TW201211835A - Input device and pen-type mouse - Google Patents

Abstract

An input device includes an input member, a pressure sensing unit, and a microprocessor. The pressure sensing unit is mounted in the input member. The microprocessor is electrically connected to the pressure sensing unit and includes plural default values. When the input member is subject to a force and makes the pressure sensing unit generate a pressure signal, the microprocessor compares the pressure signal with each of the default values to output a corresponding control signal. In this way, the input device makes the microprocessor output a different control signal according to the magnitude of the pressure acting on the input member, thereby enabling a receiving device coupled to the input device to carry out a corresponding operation in accordance with the control signal.

Description

201211835 VI. Description of the Invention: [Technical Field] The present invention relates to an input device and a pen-type mouse, and more particularly to an input device for outputting a control signal by different pressure intensities of an input member or a pen tip And pen type mouse. [Prior Art] The mouse has become a common input device for computers, and the main types can be divided into mechanical and optical mice. The optical mouse mainly includes a sensing module rts ^_ and a control circuit module. Sensing module

The mechanical mouse mainly includes a trackball, two sensing modules, a control circuit and three buttons. Each sensing module includes a photosensitive disk, a light emitting unit, and a receiving unit. When the mechanical mouse moves, the lion's ball will roll and feed each photosensitive disc. The light emitted by each of the light-emitting units is divided into light-sensing_, and each-receiving unit receives light passing through each of the receiving disks. The control circuit receives the signal generated by each-receiving order=by receiving the light passing through each photosensitive disc, and based on these signals, carries out the calculation of the position of the mechanical mouse, and then returns the calculation result to the computer's related technology. And research can refer to Yan Zhunxiang No. 6489948. When the group is back to the computer, the button of 201211835 is only the function of being pressed and not pressed. Facing the continuous advancement of information technology, the development of diversified computer software, the above-mentioned mechanical or optical sliding The function of the mouse is no longer sufficient. SUMMARY OF THE INVENTION In view of the above problems, the present invention provides an input device and a pen-type mouse, thereby solving the above-mentioned conventional mechanical mouse or optical sliding function by solving the function that the button is only pressed and not pressed. There is a problem with the lack of function of the mouse. An embodiment of the input device according to the present invention includes an input member, a pressure sensing unit, and a micro processing. The pressure lying unit is disposed on the input unit, and the microprocessor is electrically connected to the first unit and includes Multiple job values. When the operator applies the pressure intensity to the input member, the pressure unit receives the pressure intensity of the operator to apply the pressure member, and generates a pressure signal according to the magnitude of the pressure intensity applied by the operator to the input member, and the microprocessor applies the pressure signal to each - Pre-practice for comparison and output corresponding control signals. In a implementation, the micro-initiator includes a second-preset value, and the microprocessor receives and relies on the pressure domain as the corresponding Lai value, and the Lai value is respectively performed with the second preset value. The comparison results in a comparative result that is more positive than the first control signal, the second control signal, and the third control: U. Wherein the second preset value may be greater than the first preset value. When the pressure value is greater than the first preset value and the second preset value, the microprocessor outputs the first control signal. When the pressure value is less than the second weaving value, the micro (4) input (four) and the second control are used as a ring. When the value is less than the first preset value and the second preset value, the microprocessor outputs the first. 