CN107132939B - Pairing method of wireless charging mouse - Google Patents

Abstract

The invention provides a pairing method of a wireless charging mouse, which is suitable for a pairing mode of the wireless charging mouse and an electronic device, and comprises the following steps: the wireless charging mouse receives the electromagnetic energy transmitted by the charging plate; the wireless charging mouse establishes a pairing transmission channel according to the electromagnetic energy and a preset pairing address, and transmits a first pairing signal to the electronic device; the electronic device transmits a first response signal to the wireless charging mouse, and the electronic device generates a first communication address; the wireless charging mouse transmits the first pairing signal to the electronic device again; the electronic device receives the first pairing signal transmitted by the wireless charging mouse again, and transmits a second response signal to the wireless charging mouse; and storing the first communication address by the wireless charging mouse and entering a data transmission mode. The pairing method can enable a user to quickly establish a wireless connection channel within a short time when the wireless charging mouse is placed on the charging panel for charging, and the trouble of setting a driving program is avoided.

Description

Pairing method of wireless charging mouse

Technical Field

The invention relates to a wireless charging mouse, in particular to a wireless charging mouse with an automatic pairing function.

Background

The main purpose of the mouse is to facilitate a user to control a cursor on a display screen, and the movement of the cursor is correspondingly output by controlling the movement amount and the movement direction of the mouse. In recent years, the movement of the mouse is detected in an optical manner to gradually replace the conventional mechanical roller detection mouse, so that the accuracy of detecting the movement of the mouse is increased in an optical manner. As wireless charging technology becomes more mature, the existing technology applies wireless charging mode to the mouse to replace the traditional mouse that needs to be connected with power source in a wired manner. However, in the prior art, the connection between the wireless mouse and the computer device is too cumbersome, for example, the product serial number is authenticated in a wireless manner by inputting a driver.

Disclosure of Invention

The invention provides a pairing method of a wireless charging mouse, which aims to solve the problem that the connection mode between the wireless mouse and a computer device is too complicated in the prior art.

The embodiment of the invention provides a pairing method of a wireless charging mouse, which is suitable for a pairing mode of the wireless charging mouse and an electronic device, and the pairing method comprises the following steps: receiving the electromagnetic energy transmitted by the charging plate by the wireless charging mouse; establishing a pairing transmission channel by the wireless charging mouse according to the electromagnetic energy and a preset pairing address, and transmitting a first pairing signal to the electronic device by the wireless charging mouse through the pairing transmission channel; after the electronic device receives a first pairing signal transmitted by the wireless charging mouse, the electronic device transmits a first response signal to the wireless charging mouse through the pairing transmission channel, and the electronic device generates a first communication address; after the wireless charging mouse receives the first response signal transmitted by the electronic device, the wireless charging mouse transmits the first pairing signal to the electronic device again through the pairing transmission channel; after the electronic device receives the first pairing signal transmitted by the wireless charging mouse again, the electronic device transmits a second response signal to the wireless charging mouse through the pairing transmission channel; and storing the first communication address by the wireless charging mouse and entering a data transmission mode.

Based on the technical scheme, the invention has the technical effects that:

the wireless charging mouse is triggered by the electromagnetic energy emitted by the charging plate to generate a transmission channel, and whether the wireless charging mouse and the electronic device enter a data transmission mode or not is verified by the pairing signal and the response signal, so that the wireless connection channel can be quickly established by a user within a short time when the wireless charging mouse is placed on the charging plate for charging, and the trouble of setting a driving program is avoided.

For a better understanding of the nature and technical content of the present invention, reference should be made to the following detailed description of the invention, taken in conjunction with the accompanying drawings, which are set forth to illustrate, but are not to be construed to limit the scope of the invention.

Drawings

Fig. 1A is a flowchart of a pairing method for a wireless charging mouse according to an embodiment of the present invention.

Fig. 1B is a flowchart of a pairing method for a wireless charging mouse according to an embodiment of the present invention.

