WO2021017411A1

WO2021017411A1 - Power supply socket and control method for electric device

Info

Publication number: WO2021017411A1
Application number: PCT/CN2020/070031
Authority: WO
Inventors: 邹高迪; 邹新
Original assignee: 深圳迈睿智能科技有限公司
Priority date: 2019-07-29
Filing date: 2020-01-02
Publication date: 2021-02-04
Also published as: CN110347089A

Abstract

Disclosed are a power supply socket (300) and a control method for an electric device (100). In the control method, an operating mode of an electric device (100) is controlled by means of allowing the electric device (100) to interact with a user, so that the operating mode of the electric device (100) is accurately matched with a behavior state of the user. Specifically, in the control method, motions, comprising a micromotion, of the user in an activity space (200) are accurately detected on the basis of microwaves, and the behavior state of the user in the activity space (200) is determined on the basis of the motions of the user, so that the operating mode of the electric device (100) is controlled according to the behavior state of the user.

Description

Power supply socket and control method of electric equipment

Technical field

The invention relates to a power supply socket and a control method of electric equipment.

Background technique

Sockets, such as the wall socket 10P and the conversion socket 20P, are common power supply relay devices in daily life, and they are used to conveniently connect electrical equipment to the mains circuit. For example, in the environment shown in FIG. 1A, the wall socket 10P is fixedly installed on the wall and connected to the mains circuit in advance, and the plug 31P of an air conditioner 30P is allowed to be inserted into the socket provided by the wall socket 10P. The mains power is provided to the air conditioner 30P through the wall socket 10P to allow the air conditioner 30P to work. With the continuous improvement of users’ awareness of electrical safety, the existing in-wall socket 10P presents an intelligent development trend. For example, the existing in-wall socket 10P is provided with a detector, an adjustment mechanism and a blanket. A controller connected to the detector and the adjustment mechanism, the adjustment mechanism has a power supply state and a disconnection state, and the controller can control the adjustment mechanism to automatically switch between the power supply state and the power supply state and the power supply state according to the detection result provided by the detector. Switch between open circuit status. For example, the detector may be a leakage detector or a short circuit detector, so that when the detector detects that there is a leakage or a short circuit in the circuit where the wall socket 10P and the air conditioner 30P are located, the controller can control the The adjustment mechanism automatically switches from the power supply state to the open circuit state, thereby ensuring the safety of electricity use. Since the wall socket 10P is pre-fixed on the wall and connected to the mains circuit, if the wall socket 10P itself does not have the function of automatically switching the working state, the user can install it with automatic switching working state The conversion socket 20P is connected to the wall socket 10P, and then the plug 31P of the air conditioner 30P is inserted into the socket of the conversion socket 20P. Refer to FIG. 1B. Although the existing socket can ensure the safety of electricity use, the existing socket can only switch between the power supply state and the disconnected state, and cannot provide data for controlling the working mode of the electric device. For example, when the electrical device is the air conditioner 30P, the socket can only control to allow or prevent power to the air conditioner 30P, but cannot provide data for controlling the operating mode of the air conditioner 30P.

Therefore, in order to meet the user's demand for the electric equipment as much as possible, the existing electric equipment is increasingly being developed towards the direction of intelligence. For example, for the air conditioner 30P, it provides a preset program to automatically control the working mode of the air conditioner 30P. The content of the preset program may be automatic shutdown, automatic startup, and automatic adjustment when the preset conditions are met. Work mode, etc. It is true that the existing intelligence of the air conditioner 30P provides convenience to users, but the existing intelligence of the air conditioner 30P does not associate the working mode of the air conditioner 30P with the user’s own state, which results in the air conditioner 30P. The working mode matches the user's own state. Typically, the air conditioner 30P is set to automatically turn on when the user enters a certain environment (such as a room) and is in a cooling mode. However, the user may have different behaviors in the environment, which leads to his demand for the temperature of the environment. Different, for example, when the user has a reading behavior state and a sleep behavior state in the environment, the requirements for the temperature of the environment are different. The existing air conditioner 30P cannot automatically adjust its working mode according to the user's behavior state in the environment. As a result, the air conditioner 30P cannot meet the needs of users.

Summary of the invention

An object of the present invention is to provide a power supply socket and a control method of an electric device, wherein the control method can realize the interaction between the electric device and the user, so that the working mode of the electric device meets the actual needs of the user .

An object of the present invention is to provide a power supply socket and a control method of an electric device, wherein the control method controls the working mode of the electric device based on the behavior state of the user in an activity space, so that it can accurately match the user The working mode of the electrical equipment and the user's own state.

An object of the present invention is to provide a power outlet and a control method for electrical equipment, wherein the user's actions in the activity space can be detected, for example, the user's breathing movement, heartbeat movement and other micro movements can be detected. The control method can accurately determine the user's behavior state in the activity space. For example, the user's walking behavior state, reading behavior state, and sleeping behavior state in the activity space can be accurately determined, so that the control method can accurately Match the working mode of the electric equipment and the user's own state.