201211835 Three control signals. In one embodiment, the pressure sensing unit includes a ruler (the circuit, the RC circuit includes a first variable capacitor or a Buchholster resistor, wherein the first variable capacitor can be sized according to the pressure applied by the operator to the input member And changing the capacitance value, or the first variable resistor can change the electric bribe according to the pressure strength of the operator escaping the human part, so that the pressure money output by the pressure sensing unit can be applied with the pressure strength of the input member according to the operator. In the embodiment, the pressure sensing unit includes a voltage output circuit, the microprocessor includes an analog digital conversion n, the voltage output circuit includes a second Wei resistance, and the pressure sensing unit transmits a force signal to the digital camera. The second Wei resistance can change the resistance value according to the pressure intensity of the operator to be applied to the input member, so that the output signal of the pressure sensing unit can be given according to the magnitude of the force strength of the operator (4) The analog digital converter converts the pressure signal transmitted by the pressure sensing unit from the analog signal to the digital signal. In the example, the pressure sensing unit includes a step rate generating circuit and a frequency generating circuit package. Can be 'Wei sense, variable inductance can change the electrical complexity as the operator gives the pressure of the input part, so that the pressure signal of the pressure_single output can be the pressure intensity of the input part with the operator. However, the input device disclosed by the present invention can change the waste force signal generated by the pressure sensing unit as the pressure applied by the operator to the input member, thereby causing the microprocessor to output different control signals. These non-control signals are transmitted to the receiving device that is connected to the input device to enable the subtracting device to perform the corresponding operation of the phase 201211835 according to these non-control codes. For example, the micro-receiving includes two preset values for micro processing. The operator can read the human part and force the size of the class to output the corresponding control signal. That is to say, each of the input parts has three (four) functions. Therefore, by means of the force sensing single 7L and micro-u The setting can increase the use function of each input member. According to the pen type mouse disclosed in the present invention, the pen type mouse includes a displacement sensing unit, a pen head, a pressure sensing unit and a microprocessor. The pressure sensing unit is disposed on the writing head, the microprocessor is electrically connected to the pressure unit and the displacement sensing unit, and the microprocessor includes a plurality of thief values. When the operator applies pressure to the writing head, the pressure _ unit Wei The operator writes the _ pressure intensity, and generates a pressure signal according to the size of the domain (4). The microprocessor inputs (4) the control signal according to the pressure signal. That is, the pressure signal generated by the pressure_unit The operator changes the intensity of the pen tip, so that the microprocessor takes out different control money, and the same control money is transmitted to the receiving device with the input device, so that the receiving device according to these different controls The signal is correspondingly operated. j-implementing the 'micro' (four) package - the preset value and the third preset value, micro-receiving and converting the wish signal to the corresponding pressure value, and the pressure value is respectively discured and The two preset health comparisons produce a comparison result, and the micro-processing _ number, the first: the third control of the relay = the i-th r-th set value may be greater than the first-preset value. When the dynamic value is greater than the first husband in the flute one < pre 7 handle 'microprocessor output first - control success number, when the house value; pre & recording less than the second preset, micro processing H output second control letter When the field pressure value of 201211835 is less than the first preset value and the second preset value, the microprocessor outputs a third control signal. The pen type mouse disclosed in the present invention can be changed by the pressure signal generated by the field unit as the operator gives the magnitude of the force, thereby causing the microprocessor to output different control numbers. These non-control signals are transmitted to the receiving device of the pen-type slip-to-air transfer. The money receiving device performs the operation according to these non-executive moneys, thereby replacing the digits β and the implementation manners of the present day and the month. The present invention is used to demonstrate and explain the present invention, and to provide a further explanation of the scope of the present application. [Embodiment] Please refer to "Figure 1", which is a circuit block diagram of an input device invented by Yixian. The computer input device (not shown) is configured to control the cursor (not shown), for example, a keyboard, a mouse or a tablet. In this embodiment, the computer input device is a keyboard ‘but not limited thereto. The computer input device includes an input device, wherein the input device 100 includes an input member 102, a pressure sensing unit 104, a microprocessor 1, and a power supply 108. In the embodiment, the input member 1G2 can be, but is not limited to, a single-button, that is, the input member 1〇2 can also be a two-way button. Please refer to the description of the input member 102 as a two-way button. The pressure sensing unit 104 is disposed on the input component 1〇2, and the microprocessor i〇6 is electrically connected to the pressure sensing unit 104 and includes but is not limited to the first preset value 113 and the second preset value 114′ transmission module. 