Fig. 2 is an appearance schematic diagram of pairing of the wireless charging mouse according to the embodiment of the invention.

Fig. 3A is a flowchart of a pairing method for a wireless charging mouse according to an embodiment of the present invention.

Fig. 3B is a flowchart of a pairing method of a wireless charging mouse according to an embodiment of the present invention.

Fig. 4A is a flowchart of a pairing method for a wireless charging mouse according to an embodiment of the present invention.

Fig. 4B is a flowchart of a pairing method of a wireless charging mouse according to an embodiment of the present invention.

Description of reference numerals:

s101, S301, S401: judging whether a transmission channel is established by the wireless charging mouse

S102, S302, S402: data transmission

S103, S303, S403: enter into pairing mode

S105, S305, S405: receiving electromagnetic energy by a wireless charging mouse

S110, S310, S410: the wireless charging mouse establishes a pairing transmission channel according to electromagnetic energy and transmits a first pairing signal to the electronic device

S115, S315, S415: determining, by an electronic device, whether to receive a first pairing signal

S120, S320, S420: the electronic device transmits a first response signal to the wireless charging mouse through the pairing transmission channel

S125, S325, S425: judging whether a first response signal is received by the wireless charging mouse

S128, S328, S428: judging whether to continuously receive electromagnetic energy by the wireless charging mouse

S130, S330, S430: the wireless charging mouse transmits the first pairing signal to the electronic device again

S135, S335, S435: judging whether the first pairing signal is received again by the electronic device

S140, S340, S440: transmitting a second response signal from the electronic device to the wireless charging mouse

S145, S345 and S445: enter a data transfer mode

205: wireless charging mouse

210: charging panel

215: electronic device

S307: judging whether the electromagnetic energy is higher than the preset electromagnetic energy by the wireless charging mouse

S309 and S355: judging whether the preset time is exceeded or not by the wireless charging mouse

S350: judging whether the electromagnetic energy is lower than the preset electromagnetic energy by the wireless charging mouse

S360: leaving data transfer mode

S426: judging whether the transmitted first pairing signal reaches a retry upper limit value by the wireless charging mouse

S427: replacement of pairing addresses by wireless charging mouse

S436: the electronic device judges whether the first pairing signal is completely received

S437: the electronic device determines whether the first pairing signal is transmitted from a pairing address in the pairing transmission channel

S438: the electronic device prepares a recovery packet and stores the recovery packet in a FIFO register

S441: judging whether the second response signal is completely received by the wireless charging mouse

S442: wireless charging mouse receives reply packet transmitted by electronic device

S443: the wireless charging mouse establishes a first transmission channel according to the reply packet

Detailed Description

Referring to fig. 1A and fig. 2, fig. 1A is a flowchart illustrating a pairing method of a wireless charging mouse according to an embodiment of the present invention, and fig. 2 is an appearance diagram illustrating pairing of the wireless charging mouse according to the embodiment of the present invention.

In step S101, it is determined whether a transmission channel has been established by the wireless charging mouse. If the determination in step S101 is yes, the process proceeds to step S102, and in step S102, the wireless charging mouse 205 and the electronic device 215 perform data transmission at the set communication address. If the determination in step S101 is no, the process proceeds to step S103, and in step S103, the wireless charging mouse 205 and the electronic device 215 enter the pairing mode.

In step S105, the electromagnetic energy transmitted by the charging pad is received by the wireless charging mouse. When the user brings the wireless charging mouse 205 close to the charging pad 210, the resonant coil (not shown) in the wireless charging mouse 205 is electromagnetically coupled to the resonant coil (not shown) in the charging pad 210, so that the wireless charging mouse 205 receives the electromagnetic energy transmitted by the charging pad 210, and then the electromagnetic energy is converted into electric energy by the conversion circuit (not shown) in the wireless charging mouse 205 for energy storage of the charging battery (not shown) in the wireless charging mouse 205.

