the mouse operation mode, so use The person will need to carry the mouse again, which makes it difficult to carry out.

The embodiment of the present invention provides a touch device. A touch device includes a touch panel; a first driving circuit coupled to the touch panel for driving the touch panel to detect a sensing value frame of a touch event on the touch panel; a system circuit, coupled to the first driving circuit, configured to analyze the sensing value frame provided by the first driving circuit to identify a first finger position, a second finger position, and at least a third finger position, and a positional relationship between a finger position, a second finger position, and at least a third finger position, wherein the first finger position is defined as a left button position of a virtual mouse, and the second finger position is defined as a virtual mouse A right click position.

The present invention further provides a method for operating a touch device, comprising: configuring a touch panel; driving a touch panel by a first driving circuit to detect a sensing value frame of a touch event on the touch panel; The system circuit analyzes the sensed value frame to identify a first finger position, a second finger position, and at least a third finger position; and the mutual position according to the first finger position, the second finger position, and the at least one third finger position The relationship is defined by the system circuit as the first finger position as a left button position of the virtual mouse, and the second finger position as a right button position of the virtual mouse.

Based on the above, the embodiment of the present invention provides a touch device and a method for operating the same, which can identify a first finger position, a second finger position, and at least a third finger position of the operation mouse gesture, and track the first finger position and the second finger. a position and a state of the at least one third finger position. The first finger position of the operation mouse gesture may correspond to a left mouse position of the virtual mouse, and the second finger position of the operation mouse gesture may correspond to a right mouse position of the virtual mouse.

In order to make the above features and advantages of the present invention more comprehensible, the following embodiments are described in detail with reference to the accompanying drawings.

The term "coupled (or connected)" as used throughout the specification (including the scope of the claims) may be used in any direct or indirect connection. For example, if the first device is described as being coupled (or connected) to the second device, it should be construed that the first device can be directly connected to the second device, or the first device can be through other devices or some means of connection. Indirectly connected to the second device. In addition, wherever possible, the elements and/ Elements/components/steps that use the same reference numbers or use the same terms in different embodiments may refer to the related description.

FIG. 1 is a block diagram showing a circuit of a touch device 100 according to an embodiment of the present invention. In one embodiment, the touch device 100 can be a notebook computer, other types of electronic computing devices, or an external peripheral device of a computer, such as an external touch pad.

Referring to FIG. 1 , the touch device 100 includes a system circuit 110 , a driving circuit 120 , and a touch panel 130 . In one embodiment, the touch panel 130 can be a self-capacitance touch panel, a mutual-capacitance touch panel, or other types of touch sensing devices. The driving circuit 120 is coupled to the touch panel 130 and the system circuit 110. In some embodiments, system circuit 110 can be a circuit having a particular function to recognize an "operating mouse gesture" on trackpad 130. In other embodiments, system circuitry 110 includes circuitry that can execute software and/or firmware, and in one embodiment can be a central processing unit, a microcontroller, a microprocessor, and/or other system circuitry.

FIG. 2 is a schematic flow chart illustrating a method of operating a touch device according to an embodiment of the present invention. Referring to FIG. 1 and FIG. 2 , the touch panel 130 is disposed on the touch device 100 . The driving circuit 120 can drive the touch panel 130 to detect a sensing value frame of a touch event on the touch panel 130 (step S210). The system circuit 110 can analyze the sensing value frame 121 provided by the driving circuit 120 to recognize an operation mouse gesture on the touch panel 130 (step S220). The operating mouse gesture includes a first finger position, a second finger position, and at least one third finger position. In an embodiment, the system circuit 110 can analyze the sensing value frame 121 provided by the driving circuit 120 to identify the first finger position, the second finger position, and the at least one third finger position. Based on the positional relationship of the first finger position, the second finger position, and the at least one third finger position, the system circuit 110 may define the first finger position as a left mouse position of the virtual mouse and define the second finger position as a virtual The right mouse button position. Based on the operating mouse gesture on the touchpad 130, the system circuitry 110 can trigger a corresponding mouse event, such as a move event, a right click event, a left click event, a left click double click event, and the like.

FIG. 3 is a schematic diagram showing the usage scenario of the touch panel 130 of FIG. 1 according to an embodiment of the present invention. The action gesture is similar to that on the touchpad 130, when the right hand 300 holds a mouse gesture (called a virtual mouse, which does not actually exist). When the user's right hand 300 holds the virtual mouse on the touchpad 130, the thumb, forefinger, middle finger, ring finger, little finger and/or part of the palm will touch the touchpad 130. The driving circuit 120 can drive the touch panel 130 to detect a touch event on the touch panel 130 and output a corresponding sensing value frame 121.