112 lightly connected to the microprocessor. The power supply 1〇8 system is electrically connected to the 201211835 force sensing unit 1〇4, the microprocessor 1〇6 and the transmission module 112. The transmission module 112 transmits the signals generated by the microprocessors 1 to 6 to a computer (not shown) that is lightly connected to the computer input device. When the operator applies the pressure intensity to the input member 1〇2, the pressure sensing unit 1〇4 receives the pressure applied to the input member 1〇2. The pressure sensing unit 1〇4 generates a pressure signal 115 according to the pressure intensity received by the input member 102, and then the microprocessor 1〇6 performs the pressure signal 115 with the first preset value 113 and the second preset value 114. The corresponding control signal in is outputted. After the transmission module 112 receives the control signal iu, the transmission module 112 transmits the control signal ill to the computer coupled to the computer input device, so that the computer can perform the relative control according to the control signal ln transmitted by the transmission module 112. Operation. In this embodiment, the microprocessor 106 receives and converts the pressure signal 115 to a corresponding pressure value (not labeled), and compares the pressure value with the first preset value 113 and the second preset value 114 to generate a comparison. As a result, the microprocessor 1〇6 then outputs a relative first control signal (not labeled), a second control signal (not labeled), and a third control signal (not labeled) according to the comparison result. The first preset value 114 may be greater than the first preset value iu, and when the pressure value is greater than the first preset value 113 and the second preset value Π4, the microprocessor 1〇6 outputs the first control signal; When the pressure value is greater than the first preset value 113 but less than the second preset value 114, the microprocessor 106 outputs a second control signal; when the pressure value is less than the first preset value 113 and the second preset value 114, the micro processing The device 1〇6 outputs a third control signal, but this embodiment is not intended to limit the present invention. For example, when the transmission module 112 transmits the first 201211835, the second control signal or the third control signal to the computer, the computer moves the cursor to the first direction according to the first control signal, wherein the first The two-way 1 is but not limited to the simple left side. Or the computer depends on the fresh control _ number to make the Γ 速 speed f move to the first direction. Or the computer makes the cursor in the position according to the third control signal, but this embodiment is not intended to limit the present invention, and can be adjusted according to actual needs.

^Fig. 2A" is a circuit configuration of the first embodiment of the pressure sensing unit according to the present invention. The pressure sensing unit 1G4 may include an RC circuit 117, which may include a first variable resistor. When the operator applies pressure to the input member 1〇2, the first variable resistor 118 can change its resistance value ′ as the force of the input member 102 is greater than J to change the charging time required for the rainbow circuit m. For example, please refer to "2B" and "%", which are the results of the pressure intensity of the operator according to the "Phase 2A" and the output of the operator. It can be found from "2B" and "%" that i: the force sensing unit 1〇4 is large or small when the pressure applied by the operator to the input member (7) 2 is large, and the resistance value of the first variable resistor m is changed. Smaller or larger, which in turn makes the charging time required for the rc circuit ΐ7 larger or smaller. The pressure sensing unit 104 transmits the charging time curve (P [force L number II5) required by the RC circuit 117 to the microprocessor 1〇6, and the microprocessor (10) takes the charging time curve (ie, the pressure signal) required by the circuit 117. 