KR102204560B1 - Mouse pad for supporting wireless charging - Google Patents

Abstract

Disclosed are a mouse pad supporting wireless charging and a wireless charging system including the same. According to an embodiment, a mouse pad supporting wireless charging includes an RF charging transmission module that provides wireless charging based on a radio frequency (RF); And a magnetic induction charging transmission module for providing magnetic induction-based wireless charging, wherein the RF charging transmission module and the magnetic induction charging transmission module are provided separately from each other.

Description

Mouse pad supporting wireless charging {MOUSE PAD FOR SUPPORTING WIRELESS CHARGING}

The following embodiments relate to a mouse pad that supports wireless charging, and relates to a mouse pad that serves as a wireless charging transmission device supporting multiple wireless charging methods.

With the spread of computers, mouse pads that freely move the mouse body are also widely used. In relation to such a mouse pad, a technology for a mouse pad having other additional functions such as a USB hub is provided in addition to the basic function of freeing the movement of the mouse body has been developed and proposed. Such a mouse pad is disclosed in Korean Patent Application Laid-Open No. 10-2007-0049185.

Meanwhile, as portable terminals using wireless communication are widely spread in recent years, a wireless charging technology for charging a portable terminal having a built-in wireless charging receiving device is also being actively developed as a wireless charging signal is transmitted from a wireless charging transmitting device.

Therefore, if instead of separately providing a wireless charging and transmitting device, it is expected that if the device is mounted on a mouse pad, the user's convenience is maximized and free from the cost burden of purchasing both the mouse pad and the wireless charging and transmitting device.

Therefore, there is a need to propose a technology for a mouse pad having a wireless charging function.

One embodiment provides a mouse pad that supports wireless charging.

In more detail, exemplary embodiments provide multiple wireless charging mouse pads supporting both an RF method and a magnetic induction method by including an RF charging transmission module and a magnetic induction charging transmission module.

In this case, the exemplary embodiments provide a mouse pad capable of minimizing mutual interference by providing the RF charging transmission module and the magnetic induction charging transmission module separately from each other.

In particular, one embodiment provides an RF charging transmission module to which an RF method using a magnetic field is applied, not a conventional RF method using an electric field.

According to an embodiment, a mouse pad supporting wireless charging includes an RF charging transmission module that provides wireless charging based on a radio frequency (RF); And a magnetic induction charging transmission module for providing magnetic induction-based wireless charging, wherein the RF charging transmission module and the magnetic induction charging transmission module are provided separately from each other.

According to one side, the RF charging and transmitting module and the magnetic induction charging and transmitting module may be formed in areas physically separated from each other on the mouse pad.

According to the other side, each of the RF charging transmission module and the magnetic induction charging transmission module may have a structure to minimize interference when at least one component shared with each other is included.

According to another aspect, the RF charging and transmitting module may be characterized in that it provides RF-based wireless charging using a magnetic field.

According to another aspect, the RF charging and transmitting module, at least one PLL (Phase Locked Loop) for generating a power signal of at least one frequency band; At least one matching unit for matching and outputting the power signal of the at least one frequency band for each frequency; And at least one RF antenna for transmitting the power signal of the at least one frequency band to at least one receiver.

According to another aspect, the at least one matching unit may be provided corresponding to the power signal of the at least one frequency band.

According to another aspect, the RF charging and transmitting module, the control unit for controlling at least one operation of the at least one PLL or the at least one matching unit; And a communication antenna for receiving frequency information from the at least one receiver, wherein the controller controls at least one operation of the at least one PLL or the at least one matching unit based on the received frequency information. It can be characterized by that.

According to another aspect, the at least one RF antenna may be formed in either a loop type or a coil type to use a magnetic field.

According to still another aspect, the at least one RF antenna may be formed in a different area different from the area formed on the mouse pad with the at least one PLL and the at least one matching part.