FIG. 4 is a schematic diagram showing an example of a sensing value frame 121 provided by the driving circuit 120 of FIG. 1 in the use scenario shown in FIG. 3 according to an embodiment of the present invention. Each of the small squares shown in FIG. 4 represents the sensed value of one sensing unit of the touch panel 130. A small square without a net bottom indicates that the sensed value is less than the sense threshold value, that is, no touch event occurs. A small square with a mesh bottom indicates that the sensed value is greater than the sense threshold, that is, a touch event has occurred. By comparing the sensed value with the sensed threshold value, false touch detection and/or invalid point detection can be realized.

The system circuit 110 can analyze the sensed value frame 121 provided by the drive circuit 120 to recognize an operational mouse gesture on the touchpad 130. Wherein the operating mouse gesture includes a first finger position (eg, index finger position 320), a second finger position (eg, middle finger position 330), and at least one third finger position (eg, thumb position 310, ring finger position 340, and/or little finger position) 350). Depending on the user's habits, operating the mouse gesture may also include palm position 360.

System circuitry 110 can identify palm position 360 in the sensed value frame. In some embodiments, system circuit 110 can define palm position 360 as the position of the virtual mouse. When the system circuit 110 analyzes the sensed value frame and determines that all of the detected finger positions (eg, 310, 320, 330, 340, and/or 350) in the palm position 360 and the sensed value frame collectively move in a similar vector, the system circuit 110 may trigger a "cursor movement" event (corresponding to a mouse movement) according to the similar vector, that is, when each finger position is moved from the first position to the second position, the cumulative displacement amount reaches a preset threshold value, that is, The cursor moves. In one embodiment, when the cumulative displacement of the five fingers is (-10, 2), (-18, 3), (-15, -1), (-10, 0), (- 7, 1), the cursor will move horizontally to the left. In other embodiments, the sensed value frame 121 may only have a finger position (eg, 310, 320, 330, 340, and/or 350) without a palm position 360 (eg, the user is accustomed to operating the virtual mouse in a wrist-hanging manner). In the case where the sensed value frame 121 has no palm position 360, the system circuit 110 can use the finger positions 310, 320, 330, 340, and/or 350 to calculate a center of gravity position (referred to as the center of gravity of the finger) between the plurality of fingers. . The center of gravity of the finger can be the geometric center point of the five-finger (or four-finger, or three-finger) coordinate. In one embodiment, assuming that the sensed value frame 121 has only the finger positions 310 and 320, the finger center of gravity may be the center point of the line between the finger position 310 and the finger position 320. Assuming that the sensed value frame 121 has only finger positions 310, 320, and 330, the finger center of gravity may be the geometric center point within the triangle formed by the finger positions 310, 320, and 330. In the case where the sensed value frame 121 has no palm position 360, this finger center of gravity may correspond to the position of the virtual mouse. When all detected finger positions, in one embodiment, may be the thumb position 310, the index finger position 320, the middle finger position 330, the ring finger position 340, and/or the little finger position 350, when the collective moves simultaneously with a similar vector, the finger center of gravity is also This similar vector moves so that system circuit 110 can trigger a "cursor movement" event (equivalent to mouse movement).

One or more finger positions identified during the first period (eg, thumb position 310, index finger position 320, middle finger position 330, ring finger position 340, and/or little finger position 350) are not present in the sensed value frame during the second period In the middle, the system circuit 110 can determine that the state of the one or more finger positions in the second period is the "lifted state". When the system circuit analyzes the sensed value frame and determines that the state of the index finger position 320 has risen and dropped, the system circuit 110 can trigger a "single left button press" event. When the state of the middle finger position 330 is raised and lowered, the system circuit 110 can trigger a "right mouse button press" event. When the index finger position 320 and the middle finger position 330 simultaneously slide back and forth, the system circuit 110 can trigger a "mouse wheel scrolling" event.

FIG. 5 is a schematic flow chart showing the step S220 shown in FIG. 2 according to an embodiment of the present invention. In the embodiment shown in FIG. 5, step S220 includes sub-steps S221-S224. In step S221, the sensed value frame 121 is input to the system circuit 110. In step S222, the system circuit 110 can analyze the sensing value frame 121 provided by the driving circuit 120 to perform false touch detection and/or invalid point detection. The sensing value frame 121 may have touch point information in addition to the sensing value (which may be a mutual capacitance value in one embodiment). In an embodiment, the touch point information may include a coordinate of the touch point, a state of the touch point (eg, a raised state or a lowered state), a number of the touch point, and/or other information. In an embodiment, the touch point information may be represented by a touch point sequence {P _i }, where P _i = (PI _i , PX _i , PY _i , PS _i , PV _i , PP _i ), PI _i Indicates the number of the i-th touch point, PX _i represents the X coordinate of the i-th touch point, PY _i represents the Y coordinate of the i-th touch point, and PS _i represents the touch state of the i-th touch point. PV _i indicates whether the i-th touch point is valid, and PP _i indicates the palm flag of the i-th touch point. The system circuit 110 can record the touch point sequence {CurP _i } of the current frame and the previous touch point sequence {PreP _i }. Comparing {CurP _i } and {PreP _i } can determine whether the touch state of the touch point is a raised state or a lowered state.