115) converting into a pressure value (ie, charging time required by the RC circuit in) to compare with the first preset value (1) and the pre-valued value 114, thereby outputting the first control signal, the second control signal 201211835 or the The third control signal, but this embodiment is not intended to limit the present invention. For example, the RC circuit 117 may include a first variable capacitor 120 (as shown in "2D"), and "2D" is in accordance with the present invention. Referring to "1st diagram" and "2D diagram", the first variable capacitor 12A can change its capacitance according to the magnitude of the pressure intensity applied to the input member 102. The value, and thus the charging time required by the RC circuit 117, the microprocessor 106 compares the charging time required by the RC circuit 117 with the first preset value 113 and the second preset value 114, thereby outputting the first control signal, Second control signal or third control In addition to the circuit structure of the pressure sensing unit 104 described above, the pressure sensing unit 〇4 may further include a frequency generating circuit 122, and the frequency generating circuit 122 may include a variable inductor 124 (as shown in FIG. 3A). "Fig. 3A" is a schematic diagram of the second pass-through circuit structure of the pressure sensing unit IT according to the present invention. When the operator applies pressure to the input member 102, the variable inductance 124 can be input with the input. The strength of the device 1 〇 2 changes its power storage 'and changes the frequency generated by the fresh generation circuit 122. For example, 4 refers to the 3B map and the 3C map, respectively, according to the "3A map" The pressure sensing unit is a schematic diagram of the results of the pressure intensity output of the input member and the output of the operator. It can be found from "3B" and "3C" that when the pressure sensing unit author resigns (10) When the force intensity is large or small, the inductance value of the variable inductor 124 is variable or smaller, and the frequency generated by the frequency generating circuit 122 is increased or decreased. The pressure sensing unit 104 is The frequency curve generated by the frequency maternity generating circuit 122 (ie, The force signal 115) is transmitted to the microprocessor 106, and the microprocessor 1〇6 converts the fresh curve generated by the frequency generation 201211835 circuit 122 (ie, the pressure signal j!5) into a pressure value (ie, the frequency generation circuit 122 The generated frequency is compared with the first pre-value 113 and the second preset value 114 to output the first control signal, the second control signal or the second control signal, but the embodiment is not intended to limit the present invention. The present invention is a circuit structure diagram of a fourth embodiment of the force sensing unit according to the present invention. The frequency sensing unit 1〇4 may include a voltage circuit, and the voltage circuit m may include a second The resistance is 128, and the voltage circuit m is electrically connected to the analog digital converter 13 of the microprocessor. When the operator applies pressure to the input member Η) 2, the second variable resistor 128 can change its resistance value according to the magnitude of the force applied to the input member 1 〇 2, thereby changing the voltage output by the voltage circuit 126. For example, please refer to "4th Diagram" and "4C Diagram", which are the results of the pressure intensity of the input force applied to the operator by the Lili Sensing Unit according to Figure 4A, respectively. schematic diagram. From "4B" and "4C", it can be found that 'when the pressure sensing unit 104 applies the input member 1〇2 to the operator, the pressure is large or small, and the inductance of the second variable resistor 128 becomes smaller. Alternatively, the voltage output from the circuit 126 is increased or decreased. The pressure sensing unit 104 transmits the voltage curve outputted by the voltage circuit 126 (ie, the pressure city II5) to the microprocessor 1〇6, and the microprocessor touches the output of the voltage circuit I% (ie, the pressure signal 丨). After being processed by the ugly ratio converter (10), it is converted into a pressure value (ie, the voltage output by the power circuit 126) to be compared with the first preset value 113 and the second preset value 114, thereby outputting the first control signal, The second control signal scale control signal 'but this embodiment' is intended to limit the invention. The number of presets included in the 201211835 106 may be but not the second preset value 114). In this embodiment, the microprocessor is limited to two (ie, the first preset value m is adjusted according to actual needs). Please refer to "figure 5" and "figure 6", which are circuit blocks of another embodiment of the input device according to the present invention, and another embodiment of the input device according to the present invention is applied to a computer input device. The appearance structure diagram. The computer input equipment % is used to control the cursor (not marked). In this embodiment, the computer input equipment % is the mouse, but not limited to this. The computer input equipment 5〇 includes the input device fine The input device 200 includes an input member 2〇2, two pressure sensing units 2()4, a microprocessor 2〇6, a power supply 208, and a transmission module 212. In this embodiment, the input member 202 can be For example, but not limited to the two-way button, the two-way button has a pressing portion 20222, and the pressing portions 2021 and 2022 are respectively connected to each of the pressure sensing units 204. The microprocessor 206 is electrically connected to each of the pressure sensing units. 