In step S110, the wireless charging mouse establishes a pairing transmission channel according to the electromagnetic energy, and transmits a first pairing signal to the electronic device. When the wireless charging mouse 205 receives the electromagnetic energy transmitted by the charging pad 210, the electromagnetic energy may trigger a communication circuit (not shown) inside the wireless charging mouse 205 to establish a pairing transmission channel corresponding to the pairing address by using a preset pairing address, and transmit a first pairing signal to the electronic device 215 through the pairing transmission channel by using a first radio frequency transmission intensity, where the electronic device 215 may be, for example, a desktop computer, a tablet computer, a notebook computer, and the like, which is not limited thereto. In detail, the wireless charging mouse 205 may store a plurality of pairing addresses, and when the wireless charging mouse 205 receives the electromagnetic energy, the communication circuit in the wireless charging mouse 205 is triggered to select one of the pairing addresses, and the first pairing signal is transmitted to the electronic device 215 by the first radio frequency transmission strength. The energy of the radio frequency transmission intensity can be distinguished by the frequency, and in addition, different radio frequency transmission intensities can respectively transmit different distances. When the wireless charging mouse 205 selects the pairing address and the rf transmission strength, the first pairing signal is transmitted to the electronic device 215.

In step S115, the electronic device determines whether the first pairing signal is received, if the determination in step S115 is yes, the process proceeds to step S120, and if the determination in step S115 is no, the process returns to step S110, and the electronic device 215 continues to wait for the wireless charging mouse 205 to transmit the first pairing signal. In other words, when the electronic device 215 cannot receive the first pairing signal transmitted by the wireless charging mouse 205, the wireless charging mouse 205 retransmits the first pairing signal to the electronic device 215.

In step S120, the electronic device transmits a first response signal to the wireless charging mouse via the pairing transmission channel. After the electronic device 215 receives the first pairing signal transmitted by the wireless charging mouse 205 with the pairing transmission channel and the first rf transmission strength, the electronic device 215 transmits a first response signal to the wireless charging mouse 205 with the pairing transmission channel and the second rf transmission strength, the electronic device 215 generates a first communication address, and the electronic device 215 stores the first communication address in the fifo.

In step S125, the wireless charging mouse determines whether the first response signal is received. If the determination in step S125 is yes, the process proceeds to step S130, and if the determination in step S125 is no, the process returns to step S120, and the wireless charging mouse 205 continues to wait for the first response signal transmitted by the electronic device 215. In other words, when the wireless charging mouse 205 cannot receive the first response signal transmitted by the electronic device 215, the electronic device 215 retransmits the first response signal to the wireless charging mouse 205.

In step S130, the wireless charging mouse transmits the first pairing signal to the electronic device again. When the wireless charging mouse 205 receives the first response signal of the electronic device 215, the first pairing signal is transmitted to the electronic device 215 again through the first rf transmission strength and the pairing transmission channel.

In step S135, the electronic device determines whether the first pairing signal is received again, if the determination in step S135 is yes, the process proceeds to step S140, and if the determination in step S135 is no, the process returns to step S130, and the electronic device 215 continues to wait for the wireless charging mouse 205 to transmit the first pairing signal again. Specifically, when the electronic device 215 cannot receive the first pairing signal transmitted by the wireless charging mouse 205 again, the reasons for occurrence may be insufficient power supply, communication field interference, and the like.

In step S140, the electronic device transmits a second response signal to the wireless charging mouse. When the electronic device 215 receives the first pairing signal transmitted by the wireless charging mouse 205 again, the electronic device 215 is triggered to generate a second response signal, and then the electronic device 215 transmits the second response signal to the wireless charging mouse 205 through the second rf transmission strength and the pairing transmission channel, and the electronic device 215 also transmits the first communication address previously stored in the first-in first-out to the wireless charging mouse 205.