In step S223, the system circuit 110 can perform pairing identification of the finger. In an embodiment, the system circuit 110 can analyze the sensing value frame 121 provided by the driving circuit 120 to calculate the touch area. The system circuit 110 can find a sensing location having a touch area greater than the area threshold and define the sensing position as the palm position 360. This palm position 360 can be considered as the pivot position to calculate the pivot position to the finger position in a subsequent step (in one embodiment, the thumb position 310, the index finger position 320, the middle finger position 330, the ring finger position 340, and/or The vector of the little finger position 350). The smallest non-rotating rectangle of the palm position 360 can be regarded as an axis bounding box (axis_bounding). In an embodiment, the palm flag of the sensing position (palm position 360) can be updated to "1". When the palm flag is 1, the same sensing position of the next frame (the same number of touch points) will continue to retain the palm flag until the status of the touch point changes from "down" to "lift" The palm flag is cleared to 0.

After finding the palm position 360, the system circuit 110 can find the detected finger position near the palm position 360, which in one embodiment is the thumb position 310, the index finger position 320, the middle finger position 330, the ring finger position 340, and/or The little finger is positioned 350 and the fingers are paired. In an embodiment, the system circuit 110 can calculate a vector of the palm position 360 (axis position) to the thumb position 310, calculate a vector of the palm position 360 to the index finger position 320, calculate a vector of the palm position 360 to the middle finger position 330, and calculate the palm of the hand. The vector of position 360 to the ring finger position 340, and the vector that calculates the palm position 360 to the little finger position 350. The vector is converted to an angle, which in one embodiment may be the angle of the finger vector to the X axis. Taking the right hand as an example, the angle of the finger is detected from the largest to the smallest, and the sorted finger vectors are sequentially defined as the thumb, the index finger, the middle finger, the ring finger, and the little finger. When the finger vector is paired with the finger, the touch point number, the two-dimensional coordinate, the angle, and the touch point state of each finger are also recorded. The paired finger vector sequence in one embodiment may be represented as {V _i }, where V _i = {VT _i , VI _i , VX _i , VY _i , VS _i , VA _i }, VT _i represents the ith finger The finger name corresponding to the vector (such as thumb, index finger, middle finger, ring finger or little finger), VI _i represents the touch number corresponding to the i-th finger vector, VX _i represents the X coordinate of the i-th finger vector, and VY _i represents the first The Y coordinate of the i finger vector, VS _i represents the touch state of the i th finger vector, and VA _i represents the angle of the i th finger vector and the axis. The system circuit 110 can record the current paired post-pitch vector sequence {CurV _i } and the previous paired post-finger vector sequence {PreV _i }. Comparing {CurV _i } and {PreV _i } can determine whether the touch state of the finger vector is the raised state or the lowered state.

In step S224, the system circuit 110 can perform gesture detection and recognition according to the pairing result of the finger. Gestures can be determined according to design needs. In one embodiment, when the system circuit 110 analyzes the sensed value frame and determines that the first finger position (eg, the index finger position 320) and the second finger position (eg, the middle finger position 330) remain in the "up" state, the other finger positions ( The state of the third finger position, such as the thumb position 310, the ring finger position 340, and/or the little finger position 350), remains in the "down" state, and the third finger position collectively moves with a similar vector, the system circuit 110 can The "cursor movement" event is triggered correspondingly according to the similar vector. In another embodiment, when the first finger position (eg, index finger position 320), the second finger position (eg, middle finger position 330), and the third finger position (eg, thumb position 310, ring finger position 340, and/or little finger position 350) The state of the state is maintained in the "down" state, and when the first finger position, the second finger position, and the third finger position collectively move in a similar vector, the system circuit 110 can trigger the "cursor movement" event correspondingly.