204, and electrically coupled to the transmission module 2 12. The power supply 2〇8 is electrically connected to each of the pressure sensing unit 2〇4, the microprocessor 206 and the transmission module 212. The transmission module 212 transmits the signal generated by the microprocessor 206 to A computer (not labeled) coupled to the computer input device 50. In this embodiment, the preset number of the presets included in the microprocessor 2〇6 may be, but not limited to, four (ie, the first preset value 218, the first The second preset value 219, the third preset value 220, and the fourth preset value 221) can be adjusted according to actual needs. When the operator applies the pressure intensity to the pressing portion 2021, the pressure connected to the pressing portion 2021 is connected. The sensing unit 204 is configured to receive the pressure received by the pressing portion 2021. After 12201211835, the pressure signal 215 is generated according to the pressure intensity received by the pressing portion 2021, and then the microprocessor 206 respectively sets the pressure signal 215 with the first preset. The value 218 and the second preset value 219 are compared to output a corresponding control signal 211. After the transmission module 212 receives the control signal 211, the transmission module 212 transmits the control signal 211 to the computer input device 50. Computer 'to make the computer transferable The control signal 211 transmitted by the module 212 performs relative operation. In this embodiment, the microprocessor 206 receives and converts the pressure signal 215 to the pressure value (not labeled) of Lu Ying and separates the pressure value with the first The preset value 218 and the second preset value 219 are compared to generate a comparison result, and the microprocessor 2〇6 outputs a relative first control signal (not labeled), a second control signal (not labeled), and a second according to the comparison result. a control signal (not shown), wherein the first preset value 219 can be greater than the first preset value 218, and when the pressure value is greater than the first preset value 218 and the second preset value 219, the microprocessor 2() 6 output first control 4 „ „ _ _ _ _ pressure value is greater than the first preset value 218 but less than the second preset value, the microprocessor H 206 outputs a second control signal, when the pressure value is less than the first preset value 218 and When the preset value is 219, the microprocessor outputs a third control signal, but this embodiment is not intended to limit the present invention. When the singular and sigma transmission module 212 sends the first control signal, the second control signal: or the third control __ to the computer, the computer moves the cursor and the speed in the direction of the 'the' - The direction may be, but is not limited to, the top of the cursor or the second control signal causes the cursor to move in a first direction at a slow speed. Or the computer moves the cursor to a specific position according to the third control signal, but the embodiment of the present invention is not intended to limit the present invention, and may be adjusted according to actual needs. When the author gives the pressure intensity to the pressing portion 2022, the pressure sensing early 204 provided at the pressing portion 2022 is used to receive the pressure applied to the pressing portion 2022. The pressure sensing unit 204 disposed at the pressing portion 2022 generates a pressure signal 217 according to the pressure intensity received by the pressing portion 2022, and the microprocessor 206 performs the pressure signal 217 with the third preset value 220 and the fourth preset value 2 21, respectively. Comparing and outputting the corresponding control signal 2丨3, the transmission module 212 transmits the control signal 213 to the computer coupled to the computer input device 5〇, so that the computer can perform relative to the control signal 213 transmitted by the transmission module 212. Operation. The microprocessor 206 receives and converts the pressure signal 217 to a corresponding pressure value (not labeled) and compares the pressure value with the third preset value 22〇 and the fourth preset value 221, respectively, to compare the result of the shyness, and the micro processing The device 2G6 outputs a relative fourth control signal (not labeled), a fifth control signal (not labeled), and a sixth control signal sharp (not labeled) according to the comparison result. The fourth preset value 221 may be greater than the third preset value 220. When the pressure value is greater than the third preset value 22〇 and the fourth preset value 221, the microprocessor 2 turns [the fourth control signal, When the pressure value is greater than the third preset value 220 but less than the fourth pre-destruction value 221, the microprocessor n 206 outputs a fifth control signal, when the pressure value is less than the second preset value 220 and the fourth preset value 221, The processor 2〇6 rotates the sixth control: No. 