In step S145, the electronic device and the wireless charging mouse enter a data transmission mode. After the wireless charging mouse 205 receives the second response signal transmitted by the electronic device 215, the wireless charging mouse 205 stores the first communication address and establishes the first transmission channel according to the first communication address, and then the wireless charging mouse 205 and the electronic device 215 enter the data transmission mode according to the first communication address and the first transmission channel. The wireless charging mouse 205 may be provided with an indicator light (not shown), when the wireless charging mouse 205 and the electronic device 215 are in the pairing mode, the indicator light may display a flashing red light, and when the wireless charging mouse 205 and the electronic device 215 enter the data transmission mode, the indicator light may display a green light to display that the wireless connection status is good. In addition, the wireless charging mouse 205 may be provided with a reset button, and when the user touches the reset button for about 3 seconds, the wireless charging mouse 205 automatically deletes the previously set first communication address and the first transmission channel, so as to save the data storage space inside the wireless charging mouse 205.

Referring to fig. 1B and fig. 2, fig. 1B is a flowchart illustrating a pairing method of a wireless charging mouse according to an embodiment of the present invention. Fig. 1B is added with the determination step of step S128, compared to fig. 1A, and other steps in fig. 1B are the same as those in fig. 1A, and are not repeated herein. After the wireless charging mouse 205 has received the first response signal transmitted by the electronic device 215, the process proceeds to step S128, where the wireless charging mouse determines whether to continuously receive electromagnetic energy. If the determination in step S128 is yes, the process proceeds to step S130, and if the determination in step S128 is no, the process returns to step S105, and the wireless charging mouse 205 continuously waits for receiving electromagnetic energy.

Referring to fig. 2, fig. 3A and fig. 3B together, fig. 3A and fig. 3B are flowcharts of a pairing method of a wireless charging mouse according to an embodiment of the present invention. Fig. 3A and 3B are added to fig. 1 for determining the magnitude of the electromagnetic energy received by the wireless charging mouse 205 and the time range of the electromagnetic energy received. Steps S301 to S305 are the same as steps S101 to S105, and are not described herein again.

In step S307, it is determined whether the electromagnetic energy is higher than the preset electromagnetic energy by the wireless charging mouse 205. If the wireless charging mouse 205 receives that the electromagnetic energy transmitted by the charging pad 210 is higher than the predetermined electromagnetic energy, step S309 is performed, and if the wireless charging mouse 205 receives that the electromagnetic energy transmitted by the charging pad 210 is lower than the predetermined electromagnetic energy, step S305 is performed, and the wireless charging mouse 205 continues to wait for receiving the electromagnetic energy until the electromagnetic energy received by the wireless charging mouse 205 is higher than the predetermined electromagnetic energy. Those skilled in the art will appreciate that the transmission of electromagnetic energy is inversely proportional to distance, representing greater received electromagnetic energy at closer distances; conversely, the longer the distance, the smaller the electromagnetic energy received. The wireless charging mouse 205 is used to determine whether the wireless charging mouse 205 is placed on the charging pad 210 or whether the wireless charging mouse 205 is close to the charging pad 210, for example, within 3 cm, by determining the level of the electromagnetic energy received by the wireless charging mouse 205.

In step S309, it is determined whether a preset time is exceeded by the wireless charging mouse. If the time range of the wireless charging mouse 205 receiving the electromagnetic energy transmitted by the charging pad 210 exceeds the preset time, step S310 is performed, and if the time range of the wireless charging mouse 205 receiving the electromagnetic energy transmitted by the charging pad 210 is lower than the preset time, step S305 is performed again, and the wireless charging mouse 205 waits to receive the electromagnetic energy transmitted by the charging pad 210 again. In step S309, after it is determined that the wireless charging mouse 205 is placed on or close to the charging pad 210 for a predetermined time, the wireless charging mouse 205 is triggered to establish a pairing transmission channel, so as to prevent the user from consuming unnecessary power due to the short-time movement of the wireless charging mouse 205 to perform the pairing mode. Steps S310 to S345 are the same as steps S110 to S145, and are not described herein again.

