CN110083256B - Method for detecting weight of balancing weight arranged on mouse and mouse device thereof - Google Patents

Abstract

The invention discloses a method for detecting the weight of a balancing weight arranged on a mouse and a mouse device thereof, wherein the method comprises the steps of firstly executing circuit configuration, arranging a central electrode and at least one tested electrode on a balancing weight, wherein the positions and the number of the tested electrodes correspond to the weight of the balancing weight, and arranging a plurality of detection electrodes electrically connected with a control module on a balancing weight groove of the mouse; then executing an information storage step, wherein the control module stores weight information for providing the weight of the balancing weight; then, a counterweight setting step is executed, and the counterweight is arranged in the counterweight groove; finally, executing a weight analysis step, wherein the control module obtains the weight of the balancing weight according to the positions and the number of the electrodes to be tested; the invention can make the mouse device have more quantity selection, the position of the balancing weight can be fixed without arranging an additional fixing member, and the balancing weight condition and the gravity center state of the mouse main body can be obtained through the model of the mouse main body stored in the computer.

Description

Method for detecting weight of balancing weight arranged on mouse and mouse device thereof

Technical Field

The present invention relates to a method for detecting weight of a counterweight, and more particularly to a method for detecting weight of a counterweight disposed on a mouse and a mouse device thereof.

Background

Because of the convenience brought by the present computer, the industry such as game playing is gradually dependent on the computer, and the peripheral devices of the computer such as a mouse and a keyboard must be improved and modified according to the needs of the game player.

In addition to manipulating cursor displacement and pointing, the sensitivity of a conventional mouse is most important when moving a cursor. In order to achieve good results in games, the general game players have high requirements on the sensitivity of the cursor of the mobile mouse, and besides the sensitivity of the cursor can be improved in the aspects of traditional track balls or optical sensing and other hardware devices, the operation hand feeling of the players on the mouse is one of factors affecting the sensitivity.

Referring to fig. 1, taiwan patent application No. 106101285 discloses a gravity center adjustable mouse, which comprises a mouse body 11 and a weight seat 12 disposed on the mouse body 11, wherein the position of the weight seat 12 is adjustable to adjust the gravity center of the mouse body 11.

Referring to fig. 2 and 3, the weight base 12 is provided with at least one weight groove 13 for providing at least one weight 14, wherein the weight 14 is provided with electrodes for providing a computer to confirm the weight of the weight 14 provided in the mouse body 11.

However, the known technology simply uses the spacing distance between the electrodes on the balancing weight or sets a resistor on the balancing weight to make the computer determine the weight of the balancing weight, but in a limited setting area, the setting position of the electrodes is limited, and the weight distinction achieved by simply using the spacing distance or the resistor is limited, so that the selectable weight of the balancing weight is limited.

Therefore, how to increase the weight selectivity of the balancing weight, so that the operator can have more weight to adjust the center of gravity of the mouse, so that the operator can control the computer more easily, and the speed of controlling the computer can be increased, which is a goal of urgent need of related technicians.

Disclosure of Invention

Accordingly, an object of the present invention is to provide a method for detecting the weight of a counterweight disposed on a mouse, which is suitable for detecting the weight of at least one counterweight disposed on a mouse body, wherein the mouse body is provided with at least one counterweight slot for disposing the counterweight, so as to adjust the center of gravity of the mouse body.

Firstly, the circuit configuration step is executed, the balancing weight is provided with a central electrode and at least one tested electrode electrically connected with the central electrode, the positions and the number of the tested electrodes correspond to the weight of the balancing weight, and the balancing weight groove is provided with a plurality of detection electrodes electrically connected with a control module.

And then executing the information storage step, wherein the control module stores weight information so as to provide the control module to judge the weight of the balancing weight.

And then executing the counterweight setting step, wherein the counterweight is arranged in the counterweight groove, and the control module obtains the positions and the number of the detected electrodes by the plurality of detection electrodes.