'But this embodiment is not intended to limit the invention. For example, when the transmission module commits the fourth control signal, the fifth control money or the sixth control signal to the computer, the computer controls the navigation to move in the second direction at a rapid speed, the towel, The second direction can be but the boots are below the 201211835 cursor. Or the computer moves the cursor to the second direction at a slow speed according to the fifth control signal. The computer moves the cursor to a specific position according to the sixth control signal, but this example is not intended to be used in the present invention, and can be adjusted according to actual needs of the domain. The input device disclosed in the present invention can be configured by the pressure sensing unit and the micro processing, so that the micro processing unit can output different control signals according to the dependence of the input unit. When the input member is a single button and the microprocessor includes two preset values, the micro processing material is divided into three parts by the author to diverge the force to output a corresponding control signal, that is, each input. The piece has three usage features. When the input member is a two-way button, the money processor includes four preset values, so that the microprocessor can divide the pressure of each pressing portion of the operator's tilting member into three classes to output a corresponding control signal, that is, Each of the input parts has six functions. Therefore, there is a problem that the conventional input member has a limited use function. Reference is made to "Stage 7", which is a circuit block diagram of a pen type mouse according to the present invention. The pen type mouse 3GG is used to transmit signals to the receiving device (not shown) to control the cursor (not shown), and the pen type mouse 3 (8) has a mouse mode and a digital pen mode. The pen type mouse 300 includes a pen tip 3〇3, a pressure sensing unit 3〇5, a microprocessor 3〇6, a switching module 307, a power supply, a displacement sensing unit 31〇, and a transmission module 312. In this implementation, the _mouse period may be but the secret wireless pen type mouse' receiving device may be, but is not limited to, a computer having a wireless receiver. The pressure sensing unit 305 is disposed on the pen tip 3〇3, and the microprocessor 3〇6 is electrically connected to the pressure sensing unit 3〇5, the switching module 3〇7, the displacement track sensing unit 31〇, and the transmission swap group 312. The power supply unit 〇8 is connected to the pressure sensing unit 〇5, the microprocessor 15 201211835 306, the displacement trajectory sensing unit 31G and the transmission module respectively to supply power to the force sensing unit 305 and the microprocessor 3 〇 6. Displacement sensing unit 31 传输 and transmission core, and 312. The switch board group 3〇7 and the microprocessor bird are used to switch the pen type mouse 3〇〇 in the π or digital pen mode. The displacement sensing unit 3 _ is used to detect the displacement of the pen type mouse _, and the transmission module 312 side transmits the signal generated by the microprocessor 306 to the pen type mouse 3_ in a wireless transmission manner. The receiving device is in the present embodiment; the microprocessor 3〇6 may include, but is not limited to, the first preset value 320 and the first preset value 322. This embodiment is not intended to limit the invention, and may be based on actual conditions. Demand adjustments. When the pen type mouse 3 is in the mouse mode, the operator causes the displacement track sensing unit 31 to detect the displacement track of the pen type mouse 3 (8) by moving the pen type mouse 300, thereby controlling the movement of the cursor. When the pen type mouse 300 is in the pen mode, it can be placed on the pen tip 303 through the pressure sensing unit, and the pressure intensity of the pen head 303 is changed, so that the receiving device performs relative operation, which is described in detail below. When the operator applies the grinding strength to the writing head 3〇3, the force sensing unit 3〇5 receives the force received by the writing head 303. The pressure sensing unit 3〇5 generates a house force signal 317 according to the strength of the force of the pen tip 3〇3, and the microprocessor 3〇6 performs the Qingli signal claw with the first preset value 320 and the second preset value 322. Comparing and outputting the corresponding control number 318, the transmission mode 312 transmits the control signal 318 f to the receiving device connected to the pen type mouse 3〇〇, so that the receiving device can transmit according to the transmission module 312. Control signal 318 operates in a relative manner. 201211835, wherein the microprocessor 306 receives and converts the pressure signal 317 to a corresponding pressure value (not labeled) and separates the pressure value with the first preset value 320 and the second preset value 322, respectively.