In step S350, it is determined whether the electromagnetic energy is lower than a preset electromagnetic energy by the wireless charging mouse. If the wireless charging mouse 205 receives that the electromagnetic energy transmitted by the charging pad 210 is lower than the predetermined electromagnetic energy, step S355 is performed, and if the wireless charging mouse 205 receives that the electromagnetic energy transmitted by the charging pad 210 is higher than the predetermined electromagnetic energy, step S345 is performed again, and the wireless charging mouse 205 and the electronic device 215 are continuously in the data transmission mode.

In step S355, it is determined whether a preset time is exceeded by the wireless charging mouse. If the time range of the wireless charging mouse 205 receiving the low electromagnetic energy exceeds the preset time, step S360 is performed, and the wireless charging mouse 205 and the charging pad 210 leave the data transmission mode. If the time range of the wireless charging mouse 205 receiving the low electromagnetic energy is lower than the preset time, the process returns to step S345, and the wireless charging mouse 205 and the electronic device 215 are continuously in the data transmission mode. In step S355, the user is prevented from leaving the data transmission mode by moving the wireless charging mouse 205 for a short time, so as to maintain the stability of the data transmission mode.

Referring to fig. 2, fig. 4A and fig. 4B together, fig. 4A and fig. 4B are flowcharts of a pairing method of a wireless charging mouse according to an embodiment of the present invention. Steps S401 to S420 correspond to steps S101 to S120, and are not described herein again.

In step S425, the wireless charging mouse determines whether the first response signal is received. If the wireless charging mouse 205 receives the first response signal transmitted by the electronic device 215, the process proceeds to step S428. If the wireless charging mouse 205 does not receive the first response signal transmitted by the electronic device 215, the process proceeds to step S426.

In step S426, it is determined whether the transmission of the first pairing signal reaches the retry upper limit value by the wireless charging mouse. When the number of times that the wireless charging mouse 205 transmits the first pairing signal does not reach the retry upper limit value, the step S410 is returned to, and the wireless charging mouse 205 retransmits the first pairing signal to the electronic device 215; when the number of times that the wireless charging mouse 205 transmits the first pairing signal reaches the retry upper limit, the wireless charging mouse 205 suspends transmitting the first pairing signal to the electronic device 215, and then the step S427 is performed, the wireless charging mouse replaces the predetermined pairing address, and then the step S405 is performed again, and the wireless charging mouse 205 waits to be triggered again by the electromagnetic energy emitted by the charging pad 210.

In step S428, it is determined whether the wireless charging mouse continues to receive electromagnetic energy. If the determination in step S428 is yes, the process proceeds to step S430, and if the determination in step S428 is no, the process returns to step S405, and the wireless charging mouse 205 continues to wait for receiving electromagnetic energy.

In step S430, the wireless charging mouse transmits the first pairing signal to the electronic device again. In step S435, it is determined by the electronic device whether the first pairing signal is received again. If the judgment in the step S435 is yes, the process proceeds to a step S436; if the determination in step S435 is no, the process returns to step S430, and the wireless charging mouse 205 transmits the first pairing signal to the electronic device 215 again.

In step S436, it is determined by the electronic device whether the first pairing signal is completely received. If the determination in step S436 is yes, the process proceeds to step S437; if the determination in step S436 is negative, the process returns to step S430, and the wireless charging mouse 205 transmits the first pairing signal to the electronic device 215 again. Specifically, the electronic device 215 may include a communication circuit for verifying whether the electronic device 215 completely receives the first pairing signal transmitted by the wireless charging mouse 205.

In step S437, the electronic device determines whether the first pairing signal is transmitted from the pairing address in the pairing transmission channel. If yes in step S437, go to step S438; if the determination in step S437 is no, the process returns to step S430, and the wireless charging mouse 205 transmits the first pairing signal to the electronic device 215 again. When the electronic device 215 determines that the first pairing signal is transmitted from the pairing address in the pairing transmission channel, it indicates that the electronic device 215 has received the first pairing signal again.