According to another aspect, the magnetic induction charging transmission module, AC-DC power supply for supplying by converting the external AC power to DC; An oscillator generating a power signal of a specific frequency band based on the supplied DC power; A matching unit for matching and outputting a power signal of the specific frequency band; And a magnetic induction antenna for transmitting the power signal of the specific frequency band to at least one receiver.

According to another aspect, the magnetic induction charging transmission module, the control unit for controlling the operation of the oscillator; And a communication antenna for receiving frequency information from the at least one receiver, wherein the control unit controls an operation of the oscillator based on the received frequency information.

According to another side, a communication antenna included in the RF charging transmission module and a communication antenna included in the magnetic induction charging transmission module are provided to be shared by the RF charging transmission module and the magnetic induction charging transmission module. It can be characterized.

According to another aspect, the RF charging and transmitting module and the magnetic induction charging and transmitting module may be characterized in that they receive a common external AC power supply.

According to an embodiment, a mouse pad-based wireless charging system includes: a mouse pad providing multiple wireless charging; And at least one receiver wirelessly charged by the mouse pad, wherein the mouse pad includes: an RF charging transmission module that provides wireless charging based on a radio frequency (RF); And a magnetic induction charging transmission module for providing magnetic induction-based wireless charging, wherein the RF charging transmission module and the magnetic induction charging transmission module are provided separately from each other.

According to an embodiment, a charging device supporting multiple wireless charging includes an RF charging transmission module that provides wireless charging based on a radio frequency (RF); And a magnetic induction charging transmission module for providing magnetic induction-based wireless charging, wherein the RF charging transmission module and the magnetic induction charging transmission module are provided separately from each other.

According to one side, the RF charging transmission module and the magnetic induction charging transmission module may be formed in areas physically separated from each other on the charging device.

According to the other side, the RF charging and transmitting module may be characterized in that it provides RF-based wireless charging using a magnetic field.

One embodiment may provide a mouse pad that supports wireless charging,

In more detail, one embodiment may provide a multiple wireless charging mouse pad supporting both an RF method and a magnetic induction method by including an RF charging transmission module and a magnetic induction charging transmission module.

In this case, the exemplary embodiments may provide a mouse pad capable of minimizing mutual interference by providing the RF charging transmission module and the magnetic induction charging transmission module separately from each other.

In particular, one embodiment may provide an RF charging and transmitting module to which an RF method using a magnetic field is applied instead of a conventional RF method using an electric field.

1 is a block diagram showing a wireless charging system according to an embodiment.
2 is a diagram showing a mouse pad according to an embodiment.
3 is a block diagram illustrating an RF charging and transmitting module included in the mouse pad shown in FIG. 2.
4 to 5 are diagrams illustrating implementation examples of the RF charging and transmitting module shown in FIG. 3.
6 is a block diagram showing a magnetic induction charging transmission module included in the mouse pad shown in FIG. 2.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the embodiments. In addition, the same reference numerals shown in each drawing denote the same member.

In addition, terms used in the present specification are terms used to properly express preferred embodiments of the present invention, which may vary depending on the intention of users or operators, or customs in the field to which the present invention belongs. Accordingly, definitions of these terms should be made based on the contents throughout the present specification.

1 is a block diagram illustrating a wireless charging system according to an exemplary embodiment, and FIG. 2 is a diagram illustrating a mouse pad according to an exemplary embodiment.

1 to 2, the wireless charging system 100 according to an embodiment includes a mouse pad 110 providing multiple wireless charging and at least one receiver 120 wirelessly charged by the mouse pad 110 Includes.

Hereinafter, it is assumed that the mouse pad 110 is designed in a shape capable of providing a basic function to freely move the mouse body. For example, the mouse pad 110 may be designed to have an area 111 having an area greater than a certain area in which the mouse body is located and can be moved vertically and horizontally.