Comparing to produce a comparison result, the microprocessor 306 outputs a relative first control signal (not labeled), a second control signal (not labeled), and a third control apostrophe (not labeled) based on the comparison result. Wherein the second preset value 322 can be greater than the first preset value 320, and when the pressure value is greater than the first preset value 320 and the second preset value 322, the microprocessor 3〇6 outputs the first control signal, when When the pressure value is greater than the first preset value 32 〇 but less than the second preset value 322, the microprocessor 306 outputs the second control signal. When the pressure value is less than the first preset value 320 and the second preset value 322, the micro The processor 3〇6 outputs a third control signal, but this embodiment is not intended to limit the present invention. For example, when the pen type transmits the first control signal, the second control signal or the third control (four) to the receiving device in a wireless manner, the receiving device makes the moving track of the cursor (not labeled) thick according to the first control signal. The receiving device is based on the second control letter (four) standard (not marked)_pure_fine, and the receiving device causes the cursor (not labeled) to select the current location according to the third control signal, but the present embodiment also defines the present invention as Adjusted according to Wengji. In the present embodiment, the schematic diagram of the circuit structure of the pressure sensing unit 〇5 can be used as a "pen 洲 洲", "3A" or "4A _ _, (4) By the setting of the pressure sensing unit and the microprocessor, the operation of the pressure-sensitive vocabulary, the control of the pressure, the operation of the sample __ 17 201211835, and the pen-type slip disclosed by the present invention The mouse replaces the operational function of the digital pen on the tablet and is not limited by the working area of the tablet. Although the present invention has been disclosed above in the foregoing preferred embodiments, it is not intended to limit the invention to any skilled artisan. The invention may be modified and retouched without departing from the spirit and scope of the present invention. Therefore, the scope of patent protection of the present invention shall be subject to the definition of the specification of the specification. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 2A is a circuit diagram of a first embodiment of a pressure sensing unit according to the present invention. FIG. 2A is a pressure sense according to FIG. 2A. Measuring unit to operator Fig. 2C is a schematic diagram showing the result of outputting the pressure intensity of the pressure sensing unit according to Fig. 2A when the pressure is applied to the input member according to Fig. 2A. Fig. 2D is a diagram showing the result of the pressure intensity of the pressure sensing unit according to Fig. 2A. The circuit structure of the second embodiment of the pressure sensing unit according to the present invention is not intended. The first embodiment is a circuit configuration of the third embodiment of the pressure sensing unit according to the present invention. The pressure sensing unit of the figure is a schematic diagram of the result of the output when the pressure intensity of the input member is large. The 3C figure is the pressure intensity of the input force applied to the operator by the Lili sensing unit according to the 帛3A diagram. 4118A is a circuit structure diagram of a fourth embodiment of the pressure sensing unit according to the present invention. FIG. 4B is a pressure sensing unit according to FIG. The result of the output when the pressure intensity of the input member is large is shown in Fig. 4C as a result of the output of the pressure sensing unit according to Fig. 4A when the pressure intensity of the input member is given by the operator. 5 is a circuit block diagram of another embodiment of an input device according to the present invention. Fig. 6 is a schematic diagram showing the appearance of a computer input device according to another embodiment of the input device according to the present invention. Circuit block diagram of an embodiment of the pen type mouse of the present invention. [Description of main component symbols] 50 computer input equipment 100, 200 input device 102'202 input member 2021 ' 2022 pressing place 104, 204, 305 pressure sensing unit 106 , 206, 306 microprocessor 108, 208, 308 power supply 111, 211, 213, 318 control signal 112, 212, 312 transmission module 113, 218, 320 first preset value 114, 219, 322 second pre Set value 19 201211835 115, 215, 217, 317 117 118 120 122 124 126 128 130 220 221 300 303 307 310 pressure signal RC circuit first variable resistance first variable capacitance frequency generating circuit variable inductance voltage circuit second Variable resistance analog digital converter third preset value fourth preset value pen type mouse pen head switching module displacement tracking sensing unit