In step S438, the electronic device prepares a recovery packet and stores the recovery packet in the fifo register. After the electronic device 215 has confirmed to receive the first pairing signal again, the electronic device 215 stores the ready reply packet (including the first communication address) into a fifo register of the electronic device 215, wherein the fifo register may be implemented by various electronic components having a function of storing data, which is not limited to the above.

In step S440, the electronic device transmits a second response signal to the wireless charging mouse. In step S441, the wireless charging mouse determines whether the second response signal is completely received, and if the determination in step S441 is yes, the process goes to step S442; if the determination in step S441 is negative, the electronic device 215 returns to step S440 to retransmit the second response signal to the wireless charging mouse 205.

In step S442, the wireless charging mouse receives a reply packet transmitted by the electronic device. When the wireless charging mouse 205 completely receives the second response signal, the wireless charging mouse 205 also receives a reply packet that the electronic device 215 has previously placed in the fifo register.

In step S443, the wireless charging mouse establishes a first transmission channel according to the reply packet. When the wireless charging mouse 205 receives the reply packet, the wireless charging mouse 205 will retrieve the first communication address from the reply packet, store the first communication address, and establish the first transmission channel with the first communication address. In step S445, the wireless charging mouse and the electronic device enter a data transmission mode. After the wireless charging mouse 205 and the electronic device 215 complete establishing the data transmission mode, the wireless charging mouse 205 transmits the data signal to the electronic device 215 with the third rf transmission strength and the first communication address. The electronic device 215 transmits the data signal to the wireless charging mouse 205 with the fourth RF transmission strength and the first communication address. The third RF transmission strength is greater than the first RF transmission strength, and the fourth RF transmission strength is greater than the second RF transmission strength. In detail, the first rf transmission strength is the minimum transmission strength of the wireless charging mouse 205, the third rf transmission strength is the maximum transmission strength of the wireless charging mouse 205, the second rf transmission strength is the minimum transmission strength of the electronic device 215, and the fourth rf transmission strength is the maximum transmission strength of the electronic device 215. When the wireless charging mouse 205 and the electronic device 215 are in the pairing mode, the distance between the wireless charging mouse 205 and the electronic device 215 is relatively close to avoid signal interference between the wireless charging mouse 205 and other electrical products. When the wireless charging mouse 205 and the electronic device 215 are in the data transmission mode, the distance between the wireless charging mouse 205 and the electronic device 215 can be relatively long, so as to increase the distance between the wireless charging mouse 205 and the electronic device 215 for data transmission.

In summary, the present invention provides a pairing method for a wireless charging mouse, which uses electromagnetic energy emitted by a charging pad to trigger the wireless charging mouse to generate a transmission channel, and then verifies whether the wireless charging mouse and an electronic device have entered a data transmission mode through a pairing signal and a response signal, so that a user can quickly establish a wireless connection channel within a short time when the wireless charging mouse is placed on the charging pad for charging, thereby avoiding the trouble of setting a driving program.

The above description is only an embodiment of the present invention, and is not intended to limit the scope of the present invention. Any variations and equivalent alterations made by those skilled in the art without departing from the spirit and scope of the present invention are still within the scope of the present invention.

Claims (10)

1. A wireless charging mouse pairing method is suitable for a pairing mode of the wireless charging mouse and an electronic device, and is characterized by comprising the following steps:

when the electromagnetic energy transmitted by a charging plate received by the wireless charging mouse is higher than a preset electromagnetic energy, and the electromagnetic energy transmitted by the charging plate received by the wireless charging mouse exceeds a preset time;

triggering and establishing a pairing transmission channel by the wireless charging mouse according to the electromagnetic energy by using a preset pairing address, and transmitting a first pairing signal to the electronic device for automatic pairing through the pairing transmission channel;

the electronic device receives the first pairing signal transmitted by the wireless charging mouse, transmits a first response signal to the wireless charging mouse through the pairing transmission channel, and generates a first communication address;

the wireless charging mouse receives the first response signal transmitted by the electronic device, and transmits the first pairing signal to the electronic device again through the pairing transmission channel;

the electronic device receives the first pairing signal transmitted by the wireless charging mouse again, and transmits a second response signal and the first communication address to the wireless charging mouse through the pairing transmission channel; and

the wireless charging mouse stores the first communication address and enters a data transmission mode.