And finally, executing the step of analyzing the weight, and analyzing the positions and the number of the tested electrodes by the control module to obtain the weight of the balancing weight.

In another technical means of the present invention, the weight tank has a detecting surface, the weight has a detected surface, the plurality of detecting electrodes are disposed on the detecting surface in the circuit configuration step, and the central electrode and the detected electrode are disposed on the detected surface.

In another technical means of the present invention, the detecting surface and the detected surface are approximately circular, and in the circuit configuration step, the central electrode is disposed at the center of the detected surface, and the detected electrode is disposed on the detected surface in a circular ring with the central electrode as a center.

In the circuit configuration step, the balancing weight further has at least one binary counter electrode setting area for setting the tested electrodes, and the number and positions of the tested electrodes are set in the binary counter electrode setting area in a binary counter manner.

In another aspect of the present invention, in the step of storing information, the weight information is provided to the weight of the weight block in a manner corresponding to binary numbers.

The other technical means of the invention is that in the step of analyzing the weight, the control module obtains the position and the number of the tested electrodes and then compares the weight information in a binary number mode to obtain the weight of the balancing weight.

Another objective of the present invention is to provide a mouse device, which is suitable for the above method for detecting the weight of a counterweight disposed on a mouse, and includes a mouse unit, a counterweight unit, a detecting unit and a tested unit.

The mouse unit comprises a mouse main body.

The counterweight unit comprises at least one counterweight groove arranged on the mouse main body and at least one counterweight block which is detachably arranged in the counterweight groove.

The detecting unit comprises a plurality of detecting electrodes arranged on the counterweight groove and a control module electrically connected with the detecting electrodes.

The tested unit comprises a central electrode arranged on the balancing weight and at least one tested electrode electrically connected with the central electrode, wherein the positions and the number of the tested electrodes correspond to the weight of the balancing weight.

When the balancing weight is arranged in the balancing weight groove, the control module obtains the positions and the number of the detected electrodes by the plurality of detecting electrodes so as to obtain the weight of the balancing weight.

The counterweight tank has a detection surface, the counterweight has a detected surface, the plurality of detection electrodes are arranged on the detection surface, and the central electrode and the detected electrodes are arranged on the detected surface.

The other technical means of the invention is that the counterweight groove and the counterweight block are in cylindrical shape, the detecting surface and the detected surface are in round shape, the central electrode is arranged at the center of the detected surface, and the detected electrode is arranged on the detected surface in a circular ring with the central electrode as a circle center.

The weight block also has at least one binary number electrode setting area for setting the tested electrodes, and the number and positions of the tested electrodes are set in the binary number electrode setting area in binary number mode, so that the weight of the weight block is obtained in binary number mode after the control module obtains the positions and the numbers of the tested electrodes.

The invention has the beneficial effects that at least one binary number electrode setting area is virtually arranged on the detected surface of the balancing weight, the detected electrode is arranged in the binary number electrode setting area in a binary number mode in comparison with the weight of the balancing weight, so that the control module obtains the weight of the balancing weight in the binary number mode after detecting the number and the setting position of the detected electrode.

Drawings

FIG. 1 is a schematic diagram of an apparatus for adjusting the center of gravity of a mouse in accordance with taiwan patent application No. 106101285;

FIG. 2 is a schematic diagram of a conventional counterweight housing;

FIG. 3 is a schematic diagram of a device illustrating a conventional counterweight;

FIG. 4 is a schematic diagram of a mouse device according to a preferred embodiment of the present invention;

FIG. 5 is a schematic diagram of the apparatus illustrating a weight trough and a weight in the preferred embodiment;

FIG. 6 is a schematic diagram illustrating the binary counter electrode arrangement regions of the preferred embodiment;

FIG. 7 is a schematic circuit diagram illustrating the circuit connection of the balancing weight of the preferred embodiment when the balancing weight is placed in the balancing weight slot;

FIG. 8 is a flow chart illustrating the method of detecting the weight of the mouse-mounted weight in the preferred embodiment.