In some embodiments, when the system circuit 110 analyzes the sensed value frame, it is determined that the state of the first finger position (eg, the index finger position 320) and the third finger position remains in the "down" state, and the second finger position (eg, the middle finger position) 330) When the "down" state (DOWN1) is changed to the "lifted" state (UP1) and then returned to the "down" state (DOWN2) (where the time difference between DOWN2 and UP1 is less than the time threshold), the system circuit 110 can trigger " Right click on the event. When the system circuit 110 analyzes the sensed value frame, it is determined that the state of the second finger position (for example, the middle finger position 330) and the third finger position is maintained in the "down" state, and the first finger position (eg, the index finger position 320) is "down". When the state (DOWN1) changes to the "up" state (UP1) and then returns to the "down" state (DOWN2) (where the time difference between DOWN2 and UP1 is less than the time threshold), the system circuit 110 can trigger a "left mouse click" "event. When the system circuit 110 analyzes the sensed value frame, it is determined that the state of the second finger position (for example, the middle finger position 330) and the third finger position is maintained in the "down" state, and the first finger position (eg, the index finger position 320) is "down". The state (DOWN1) changes to the "lift" state (UP1) and then returns to the "down" state (DOWN2) and then changes to the "lifted" state (UP2) and then returns to the "down" state (DOWN3) (where DOWN2 and The time difference of UP1 is less than the time threshold, and the time difference between UP2 and DOWN3 is less than the time threshold), and the system circuit 110 can trigger the "double-click double-click" event.

In other embodiments, when the system circuit 110 analyzes the sensed value frame, it determines that the state of the first finger position (eg, the index finger position 320) and the third finger position remains in the "down" state, and the second finger position (eg, the middle finger) Position 330) changes from the "down" state (DOWN1) to the "lifted" state (UP1) and then back to the "down" state (DOWN2) and then changes to the "lifted" state (UP2) (where DOWN2 and UP1 are The time difference is less than the time threshold), and the system circuit 110 can trigger a "right mouse click" event. When the system circuit 110 analyzes the sensed value frame, it is determined that the state of the second finger position (for example, the middle finger position 330) and the third finger position is maintained in the "down" state, and the first finger position (eg, the index finger position 320) is "down". When the state (DOWN1) changes to the "lifted" state (UP1) and then returns to the "down" state (DOWN2) and then changes to the "lifted" state (UP2) (where the time difference between DOWN2 and UP1 is less than the time threshold), System circuit 110 can trigger a "left mouse click" event.

When the system circuit 110 analyzes the sensed value frame, it is determined that the state of the second finger position (for example, the middle finger position 330) and the third finger position is maintained in the "down" state, and the first finger position (eg, the index finger position 320) is "down". Change state (DOWN1) to "lift" state (UP1) and then return to "down" state (DOWN2) and then change to "lift" state (UP2) and then return to "down" state (DOWN3) and then change to " When the state is raised (UP3) (wherein the time difference between DOWN2 and UP1 is less than the time threshold, and the time difference between UP2 and DOWN3 is less than the time threshold), the system circuit 110 can trigger the "double-click double-click" event.

When the system circuit 110 analyzes the sensed value frame, it is determined that the state of the second finger position (for example, the middle finger position 330) and the third finger position is maintained in the "down" state, and the first finger position (eg, the index finger position 320) is "down". When the state changes to the "up" state and then returns to the "down" state, and the first finger position, the second finger position, and the third finger position collectively move in a similar vector, the system circuit 110 can trigger the drag event according to the similar vector.

FIG. 6 is a schematic diagram showing an application example of a touch device according to an embodiment of the present invention. The notebook computer 600 shown in FIG. 6 can be the touch device 100 shown in FIG. 1 or the touch device 700 shown in FIG. 7 (described in detail later). The notebook computer 600 includes a body 610 and a body 620. The body 620 is pivoted on one side of the body 610. The display panel 621 is disposed on the body 620. The system circuit 110 , the driving circuit 120 , the touch panel 130 , and the keyboard 611 are disposed on the body 610 , wherein the touch panel 130 can be disposed on the touch panel region 612 of the body 610 .

FIG. 7 is a block diagram showing a circuit of a touch device 700 according to another embodiment of the present invention. The touch device 700 includes a system circuit 110 , a driving circuit 120 , a touch panel 130 , a driving circuit 710 , a first sensor 720 , a driving circuit 730 , and a second sensor 740 . The system circuit 110, the driving circuit 120, and the touch panel 130 shown in FIG. 7 can refer to the related descriptions of the system circuit 110, the driving circuit 120, and the touch panel 130 shown in FIG. 1, and the related descriptions with reference to FIG. 2 to FIG. No longer. The number of first sensors 720 and the number of second sensors 740 can be determined based on design requirements. The first sensor 720 and the second sensor 740 can be self-capacitive touch sensors, mutual capacitive touch sensors or other types of touch sensing devices. In some embodiments, the first sensor 720 and/or the second sensor 740 can be a non-contact sensing device, such as a proximity sensor, a self-capacitive touch sensor, or the like.