2. The pairing method of a wireless charging mouse according to claim 1, further comprising:

when the wireless charging mouse is electromagnetically coupled with the charging plate, the wireless charging mouse receives the electromagnetic energy transmitted by the charging plate, and the wireless charging mouse establishes the pairing transmission channel according to the electromagnetic energy.

3. The pairing method of a wireless charging mouse according to claim 1, further comprising:

when the electromagnetic energy transmitted by the charging plate and received by the wireless charging mouse is lower than a preset electromagnetic energy and exceeds a preset time, the wireless charging mouse and the electronic device leave the data transmission mode.

4. The pairing method of a wireless charging mouse according to claim 1, further comprising:

if the wireless charging mouse does not receive the first response signal of the electronic device, judging whether the number of times of transmitting the first pairing signal by the wireless charging mouse reaches a retry upper limit value;

when the number of times of transmitting the first pairing signal by the wireless charging mouse does not reach the retry upper limit value, the wireless charging mouse retransmits the first pairing signal to the electronic device; and

when the number of times of the wireless charging mouse transmitting the first pairing signal reaches the retry upper limit value, the wireless charging mouse suspends transmitting the first pairing signal to the electronic device and replaces the pairing address, and the wireless charging mouse waits to be triggered again by the electromagnetic energy emitted by the charging plate.

5. The pairing method of a wireless charging mouse according to claim 1, further comprising:

if the wireless charging mouse receives the first response signal transmitted by the electronic device, the wireless charging mouse waits to be triggered again by the second response signal;

the electronic device judges whether the first pairing signal is completely received;

if the electronic device has completely received the first pairing signal, the electronic device determines whether the first pairing signal is transmitted from the pairing address in the pairing transmission channel;

wherein when the electronic device determines that the first pairing signal is transmitted from the pairing address in the pairing transmission channel, it indicates that the electronic device has received the first pairing signal again; and

if the electronic device has received the first pairing signal again, a reply packet is prepared, the reply packet comprises the first communication address, and the reply packet is stored in a first-in first-out register of the electronic device.

6. The pairing method of a wireless charging mouse according to claim 5, further comprising:

if the wireless charging mouse receives the second response signal of the electronic device, the wireless charging mouse also receives the reply packet which is previously placed into the first-in first-out register by the electronic device; and

the wireless charging mouse will take out the first communication address from the reply packet, and store the first communication address, and establish a first transmission channel with the first communication address.

7. The method of claim 1, wherein after the wireless charging mouse establishes the pairing transmission channel, the wireless charging mouse transmits the first pairing signal to the electronic device via the pairing transmission channel with a first RF transmission strength; after the electronic device receives the first pairing signal transmitted by the wireless charging mouse, the electronic device transmits the first response signal to the wireless charging mouse through the pairing transmission channel at a second radio frequency transmission intensity.

8. The method as claimed in claim 7, wherein after the wireless charging mouse receives the first response signal transmitted by the electronic device, the wireless charging mouse transmits the first pairing signal to the electronic device again with the first rf transmission strength and the pairing transmission channel; after the electronic device receives the first pairing signal transmitted by the wireless charging mouse again, the electronic device transmits the second response signal and the first communication address to the wireless charging mouse by the second radio frequency transmission intensity and the pairing transmission channel.

9. The method as claimed in claim 8, wherein after the wireless charging mouse and the electronic device complete establishing the data transmission mode, the wireless charging mouse transmits the data signal to the electronic device with a third RF transmission strength and the first communication address, and the electronic device transmits the data signal to the wireless charging mouse with a fourth RF transmission strength and the first communication address.

10. The method as claimed in claim 9, wherein the third RF transmission strength is greater than the first RF transmission strength, and the fourth RF transmission strength is greater than the second RF transmission strength.

Images