Symbol description in the drawings:

11. a mouse body; 12. a counterweight base; 13. a counterweight groove; 14. balancing weight; 2. a mouse unit; 21. a mouse body; 3. a counterweight unit; 31. a counterweight groove; 311. a detection surface; 32. balancing weight; 321. a surface to be measured; 322. a binary counter electrode setting area; 323. a central region; 4. a detection unit; 41. a detection electrode; 42. a control module; 5. a unit under test; 51. a center electrode; 52. a measured electrode; 901 to 904.

Detailed Description

The features and aspects of the present invention will become apparent from the following detailed description of preferred embodiments, which is to be read in connection with the accompanying drawings.

Referring to fig. 4 and 5, a preferred embodiment of a mouse device according to the present invention includes a mouse unit 2, a counterweight unit 3, a detecting unit 4 and a tested unit 5.

The mouse unit 2 includes a mouse main body 21 for operating the computer, and a computer operator can operate the computer by using the mouse main body 21, so that the mouse for operating the computer is widely used in commercial products and will not be described in detail. In practice, the mouse body 21 can be used in the mouse device with adjustable center of gravity disclosed in the prior art, and should not be limited to the example of the preferred embodiment.

Referring to fig. 6 and 7, the counterweight unit 3 includes at least one counterweight groove 31 disposed on the mouse body 21, and at least one counterweight 32 detachably disposed on the counterweight groove 31.

In the preferred embodiment, the weight groove 31 and the weight 32 are generally cylindrical, and the weight groove 31 and the weight 32 are matched in size and shape, so that the weight 32 is detachably disposed in the weight groove 31. In practical implementation, the weight 32 and the weight slot 31 may be provided with other cylindrical shapes, so that the weight 32 may be closely inserted into the weight slot 31, which should not be limited thereto.

The weight slot 31 has a detecting surface 311, the weight 32 has a detected surface 321, and at least one binary counter electrode arrangement area 322, in the preferred embodiment, the detecting surface 311 is a circular bottom surface of the weight slot 31, the detected surface 321 is a circular bottom surface of the weight 32, and when the weight 32 is inserted into the weight slot 31, the detected surface 321 abuts against the detecting surface 311. In practical implementation, the detected surface 321 may be any surface of the counterweight 32, and the detecting surface 311 may be any surface of the counterweight slot 31 and matched with the detected surface 321, which should not be limited thereto.

The detecting unit 4 includes a plurality of detecting electrodes 41 disposed in the counterweight groove 31, and a control module 42 electrically connected to the detecting electrodes 41, wherein the control module 42 can transmit information to a computer so that the information of the counterweight 32 is displayed on the computer.

The tested unit 5 includes a central electrode 51 disposed on the balancing weight 32, and at least one tested electrode 52 electrically connected to the central electrode 51, where the positions and the number of the tested electrodes 52 correspond to the weight of the balancing weight 32.

Preferably, the plurality of detecting electrodes 41 are disposed on the detecting surface 311, the central electrode 51 and the detected electrode 52 are disposed on the detected surface 321, and the disposed positions of the plurality of detecting electrodes 41 are matched with the binary number electrode disposed area 322, so that the control module 42 obtains the number and positions of the detected electrodes 52.

The binary counter electrode arrangement area 322 is a region virtual to the tested surface 321, and in the preferred embodiment, is a plurality of annular regions formed by the center of the tested surface 321, and the binary counter electrode arrangement areas 322 are spaced apart from each other for arranging the tested electrode 52.

In the preferred embodiment, the central electrode 51 is disposed at the center of the tested surface 321, that is, at the center of the tested surface 321, the tested electrode 52 is disposed around the tested surface 321 with the central electrode 51 as the center, and the number and positions of the tested electrodes 52 are set in the binary counter electrode setting area 322 in a binary counter manner against the weight of the balancing weight 32.