FIG. 8 is a side cross-sectional view showing the notebook computer 600 of FIG. 6 in accordance with an embodiment of the present invention. Referring to FIG. 7 and FIG. 8 , the first sensor 720 is disposed on the first side of the touch panel 130 , and the second sensor 740 is disposed on the second side of the touch panel 130 . FIG. 9 is a top plan view showing the touch panel region 612 of FIG. 8 according to an embodiment of the present invention. The first sensor 720 and the second sensor 740 are elongated sensors. The first sensor 720 and the second sensor 740 are respectively disposed on opposite sides of the touch panel 130 .

The driving circuit 710 is coupled to the first sensor 720 and the system circuit 110. The driving circuit 710 can drive the first sensor 720 to detect a touch event on the first sensor 720. When the system circuit 110 senses a touch event on the first sensor 720 via the driving circuit 710, the system circuit 110 ignores the touch event of the touch panel 130 to respond to avoid a false touch. The driving circuit 730 is coupled to the second sensor 740 and the system circuit 110. The driving circuit 730 can drive the second sensor 740 to detect a touch event on the second sensor 740. When the system circuit 110 senses a touch event on the second sensor 740 via the drive circuit 730, the system circuit 110 uses the position of the second sensor 740 as the palm position for operating the mouse gesture (eg, instead of / As the palm position 360 shown in Fig. 4).

FIG. 10 is a top plan view showing the touch panel region 612 of FIG. 8 according to another embodiment of the present invention. The first sensor 720 includes two sensors 721 and 722, and the second sensor 740 includes two sensors 741 and 742. In one embodiment, the sensors 721, 722, 741, and 742 are elongated sensors, and the sensors 721, 722, 741, and 742 can be self-capacitive touch sensors and mutual capacitive touch. A sensor or other type of touch sensing device. In some embodiments, the sensors 721, 722, 741, and 742 can be non-contact sensing devices, such as proximity sensors, self-capacitive touch sensors, and the like. The sensors 721 and 722 are disposed on one side of the touch panel 130, and the sensors 741 and 742 are disposed on opposite sides of the touch panel 130, as shown in FIG. When the system circuit 110 senses a touch event on the first sensor 720 via the driving circuit 710, the system circuit 110 ignores (does not process) the corresponding area of the touchpad 130 corresponding to the first sensor 710. Touch the event. In an embodiment, when the system circuit 110 senses a touch event on the sensor 721 via the driving circuit 710, the system circuit 110 ignores (does not process) the correspondence of the touchpad 130 corresponding to the sensor 721. The touch event of the area 131. Therefore, when the user operates the keyboard 611 with the left hand and the touch panel 130 with the right hand, the left wrist placed on the touch panel 130 does not accidentally trigger the corresponding area 131 of the touch panel 130. Similarly, when the system circuit 110 senses a touch event on the sensor 722 via the drive circuit 710, the system circuit 110 can ignore (not process) the corresponding area 132 of the touchpad 130 corresponding to the sensor 722. Touch event.

When the system circuit 110 senses a touch event on the second sensor 740 via the drive circuit 730, the system circuit 110 uses the position of the second sensor 740 as the palm position for operating the mouse gesture (eg, instead of / As the palm position 360 shown in Fig. 4). In one embodiment, when the system circuit 110 senses a touch event on the sensor 741 via the drive circuit 730, the system circuit 110 uses the position of the sensor 741 as the palm position for operating the mouse gesture (eg, Replace / as the palm position 360 shown in Figure 4. Similarly, when system circuit 110 senses a touch event on sensor 742 via drive circuit 730, system circuit 110 uses the position of sensor 742 as the palm position to operate the mouse gesture.

FIG. 11 is a top plan view showing the touch panel region 612 of FIG. 8 according to another embodiment of the present invention. The first sensor 720 includes six sensors 723, 724, 725, 726, 727, and 728, and the second sensor 740 includes six sensors 743, 744, 745, 746, 747, and 748. The sensors 723 to 728 and 743 to 748 are elongated sensors. The sensors 723-728 and 743-748 can be self-contained touch sensors, mutual capacitive touch sensors or other types of touch sensing devices. In some embodiments, sensors 723-728 and 743-748 may be non-contact sensing devices, such as proximity sensors, self-capacitive touch sensors, and the like. The sensors 723 to 728 are disposed on one side of the touch panel 130, and the sensors 743 to 748 are disposed on opposite sides of the touch panel 130, as shown in FIG. When the system circuit 110 senses a touch event on the sensors 723-728 via the drive circuit 710, the system circuit 110 can ignore (not process) the corresponding area of the touchpad 130 corresponding to the sensors 723-728. Touch event. For example, when the user's left hand 1110 operates the keyboard 611 and the right hand 1120 operates the touch panel 130, the sensors 723 and 724 can sense the left hand 1110, so that the touch events of the touchpad 130 corresponding regions 133 and 134 are ignore. Therefore, the left wrist placed on the touch panel 130 does not accidentally trigger the corresponding regions 133 and 134 of the touch panel 130.