The mouse pad 110 is characterized in that it is implemented to provide a wireless charging function that provides wireless charging in addition to the basic functions. To this end, the mouse pad 110 includes an RF charging transmission module 210 and a magnetic induction charging transmission module 220 that provide RF-based wireless charging, and uses both an RF method and a magnetic induction method, and at least one The receiver 120 can be wirelessly charged.

The RF charging/transmitting module 210 included in the mouse pad 110 transmits a power signal of at least one frequency band to the at least one receiver 120 by an RF method. For example, the RF charging/transmitting module 210 may wirelessly charge the at least one receiver 120 by transmitting the power signal of the first frequency band to the at least one receiver 120 in an RF manner. Hereinafter, the power signal may be implemented in the form of a pulse or a continuous wave (CW). For another example, the RF charging and transmitting module 210 may improve wireless charging efficiency by transmitting power signals of a plurality of frequency bands to at least one receiver 120 in an RF manner. For a more specific example, the RF charging/transmitting module 210 simultaneously transmits a power signal of a first frequency band and a power signal of a second frequency band to at least one receiver 120 in an RF manner, thereby at least one receiver ( 120) may be charged using both the power signal of the first frequency band and the power signal of the second frequency band. A detailed description of this will be described with reference to FIG. 3. In this case, each frequency band may be set so that the power signals have a frequency band difference of 1 kHz or more from each other so that interference between the power signals of a plurality of frequency bands transmitted by the RF method can be minimized.

The magnetic induction charging transmission module 220 included in the mouse pad 110 transmits a power signal of a specific frequency band to at least one receiver 120 in a magnetic induction method. Accordingly, at least one receiver 120 may be charged using a power signal of a specific frequency band received from the magnetic induction charging transmission module 220 through a magnetic induction method. A detailed description of this will be described with reference to FIG. 6.

The RF charging transmission module 210 and the magnetic induction charging transmission module 220 operate individually as well as operate simultaneously, so that at least one receiver 120 simultaneously uses and charges the RF method and the magnetic induction method. Charging efficiency can be maximized.

In addition, the RF charging and transmitting module 210 and the magnetic induction charging and transmitting module 220 may be respectively connected to individual external AC power and may be connected to a common external AC power to receive power.

At this time, since the RF charging transmission module 210 and the magnetic induction charging transmission module 220 transmit power signals of different frequency bands in different ways, the RF charging transmission module 210 and the magnetic induction charging transmission module 220 If) is integrated into one area on the mouse pad 110, mutual interference may occur.

Accordingly, the RF charging transmission module 210 and the magnetic induction charging transmission module 220 may be formed in areas physically separated from each other on the mouse pad 110 so as to minimize or prevent mutual interference. Hereinafter, the fact that the RF charging transmission module 210 and the magnetic induction charging transmission module 220 are formed in areas physically separated from each other is, in each of the RF charging transmission module 210 and the magnetic induction charging transmission module 220 It means that the RF charging transmission module 210 and the magnetic induction charging transmission module 220 are physically isolated and spaced apart so that the interference between the generated power signals is below a specific value, which is a negligible level.

For example, the RF charging and transmitting module 210 may be formed in the upper left area 112 on the mouse pad 110, and the magnetic induction charging transmitting module 220 is the upper right area 113 on the mouse pad 110. ) Can be formed. Furthermore, an isolation film for shielding the power signal between the RF charging transmission module 210 and the magnetic induction charging transmission module 220 so that the RF charging transmission module 210 and the magnetic induction charging transmission module 220 are more thoroughly isolated (Fig. Not shown) may be arranged.

For another example, when each of the RF charging transmission module 210 and the magnetic induction charging transmission module 220 is implemented to include at least one component (eg, ground) shared with each other, the RF charging transmission module 210 ) And the magnetic induction charging transmission module 220 may have a structure that minimizes mutual interference, such as each including filters to be applied to a ground shared with each other.