When the weight block 32 is disposed in the weight slot 31, the control module 42 obtains the positions and the number of the detected electrodes 52 by the plurality of detecting electrodes 41, obtains the weight of the weight block 32 in a binary counting manner, and transmits the information of the weight block 32 to a computer so as to enable an operator to know the number, the positions and the weight of the weight block 32 in the mouse body 21.

Referring to fig. 8, the method for detecting the weight of the weight block disposed on the mouse according to the preferred embodiment is suitable for detecting the weight of at least one weight block 32 disposed on a mouse body 21, wherein the mouse body 21 is provided with at least one weight slot 31 for disposing the weight block 32 for adjusting the center of gravity of the mouse body 21.

The method for detecting the weight of the balancing weight arranged on the mouse comprises a circuit configuration step 901, an information storage step 902, a balancing weight setting step 903 and a weight analysis step 904.

Firstly, the circuit configuration step 901 is performed, the weight block 32 is provided with a central electrode 51 and at least one tested electrode 52 electrically connected with the central electrode 51, the positions and the number of the tested electrodes 52 correspond to the weight of the weight block 32, and the weight slot 31 is provided with a plurality of detecting electrodes 41 electrically connected with a control module 42.

The plurality of detecting electrodes 41 are disposed on the detecting surface 311, and the central electrode 51 and the detected electrode 52 are disposed on the detected surface 321. The central electrode 51 is disposed at the center of the tested surface 321, and the tested electrode 52 is disposed around the tested surface 321 with the central electrode 51 as a center.

The weight 32 further has at least one binary-number electrode arrangement region 322 for arranging the electrodes 52, and the arranged number and positions of the electrodes 52 are arranged in the binary-number electrode arrangement region 322 in a binary-number manner.

Referring back to fig. 6, a central area 323 is disposed at the center of the tested surface 321, the central electrode 51 is disposed in the central area 323, and the binary counter electrode disposing area 322 is disposed around the central area 323, in the preferred embodiment, three annular areas are used as the binary counter electrode disposing areas 322, each binary counter electrode disposing area 322 is spaced apart from each other, and in practical implementation, the number of the binary counter electrode disposing areas 322 should not be limited to this.

Referring back to fig. 7, when one of the binary counter electrode arrangement areas 322 is provided with a measured electrode 52, the measured electrode 52 is electrically shorted to the weight 32 provided with the central electrode 51, preferably, a shorted wire is provided on the weight 32 to enable the control module 42 to form a power loop through the central electrode 51 and the measured electrode 52, and the inner most binary counter electrode arrangement area 322 is not provided with a measured electrode 52 in the three binary counter electrode arrangement areas 322 of the preferred embodiment.

Then, the information storage step 902 is executed, where the control module 42 stores a weight information to provide the control module 42 with a determination of the weight of the balancing weight 32. The weight information is provided in a binary numbered manner to provide the weight of the weight 32. In the preferred embodiment, the weight information is stored in eight sets of information, 000, 001, 010, 011, 100, 101, 110, 111, each set corresponding to a weight, by means of three binary counter electrode placement areas 322.

For example, 000 is 0g,001 is 5g,010 is 10g,011 is 15g,100 is 20g,101 is 25g,110 is 30g, and 111 is 35g, and in practice, other amounts may be used, and should not be limited thereto, as compared with the binary count of the weight information.

Then, the weight setting step 903 is performed, the weight 32 is set in the weight slot 31, and the control module 42 obtains the positions and the number of the detected electrodes 52 through the plurality of detecting electrodes 41. Since the setting positions of the plurality of detecting electrodes 41 are set in the binary counter electrode setting area 322 according to the binary counter manner, the control module 42 can know that the inner-most binary counter electrode setting area 322 is not provided with the measured electrode 52 in the preferred embodiment through the condition that the central electrode 51 is electrically connected with the measured electrode 52.