When the system circuit 110 senses a touch event on the sensors 743-748 via the drive circuit 730, the system circuit 110 uses the position of the sensors 743-748 as the palm position for operating the mouse gesture. In an embodiment, when the system circuit 110 senses a touch event on the sensor 747 via the drive circuit 730, the system circuit 110 uses the position of the sensor 747 as the palm position for operating the mouse gesture (eg, Replace / as the palm position 360 shown in Figure 4.

In different application scenarios, the relevant functions of system circuitry 110 may utilize general programming languages (such as C or C++), hardware description languages (such as Verilog HDL or VHDL), or other suitable programming languages. To be implemented as software, firmware or hardware. Software (or firmware) that can perform related functions can be arranged as any known computer-accessible medias, such as magnetic tapes, semiconductors, magnetic disks. Or compact disks (such as CD-ROM or DVD-ROM), or software (or firmware) can be transmitted via the Internet, wired communication, wireless communication, or other communication medium. The software (or firmware) can be stored in an accessible medium of the computer to facilitate access to/execute software (or firmware) programming codes by the processor of the computer. In addition, the apparatus and method of the present invention can be realized by a combination of hardware and software.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and the scope of protection of this case is subject to the definition of the appended patent application.

100, 700‧‧‧ touch devices
110‧‧‧System Circuit
120‧‧‧Drive circuit
121‧‧‧Sensor frame
130‧‧‧Touchpad
131～134‧‧‧ corresponding area
300, 1120‧‧‧ right hand
310‧‧‧ Thumb position
320‧‧‧ index finger position
330‧‧‧ middle finger position
340‧‧‧ ring finger position
350‧‧‧Little finger position
360‧‧‧ palm position
600‧‧‧Note Computer
610‧‧‧ Ontology
611‧‧‧ keyboard
612‧‧‧Touchpad area
620‧‧‧ Ontology
621‧‧‧ display panel
710, 730‧‧‧ drive circuit
720‧‧‧first sensor
721～728, 741～748‧‧‧ sensor
740‧‧‧Second sensor
1110‧‧‧ left hand
S210～S220, S221～S224‧‧‧ steps

FIG. 1 is a block diagram showing a circuit of a touch device according to an embodiment of the present invention. FIG. 2 is a schematic flow chart illustrating a method of operating a touch device according to an embodiment of the present invention. FIG. 3 is a schematic diagram showing the usage scenario of the touch panel shown in FIG. 1 according to an embodiment of the present invention. FIG. 4 is a schematic diagram showing an example of a sensing value frame provided by the driving circuit shown in FIG. 1 in the use scenario shown in FIG. 3 according to an embodiment of the present invention. FIG. 5 is a schematic flow chart showing the step S220 shown in FIG. 2 according to an embodiment of the present invention. FIG. 6 is a schematic diagram showing an application example of a touch device according to an embodiment of the present invention. FIG. 7 is a block diagram showing a circuit of a touch device according to another embodiment of the present invention. FIG. 8 is a side cross-sectional view showing the notebook computer of FIG. 6 according to an embodiment of the present invention. FIG. 9 is a top plan view showing the touch panel area of FIG. 8 according to an embodiment of the present invention. FIG. 10 is a top plan view showing the touch panel area of FIG. 8 according to another embodiment of the present invention. FIG. 11 is a top plan view showing the touch panel area of FIG. 8 according to another embodiment of the present invention.

130‧‧‧Touchpad

133, 134‧‧‧ corresponding areas

610‧‧‧ Ontology

611‧‧‧ keyboard

612‧‧‧Touchpad area

620‧‧‧ Ontology

621‧‧‧ display panel

720‧‧‧first sensor

723~728, 743~748‧‧‧ sensor

740‧‧‧Second sensor

1110‧‧‧ left hand

1120‧‧‧ right hand

Claims (24)