As such, the mouse pad 110 according to an embodiment forms the RF charging transmission module 210 and the magnetic induction charging transmission module 220 in areas that are physically separated from each other and separated from each other. It can provide both induction methods. A detailed description of the detailed structures of the RF charging transmission module 210 and the magnetic induction charging transmission module 220 will be described with reference to FIGS. 3 and 6 below.

3 is a block diagram illustrating an RF charging and transmitting module included in the mouse pad shown in FIG. 2.

Referring to FIG. 3, the RF charging and transmitting module 210 includes at least one PLL (Phase Locked Loop) 310, at least one matching unit 320, and at least one RF antenna 330.

At least one PLL 310 generates a power signal of at least one frequency band. At this time, at least one PLL 310 may sequentially (almost simultaneously) generate power signals of a plurality of frequency bands. To this end, the at least one PLL 310 may be implemented in plural to correspond to power signals in a plurality of frequency bands, but is not limited thereto or may be implemented as a single component. A detailed description thereof will be described with reference to FIGS. 4 to 5.

The operation of the at least one PLL 310 may be performed when external AC power is supplied. However, the present invention is not limited or limited thereto, and the at least one PLL 310 may be operated by power supplied from a power supply unit built into the mouse pad 110 rather than power supplied from the outside of the mouse pad 110.

At least one matching unit 320 to be described below may also be operated not only when external AC power is supplied, but also by power supplied from a power supply built into the mouse pad 110.

At least one matching unit 320 is disposed at an output terminal of at least one PLL 310 to match and output a power signal of at least one frequency band for each frequency. Here, the at least one matching unit 320 is provided in correspondence with the power signal of at least one frequency band, so that feeding may be performed for each power signal of at least one frequency band. For example, when a power signal of a first frequency band and a power signal of a second frequency band are transmitted from at least one PLL 310, at least one matching unit 320 2 It is provided in plural corresponding to the power signal of the frequency band, and the power signal of the first frequency band is matched and output by the first matching unit, and the power signal of the second frequency band is matched and output by the second matching unit. .

At least one RF antenna 330 is disposed at an output terminal of at least one matching unit 320 and transmits a power signal of at least one frequency band to at least one receiver 120. In particular, the at least one RF antenna 330 may be formed in either a loop type or a coil type so that a magnetic field-based RF method can be used in a manner that transmits a power signal of at least one frequency band. Therefore, the RF charging and transmitting module 210 includes at least one RF antenna 330 formed in either a loop type or a coil type, thereby applying an RF method using a magnetic field rather than a conventional RF method using an electric field. Through this, it is possible to achieve a technical effect of allowing the power signal of at least one frequency band transmitted to the at least one receiver 120 to pass through water or a human body.

At this time, since the at least one RF antenna 330 is formed to have a relatively thin thickness compared to the at least one PLL 310 and the at least one matching unit 320, the mouse body is positioned on the mouse pad 110. (On the other hand, at least one PLL 310 and at least one matching unit 320 may be formed in the region 111 to be performed so that the mouse body is positioned on the mouse pad 110 as shown in FIG. 2. It may be formed in the region 112 other than the region 111). That is, at least one RF antenna 330 is formed in another region 111 that is distinct from the region 112 in which at least one PLL 310 and at least one matching unit 320 are formed on the mouse pad 210 As a result, the mouse pad 110 can be miniaturized.

In addition, the RF charging and transmitting module 210 receives frequency information from the control unit 340 and at least one receiver 120 for controlling at least one operation of at least one PLL 310 or at least one matching unit 320. It may further include a communication antenna 350 for receiving. Accordingly, the controller 340 may control the operation of at least one of the at least one PLL 310 or the at least one matching unit 320 based on the frequency information received through the communication antenna 350. For example, the control unit 340 causes at least one PLL 310 based on the frequency information received from the communication antenna 350 (at least information related to the frequency band of the power signal to be used by the one receiver 120). The power signal of the corresponding frequency band may be controlled to be generated, or the at least one matching unit 320 may be controlled to match and output only the power signal of the corresponding frequency band.