Finally, the analyzing weight step 904 is performed, and the control module 42 analyzes the position and number of the electrodes 52 to obtain the weight of the balancing weight 32. After the control module 42 obtains the positions and the number of the electrodes 52 to be measured, the weight information is compared in a binary number manner to obtain the weight of the balancing weight 32.

In a preferred embodiment, the binary counter electrode setting area 322 where the measured electrode 52 is not set is denoted by 0, and the binary counter electrode setting area 322 where the measured electrode 52 is set is denoted by 1, so that the control module 42 can obtain a binary value of 011 by the set number and position of the measured electrode 52, and can obtain the weight of the balancing weight 32 by comparing the weight information.

It should be noted that, the weight of the weight block 32 is limited by the area of the measured surface 321 of the weight block 32 by simply using the setting position in the early stage, for example, when the area of the measured surface 321 is only 3 sets of areas, only 3 sets of weights can be obtained in the early stage, but the preferred embodiment can obtain 8 sets of weights by using the three sets of binary number electrode setting areas 322.

For another example, when the area of the tested surface 321 is only provided with 4 groups of areas, only 4 groups of weights can be obtained in early stage, but 16 groups of weights can be obtained in a binary number manner, the method for detecting the weight of the mouse-mounted balancing weight disclosed by the invention can actually greatly improve the weight selection.

The inventors emphasized that, since the weight 32 of the preferred embodiment is cylindrical, the placement angle of the weight 32 cannot be fixed when the weight 32 is placed in the weight slot 31, and therefore, the plurality of electrodes under test 52 are disposed concentrically, so that the electrodes under test 52 can be electrically connected with the plurality of detecting electrodes 41 when the weight 32 is disposed in the weight slot 31 at different placement angles. In practice, the plurality of detecting electrodes 41 are arranged concentrically to correspond to the center electrode 51 and the measured electrode 52. In addition, a positioning member may be disposed in the weight slot 31 to fix the angle of the weight 32 in the weight slot 31, and the detecting electrode 41 or the detected electrode 52 is not required to be disposed in a concentric circle.

When the weight 32 is a square column and the shape of the weight slot 31 is matched with the weight 32, the position of the weight 32 in the weight slot 31 will be fixed, and the measured electrode 52 can be disposed on the measured surface 321 in a binary manner only by virtualizing the position of the binary electrode disposing area 322 on the measured surface 321, without disposing in a concentric circle manner, so that the control module 42 obtains the number and position of the measured electrode 52, and further obtains the weight of the weight 32 in a binary manner.

As can be seen from the above description, the method for detecting the weight of the weight block installed on the mouse and the mouse device thereof of the present invention have the following effects:

1. with more weight choices:

since the mouse body 21 is small, the weight 32 is smaller, so the number of electrodes that can be disposed on the measured surface 321 of the weight 32 is limited, and the present invention can create more weight choices by disposing the electrodes in the binary number manner in the binary number electrode disposing area 322.

2. The position of the balancing weight does not need to be fixed:

when the weight block 32 is circular, the measured electrode 52 is disposed on the measured surface 321 in concentric circles, so that the weight block 32 is disposed on the weight slot 31 at any angle, and the detecting electrode 41 can be electrically connected with the measured electrode 52 without a fixing member for fixing the position of the weight block 32.

3. Obtaining the center of gravity of the mouse:

after the control module 42 transmits the weight information of the weight block 32 disposed in the mouse main body 21 to the computer, it is matched with other sensing systems in the mouse main body 21 to confirm the position of the weight block 32, and the program can calculate the weight status and the gravity center status of the mouse main body 21 according to the model of the mouse main body 21 stored in the computer.