A touch device includes: a touch panel; a first driving circuit coupled to the touch panel for driving the touch panel to detect a touch event on the touch panel And a system circuit coupled to the first driving circuit for analyzing the sensing value frame provided by the first driving circuit to identify a first finger position, a second finger position, and at least one a three-finger position, and defining a first finger position as a left-click position of a virtual mouse according to a positional relationship between the first finger position, the second finger position, and the at least one third finger position; And defining the second finger position as a right button position of the virtual mouse. The touch device of claim 1, wherein the system circuit further identifies a palm position in the sensing value frame, and defines the palm position as the position of the virtual mouse, when the system circuit analyzes The system circuit triggers a cursor movement event when the sensed value frame determines that the position of the palm and the position of all of the fingers in the sensed value frame collectively move in a similar vector. The touch device of claim 1, wherein the first finger position and the second finger position that are recognized during a first period are not present in the sensing value frame during a second period The system circuit determines that the state of the first finger position and the second finger position in the second period is a raised state; and when the system circuit analyzes the sensing value frame, determines the first finger position and the second The system circuit triggers a cursor movement event when the finger position is maintained in the raised state, the state of the at least one third finger position is maintained in a lowered state, and the at least one third finger position collectively moves in a similar vector . The touch device of claim 1, wherein the system circuit determines that the second finger position recognized during a first period does not exist in the sensing value frame during a second period. The state of the second finger position in the second period is a raised state; when the system circuit analyzes the sensing value frame, determining that the state of the first finger position and the at least one third finger position is maintained in a lowered state The system circuit triggers a mouse right click event when the second finger position changes from the lowered state to the raised state and then returns to the lowered state. The touch device of claim 1, wherein the system circuit determines that the second finger position recognized during a first period does not exist in the sensing value frame during a second period. The state of the second finger position in the second period is a raised state; when the system circuit analyzes the sensing value frame, determining that the state of the first finger position and the at least one third finger position is maintained in a lowered state The system circuit triggers a mouse right click event when the second finger position changes from the lowered state to the raised state and then returns to the lowered state and then changes to the raised state. The touch device of claim 1, wherein the system circuit determines that the first finger position recognized during a first period does not exist in the sensing value frame during a second period The state of the first finger position in the second period is a raised state; when the system circuit analyzes the sensing value frame, determining that the state of the second finger position and the at least one third finger position are maintained in a lowered state The system circuit triggers a mouse left click event when the first finger position changes from the lowered state to the raised state and returns to the lowered state. The touch device of claim 1, wherein the system circuit determines that the first finger position recognized during a first period does not exist in the sensing value frame during a second period The state of the first finger position in the second period is a raised state; when the system circuit analyzes the sensing value frame, determining that the state of the second finger position and the at least one third finger position are maintained in a lowered state The system circuit triggers a mouse left click event when the first finger position changes from the lowered state to the raised state and then returns to the lowered state and then changes to the raised state. The touch device of claim 1, wherein the system circuit determines that the first finger position recognized during a first period does not exist in the sensing value frame during a second period The state of the first finger position in the second period is a raised state; when the system circuit analyzes the sensing value frame, determining that the state of the second finger position and the at least one third finger position are maintained in a lowered state And the system circuit triggers a left-click double-click event when the first finger position changes from the lowered state to the raised state and then returns to the lowered state and then changes to the raised state and then returns to the lowered state. The touch device of claim 1, wherein the system circuit determines that the first finger position recognized during a first period does not exist in the sensing value frame during a second period The state of the first finger position in the second period is a raised state; when the system circuit analyzes the sensing value frame, determining that the state of the second finger position and the at least one third finger position are maintained in a lowered state The system circuit triggers when the first finger position changes from the lowered state to the raised state and then returns to the lowered state and then changes to the raised state and then returns to the lowered state and then changes to the raised state. Left mouse click on the event. The touch device of claim 1, wherein the system circuit determines that the first finger position recognized during a first period does not exist in the sensing value frame during a second period The state of the first finger position in the second period is a raised state; when the system circuit analyzes the sensing value frame, determining that the state of the second finger position and the at least one third finger position are maintained in a lowered state And the first finger position changes from the lowered state to the raised state and then returns to the lowered state, and the first finger position, the second finger position, and the at least one third finger position collectively adopt a similar vector The system circuit triggers a drag event while moving. The touch device of claim 1, further comprising: at least one first sensor disposed on a first side of the touch panel; and a second driving circuit coupled to the at least a first sensor and the system circuit for driving the at least one first sensor to detect a touch event on the at least one first sensor; wherein when the system circuit is When the two driving circuit senses the touch event on the at least one first sensor, the system circuit ignores a touch corresponding to a corresponding area of the touch panel of the at least one first sensor Hit the event. The touch device of claim 11, further comprising: at least one second sensor disposed on a second side of the touch panel; and a third driving circuit coupled to the at least a second sensor and the system circuit for driving the at least one second sensor to detect a touch event on the at least one second sensor; wherein when the system circuit is When the three driving circuit senses the touch event on the at least one second sensor, the system circuit uses the position of the at least one second sensor as a palm position. A method for operating a touch device includes: configuring a touch panel; driving a touch panel by a first