Here, the communication antenna 350 may be shared and used by the magnetic induction charging transmission module 220 to be described later. A detailed description of this will be described with reference to FIG. 6.

4 to 5 are diagrams illustrating implementation examples of the RF charging and transmitting module shown in FIG. 3. Hereinafter, all of FIGS. 4 to 5 show a detailed example of the RF charging and transmitting module 210 described above with reference to FIGS. 1 through 3, and in more detail, FIG. 4 shows an RF charging and transmitting module including a plurality of PLLs. 5 is a diagram showing an RF charging and transmitting module including a single PLL.

Referring to FIG. 4, the RF cable/transmission module 400 according to an embodiment is characterized by including a plurality of PLLs 410, 411, and 412. Specifically, the RF charging/transmitting module 400 includes a plurality of PLLs 410, 411, 412, a plurality of power amplifiers 420, 421, 422, a plurality of matching units 430, 431, 432, and a plurality of RF antennas 440, 441, 442 and a control unit 450 may be included.

Therefore, the power signals of a plurality of frequency bands generated from the plurality of PLLs 410, 411, 412 are matched through a plurality of power amplifiers corresponding to each frequency band among the plurality of power amplifiers 420, 421, 422. Among the units 430, 431, and 432, a matching unit corresponding to each frequency band may be matched and output. Likewise, power signals of a plurality of frequency bands matched and output for each frequency band by the plurality of matching units 430, 431, and 432 may be transmitted to at least one receiver through a corresponding RF antenna, respectively.

Here, since the plurality of power amplifiers 420, 421, and 422 may be formed in the same structure to perform the same function as the power amplifier used in the conventional wireless charging and transmitting apparatus, a detailed description thereof will be omitted.

Referring to FIG. 5, the RF cable-wired transmission module 500 according to another embodiment is characterized by including a single PLL 510. In more detail, the RF charging/transmitting module 500 includes a single PLL 510, a plurality of power amplifiers 520, 521, 522, a plurality of matching units 530, 531, 532, and a plurality of RF antennas 540. , 541, 542 and a control unit 550 may be included.

Accordingly, power signals of a plurality of frequency bands sequentially (almost simultaneously) generated from a single PLL 510 are power signals corresponding to each frequency band among the plurality of power amplifiers 520, 521, 522 by the switch element 560. Among the plurality of matching units 530, 531, and 532 through an amplifier, matching may be output through a matching unit corresponding to each frequency band. Similarly, power signals of a plurality of frequency bands matched and output for each frequency band by the plurality of matching units 530, 531, and 532 may be transmitted to at least one receiver through a corresponding RF antenna, respectively.

Here, since the plurality of power amplifiers 520, 521, and 522 may be formed in the same structure to perform the same function as the power amplifier used in the conventional wireless charging and transmitting apparatus, a detailed description thereof will be omitted.

6 is a block diagram showing a magnetic induction charging transmission module included in the mouse pad shown in FIG. 2.

Referring to FIG. 6, the magnetic induction charging transmission module 220 includes an AC-DC power supply 610, an oscillator 620, a matching unit 630, and a magnetic induction antenna 640.

The AC-DC power supply 610 converts external AC power to DC and supplies it to the oscillator 620 connected to the output terminal.

The oscillator 620 generates a power signal of a specific frequency band based on the supplied DC power. In this case, the oscillator 620 may adaptively adjust the frequency band of the generated power signal. As an example, the oscillator 620 determines a frequency band of a power signal to be generated based on frequency information received from at least one receiver 120 through a communication antenna 650 to be described later, and generates the power signal in the determined frequency band. Can be created and printed.

The matching unit 630 is disposed at the output terminal of the oscillator 620 to match and output a power signal of a specific frequency band. Here, the matching unit 630 may be adaptively adjusted by the oscillator 620 and formed in a structure capable of matching various frequency bands so as to match the frequency band of the output power signal.