In summary, the present invention presets the plurality of binary counter electrode setting areas 322 on the tested surface 321, and a central area 323, the central area 323 sets the central electrode 51, the tested electrode 52 is matched with the weight of the balancing weight 32, and is set in the plurality of binary counter electrode setting areas 322 in a binary counter manner, the control module 42 obtains the number and the positions of the tested electrode 52 through the plurality of detecting electrodes 41, so as to obtain the binary counter value represented by the tested electrode 52, and then the weight of the balancing weight 32 can be obtained by comparing the weight information, finally, the control module 42 transmits the weight of the balancing weight 32 to the computer, so that an operator can know the gravity center and the weight information of the used mouse device, and the purpose of the present invention can be achieved.

The foregoing description is only illustrative of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, i.e., the invention is not limited to the specific embodiments described herein, but is to be accorded the full scope of the claims.

Claims (2)

1. The method for detecting the weight of the balancing weight arranged on the mouse is suitable for detecting the weight of at least one balancing weight arranged on a mouse main body, the mouse main body is provided with at least one balancing weight groove used for arranging the balancing weight and used for adjusting the gravity center of the mouse main body, and the balancing weight groove and the balancing weight are cylindrical and matched in size and shape, and is characterized in that the method for detecting the weight of the balancing weight arranged on the mouse comprises the following steps:

the method comprises a circuit configuration step, a counter weight and a control module, wherein the counter weight is provided with a circular detected surface, a central electrode and at least one detected electrode electrically connected with the central electrode, the central electrode is arranged in the center of the detected surface, the detected electrode is arranged on the detected surface in a circular ring mode by taking the central electrode as a center, the positions and the number of the detected electrodes correspond to the weight of the counter weight, the counter weight is also provided with at least one binary number electrode setting area for setting the detected electrode, the setting number and the positions of the detected electrodes are arranged in the binary number electrode setting area in a binary number mode, the counter weight groove is provided with a circular detection surface, the detection surface of the counter weight groove is provided with a plurality of detection electrodes electrically connected with the control module, and the setting positions of the detection electrodes are matched with the binary number electrode setting area;

an information storage step, the control module stores weight information, the weight information is corresponding to the binary number mode to provide the control module to judge the weight of the balancing weight;

a counterweight setting step, wherein the counterweight is arranged in the counterweight groove, and the control module obtains the positions and the number of the detected electrodes by the plurality of detecting electrodes; and

And a weight analysis step, wherein the control module obtains the positions and the number of the detected electrodes and then compares the weight information in a binary number mode to obtain the weight of the balancing weight.

2. A mouse device adapted for use in the method of claim 1 for detecting the weight of a mouse-mounted counterweight, comprising:

a mouse unit including a mouse body;

the counterweight unit comprises at least one counterweight groove arranged on the mouse main body and at least one counterweight block detachably arranged on the counterweight groove, wherein the counterweight groove and the counterweight block are cylindrical and matched in size and shape, the counterweight groove is provided with a circular detection surface, and the counterweight block is provided with a circular detected surface;

the detection unit comprises a plurality of detection electrodes arranged on the counterweight groove and a control module electrically connected with the plurality of detection electrodes, and the plurality of detection electrodes are arranged on the detection surface; and

The measured unit comprises a central electrode arranged on the balancing weight and at least one measured electrode electrically connected with the central electrode, wherein the central electrode is arranged in the center of the measured surface, the measured electrode is arranged on the measured surface in a circular ring with the central electrode as a circle center, and the positions and the number of the measured electrodes correspond to the weight of the balancing weight;

the balancing weight is provided with at least one binary number electrode setting area for setting the tested electrodes, the setting number and the positions of the tested electrodes are set in the binary number electrode setting area in a binary number mode, the setting positions of the plurality of detection electrodes are matched with the binary number electrode setting area, and when the balancing weight is set in the balancing weight groove, the control module obtains the weight of the balancing weight in a binary number mode after obtaining the positions and the numbers of the tested electrodes through the plurality of detection electrodes.