driving circuit to detect a sensing value frame of a touch event on the touch panel; The system circuit analyzes the sensed value frame to identify a first finger position, a second finger position, and at least a third finger position; and according to the first finger position, the second finger position, and the at least one third The positional relationship of the finger positions is defined by the system circuit as a left button position of a virtual mouse, and the second finger position is defined as a right button position of the virtual mouse. The operating method of the touch device of claim 13, wherein the system circuit further identifies a palm position in the sensing value frame, and defines the palm position as a position of the virtual mouse, The operating method further includes: when the system circuit analyzes the sensing value frame and determines that the position of the palm and all the positions of the fingers in the sensing value frame collectively move by a similar vector, a cursor movement event is triggered by the system circuit. The operating method of the touch device of claim 13, wherein the first finger position and the second finger position recognized during a first period are not present in the sensing value during a second period. In the frame, the system circuit determines that the state of the first finger position and the second finger position in the second period is a raised state, and the operating method further comprises: when the system circuit analyzes the sensing value frame And determining that the first finger position and the second finger position are maintained in the raised state, the state of the at least one third finger position is maintained in a lowered state, and the at least one third finger position collectively adopts a similar vector When moving, a cursor movement event is triggered by the system circuitry. The operating method of the touch device of claim 13, wherein the second finger position recognized during a first period does not exist in the sensing value frame during a second period, the system The circuit determines that the state of the second finger position in the second period is a raised state, and the operating method further includes: determining, by the system circuit, the first finger position and the at least one The state of the third finger position is maintained in a lowered state, and when the second finger position is changed from the lowered state to the raised state and returned to the lowered state, a mouse right click event is triggered by the system circuit. The operating method of the touch device of claim 13, wherein the second finger position recognized during a first period does not exist in the sensing value frame during a second period, the system The circuit determines that the state of the second finger position in the second period is a raised state, and the operating method further includes: maintaining the state of the first finger position and the at least one third finger position in a lowered state And when the second finger position changes from the lowered state to the raised state and then returns to the lowered state and then changes to the raised state, a mouse right click event is triggered by the system circuit. The operating method of the touch device of claim 13, wherein the first finger position recognized during a first period does not exist in the sensing value frame during a second period, the system The circuit determines that the state of the first finger position in the second period is a raised state, and the operating method further includes: determining, by the system circuit, the second finger position and the at least one The state of the third finger position is maintained in a lowered state, and when the first finger position is changed from the lowered state to the raised state and then returned to the lowered state, a mouse click event is triggered by the system circuit. The operating method of the touch device of claim 13, wherein the first finger position recognized during a first period does not exist in the sensing value frame during a second period, the system The circuit determines that the state of the first finger position in the second period is a raised state, and the operating method further includes: determining, by the system circuit, the second finger position and the at least one The state of the third finger position is maintained in a lowered state, and when the first finger position is changed from the lowered state to the raised state and then returned to the lowered state and then changed to the raised state, the system circuit triggers a Mouse left click event. The operating method of the touch device of claim 13, wherein the first finger position recognized during a first period does not exist in the sensing value frame during a second period, the system The circuit determines that the state of the first finger position in the second period is a raised state, and the operating method further includes: determining, by the system circuit, the second finger position and the at least one The state of the third finger position is maintained in a lowered state, and the first finger position is changed from the lowered state to the raised state, and then returned to the lowered state and then changed to the raised state and returned to the lowered state, The system circuit triggers a left-click double-click event. The operating method of the touch device of claim 13, wherein the first finger position recognized during a first period does not exist in the sensing value frame during a second period, the system The circuit determines that the state of the first finger position in the second period is a raised state, and the operating method further includes: determining, by the system circuit, the second finger position and the at least one The state of the third finger position is maintained in a lowered state, and the first finger position is changed from the lowered state to the raised state, then returned to the lowered state, and then changed to the raised state and then returned to the lowered state and then changed. By the time the up state is reached, a single left click event is triggered by the system circuitry. The operating method of the touch device of claim 13, wherein the first finger position recognized during a first period does not exist in the sensing value frame during a second period, the system The circuit determines that the state of the first finger position in the second period is a raised state, and the operating method further includes: determining, by the system circuit, the second finger position and the at least one The state of the third finger position is maintained in a lowered state, and the first finger position is changed from the lowered state to the raised state and returned to the lowered state, and the first finger position, the second finger position, and the When the at least one third finger position collectively moves with a similar vector, the system circuit triggers a drag event based on the similar vector. The method of operating the touch device of claim 13, further comprising: configuring at least one first sensor on a first side of the touch panel; and driving the at least one by a second driving circuit a first sensor for detecting a touch event on the at least one first sensor; and ignoring the corresponding when the touch event on the at least one first sensor is sensed a touch event of a corresponding area of the touch panel of the at least one first sensor. The method of operating the touch device of claim 23, further comprising: configuring at least one second sensor on a second side of the touch panel; driving the at least one by a third driving circuit a second sensor to detect a touch event on the at least one second sensor; and when the touch event on the at least one second sensor is sensed, The position of the at least one second sensor is referred to as a palm position.