The magnetic induction antenna 640 is disposed at the output terminal of the matching unit 630 and transmits a power signal of a specific frequency band fed from the matching unit 630 to at least one receiver 120. In this case, the magnetic induction antenna 640 may be formed in a coil-type shape to use a magnetic induction method.

The AC-DC power supply 610, oscillator 620, and matching unit 630 described above may operate when external AC power is supplied. However, the present invention is not limited or limited thereto, and the AC-DC power supply 610, the oscillator 620, and the matching unit 630 are not power supplied from the outside of the mouse pad 110, but a power supply built in the mouse pad 110. It can also be operated by power supplied from

In addition, the magnetic induction charging transmission module 220 includes a control unit 660 for controlling the operation of the oscillator 620 or the matching unit 630 and a communication antenna 650 for receiving frequency information from at least one receiver 120. It may contain more. Accordingly, the controller 660 may control the operation of the oscillator 620 or the matching unit 630 based on the frequency information received through the communication antenna 650. For example, the controller 660 causes the oscillator 620 to cause the corresponding frequency band based on the frequency information received from the communication antenna 650 (at least information related to the frequency band of the power signal to be used by the one receiver 120). The power signal of may be controlled to be generated, or the matching unit 630 may be controlled to match and output only the power signal of a corresponding frequency band.

Here, the communication antenna 650 may be shared and used by the above-described RF charging and transmitting module 210. That is, the communication antenna 350 included in the RF charging transmission module 210 and the communication antenna 650 included in the magnetic induction charging transmission module 220 include the RF charging transmission module 210 and the magnetic induction charging transmission module ( 220) can be provided singly to be shared.

As described above, the mouse pad 110 according to an embodiment includes an RF charging transmission module 210 and a magnetic induction charging transmission module 220, thereby providing both an RF method and a magnetic induction method, and in particular, RF charging and transmission By providing the module 210 and the magnetic induction charging transmission module 220 separated from each other, mutual interference can be minimized. In addition, the mouse pad 110 according to an embodiment provides an RF charging and transmitting module 210 to which an RF method using a magnetic field is applied, rather than a conventional RF method using an electric field, thereby transmitting from the RF charging and transmitting module 210. By allowing at least one power signal to pass through water and a human body, it is possible to propose an RF-type wireless charging technology that is not restricted by the surrounding environment.

The above-described RF charging and transmitting module 210 is not limited to or limited to the described structure, and may be formed in a variety of structures that provide an RF-type wireless charging using a magnetic field, and the magnetic induction charging transmitting module 220 is also It may be formed in a variety of structures that provide inductive wireless charging.

In addition, although the mouse pad 110 including the RF charging transmission module 210 and the magnetic induction charging transmission module 220 has been described above, it is implemented as a charging device that supports not only the mouse pad 110 but also wireless charging. It will be possible. That is, through the above-described examples, including an RF charging transmission module that provides a radio frequency (RF)-based wireless charging using a magnetic field and a magnetic induction charging transmission module that provides a magnetic induction-based wireless charging, RF charging transmission A charging device characterized in that the module and the magnetic induction charging transmission module are provided separately from each other may be described.

As described above, although the embodiments have been described by the limited embodiments and drawings, various modifications and variations are possible from the above description by those of ordinary skill in the art. For example, the described techniques are performed in a different order from the described method, and/or components such as a system, structure, device, circuit, etc. described are combined or combined in a form different from the described method, or other components Alternatively, even if substituted or substituted by an equivalent, an appropriate result can be achieved.

Therefore, other implementations, other embodiments, and claims and equivalents fall within the scope of the claims to be described later.