Claims (1)

201211835 VII. Patent application scope: 1. An input device comprising: an input member; - a pressure sensing unit "set" on the input member, receiving the pressure of the employee member; and - a microprocessor, electrically connected to The pressure sensing unit includes a plurality of preset values; wherein, the pressure of the pressure element is generated by the pressure of the pressure element of the pressure element, and the microprocessor sends the pressure signal to the preset value A comparison is performed to output a corresponding control signal. 2. The input device of claim 1, wherein the microprocessor comprises - a first pre-value and a preset value - the microprocessor receives and converts the pressure signal to a corresponding - pressure value And comparing the pressure value with the first preset value and the second preset value, respectively, to output a relative-first control signal, a second control signal, and a third control signal, wherein the first The preset value is greater than the first preset value: when the pressure value is greater than the first preset value and the second preset value, the microprocessor outputs the first control signal, when the pressure value is greater than the first When the preset value is less than the second preset value, the microprocessor rotates the second control signal, and when the pressure is at the first pre-wei and the second preset value, the processor wheel This control signal is output. 3. The input device, as described in the claim item, the radiation sensing unit comprises a rainbow circuit 4RC circuit comprising a first variable capacitor or a first variable resistor. 21 201211835 4. The input device of claim i, wherein the pressure sensing unit comprises a voltage output circuit, the microprocessor comprising an analog-to-digital converter, the voltage output circuit comprising - a second variable a resistor that transmits the pressure signal to the analog to digital converter. 5. The input device of claim i, wherein the pressure sensing unit comprises a frequency generating circuit, the frequency generating circuit comprising a variable inductance. 6. A pen type mouse, wherein the pen type mouse further comprises: a displacement tracking sensing unit; a head; a pressure sensing unit is disposed on the pen head, and the pressure sensing unit receives the pen head And a microprocessor-electrical connection between the displacement trajectory sensing unit and the forcing sensing unit and including a plurality of preset values; wherein the displacement trajectory senses the single mouse The trajectory is moved, and the force sensing unit generates a dust signal according to the force received by the pen tip, and the microprocessor compares the reliance signal with the preset values to output a corresponding “control signal”. 7. The pen-type mouse according to claim 6, wherein the microprocessor includes a -first pre-sigh value and - a -pre-missing - the microprocessor receives and converts the Lay signal to the appropriate - dust force And comparing the force value with the first preset value and the second preset value, respectively, to output a relative first control Wei, a second control: signal, and a second control age number 'shooting' The second preset value is greater than the first preset value, 22 201211835, when the pressure value is greater than the first preset value and the second preset value, the microprocessor outputs the first control 彳§号' When the pressure value is greater than the first preset value but less than the second preset value, the microprocessor outputs the second control signal, when the pressure value is less than the first preset value and the second preset value The microprocessor outputs the third control signal. 8. The pen type mouse as claimed in claim 6, wherein the pressure sensing unit comprises a circuit ‘the RC circuit comprises a first variable capacitor or a first variable resistor. 9. The pen-type mouse of claim 6, wherein the pressure sensing unit comprises a voltage output circuit, the processor comprising an analog-to-digital converter, the dragon output circuit comprising a second variable resistor. 10. The pen-type mouse of claim 6, wherein the pressure sensing unit comprises a frequency generating circuit comprising a variable inductance. twenty three