Claims (17)

In a mouse pad that supports wireless charging,
RF charging transmission module for providing wireless charging based on RF (Radio Frequency); And
Magnetic induction charging transmission module that provides magnetic induction-based wireless charging
Including,
The RF charging transmission module and the magnetic induction charging transmission module,
In the case of including at least one component separated from each other and shared with each other, a structure including an isolation film shielding a power signal between the RF charging transmission module and the magnetic induction charging transmission module to minimize interference or the RF charging transmission The module and the magnetic induction charging transmission module are characterized by having a structure including each of filters applied to a shared ground,
The RF charging and transmitting module,
It is characterized in that it provides RF-based wireless charging using a magnetic field through at least one RF antenna formed in either a loop type or a coil type,
At least one PLL (Phase Locked Loop) generating a power signal of at least one frequency band;
At least one matching unit for matching and outputting the power signal of the at least one frequency band for each frequency; And
The at least one RF antenna for transmitting the power signal of the at least one frequency band to at least one receiver
Including,
The at least one RF antenna,
The mouse pad, wherein the at least one PLL and the at least one matching part are formed in an area in which the mouse body is located, which is a different area distinguished from the area formed on the mouse pad. The method of claim 1,
The RF charging transmission module and the magnetic induction charging transmission module,
A mouse pad, characterized in that each formed in areas physically separated from each other on the mouse pad. delete delete delete The method of claim 1,
The at least one matching unit,
Mouse pad, characterized in that provided in response to the power signal of the at least one frequency band. The method of claim 1,
The RF charging and transmitting module,
A control unit controlling an operation of at least one of the at least one PLL or the at least one matching unit; And
Communication antenna for receiving frequency information from the at least one receiver
Including more,
The control unit,
And controlling an operation of at least one of the at least one PLL or the at least one matching unit based on the received frequency information. delete delete The method of claim 1,
The magnetic induction charging transmission module,
AC-DC power supply that converts and supplies external AC power to DC;
An oscillator generating a power signal of a specific frequency band based on the supplied DC power;
A matching unit for matching and outputting a power signal of the specific frequency band; And
Magnetic induction antenna for transmitting the power signal of the specific frequency band to at least one receiver
Mouse pad comprising a. The method of claim 10,
The magnetic induction charging transmission module,
A control unit for controlling the operation of the oscillator; And
Communication antenna for receiving frequency information from the at least one receiver
Including more,
The control unit,
And controlling the operation of the oscillator based on the received frequency information. The method according to any one of claims 7 or 11,
A communication antenna included in the RF charging transmission module and a communication antenna included in the magnetic induction charging transmission module,
Mouse pad, characterized in that provided to be shared by the RF charging transmission module and the magnetic induction charging transmission module. The method of claim 1,
The RF charging transmission module and the magnetic induction charging transmission module,
Mouse pad, characterized in that receiving a common external AC power supply. In the mouse pad-based wireless charging system,
A mouse pad that provides multiple wireless charging; And
At least one receiver wirelessly charged by the mouse pad
Including,
The mouse pad,
RF charging transmission module for providing wireless charging based on RF (Radio Frequency); And
Magnetic induction charging transmission module that provides magnetic induction-based wireless charging
Including,
The RF charging transmission module and the magnetic induction charging transmission module,
In the case of including at least one component separated from each other and shared with each other, a structure including an isolation film shielding a power signal between the RF charging transmission module and the magnetic induction charging transmission module to minimize interference or the RF charging transmission The module and the magnetic induction charging transmission module are characterized by having a structure including each of the filters applied to a shared ground
The RF charging transmission module,
It is characterized in that it provides RF-based wireless charging using a magnetic field through at least one RF antenna formed in either a loop type or a coil type,
At least one PLL (Phase Locked Loop) generating a power signal of at least one frequency band;
At least one matching unit for matching and outputting the power signal of the at least one frequency band for each frequency; And
The at least one RF antenna for transmitting the power signal of the at least one frequency band to at least one receiver
Including,
The at least one RF antenna,
The wireless charging system, characterized in that the at least one PLL and the at least one matching part are formed in an area in which the mouse body is located, which is a different area distinguished from the area formed on the mouse pad. delete delete delete

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