An object of the present invention is to provide a power outlet and a control method for electrical equipment, wherein the control method can accurately determine the user's behavior in the activity space according to the user's actions in the activity space during a continuous period of time status.

An object of the present invention is to provide a power supply socket and a control method for electrical equipment, wherein the control method can accurately determine the power supply used in the activity space according to the combination of two or more actions of the user in the activity space Behavioral status.

An object of the present invention is to provide a power supply socket and a control method of electrical equipment, wherein the control method radiates a detection microwave to the active space and receives a response echo generated based on the detection microwave, and analyzes The way of responding to the echo detects the user's action in the activity space. Preferably, the control method analyzes the response echo in a manner of trending the response echo and classifying the fluctuating frequency of the trended response echo, so that the control method can accurately detect Actions in the activity space, such as walking, arm swinging, body/head shaking, breathing action, heartbeat action and other micro movements.

An object of the present invention is to provide a power supply socket and a control method of an electric device, wherein the control method radiates the detection microwave to the active space through a power supply socket for supplying power to the electric device and receives According to the response echo, there is no need to provide additional equipment that affects the aesthetics of the activity space, such as a separate microwave antenna, in the activity space.

An object of the present invention is to provide a power supply socket and a method for controlling electrical equipment, wherein the power supply socket provides a socket body and a microwave detector arranged on the socket body, and the socket body is configured to The electrical equipment provides electrical energy, and the microwave detector is configured to radiate the detection microwave to the active space and to receive the response echo.

An object of the present invention is to provide a power supply socket and a method for controlling electrical equipment, wherein the power supply socket integrates the socket body and the microwave detector, so that the socket body and the microwave detector can be simultaneously Connect to the mains circuit.

An object of the present invention is to provide a power supply socket and a control method for electrical equipment, wherein the power supply socket integrates the socket body and the microwave detector so as not to occupy an additional jack and based on the user’s presence in the activity space The behavior state of the corresponding electric equipment realizes interactive control.

An object of the present invention is to provide a power supply socket and a control method of an electric device, wherein the power supply socket communicates and controls the working mode of the electric device through a communication interface based on the behavior state of the user in the activity space.

An object of the present invention is to provide a power supply socket and a method for controlling electrical equipment, wherein based on the communication matching between the communication interface and different electrical equipment, the power supply socket can be based on the behavior state of the user in the activity space At the same time, it realizes the interactive control of different electrical equipment.

An object of the present invention is to provide a power supply socket and a control method for electric equipment, wherein the microwave detector is movably arranged on the socket body, so that the coverage of the detection microwave in the active space can be Be adjusted.

An object of the present invention is to provide a power supply socket and a method for controlling a power-consuming device, wherein the communication interface is configured to be able to receive a control command for the corresponding power-consuming device and generate a learning method for the corresponding power-consuming device. The control instruction of the device further realizes the matching between the power supply socket and the different electric devices.

An object of the present invention is to provide a power supply socket and a control method for electrical equipment, wherein a radiation source of the microwave detector can extend to a radiation source through hole of the socket body, so that the microwave detector can Stably radiate the detection microwave to the active space and receive the response echo.

According to one aspect of the present invention, the present invention provides a control method of electric equipment, wherein the control method includes the following steps:

(a) After a microwave detector radiates a detection microwave to an active space, receiving a response echo generated based on the detection microwave;

(b) Analyze the response echo to detect the user's actions in the activity space;

(c) Judging the user's behavior state in the activity space according to the user's actions; and

(d) Control the working mode of the electrical equipment according to the user's behavior state.

According to an embodiment of the present invention, the step (b) further includes the steps:

(b.1) Trending the response echo; and

(b.2) Classify the fluctuating frequency of the response echo that is trended to analyze the response echo.

According to an embodiment of the present invention, in the step (b.1), trending the content of the response echo includes trending the response echo based on a change in the amplitude of the response echo , Or trending the response echo based on the phase change of the response echo, or trending the response echo based on the pulse width change of the response echo, or The response echo is trended based on the frequency change of the response echo.

According to an embodiment of the present invention, in the step (b.2), the trended response echo is allowed to pass through at least one filter to classify the fluctuating frequency of the trended response echo.

According to an embodiment of the present invention, in the step (b.2), the filter is set to be the trended response after the trended response echo passes through the filter. The fluctuation frequency of the response echo is less than 25 Hz.

According to an embodiment of the present invention, in the step (c), the user's behavior state in the activity space is determined according to the user's actions in a continuous time period.

According to an embodiment of the present invention, in the step (a), the microwave detector integrated in a power supply socket is used to radiate the detection microwave to the active space and receive all generated microwaves based on the detection microwave. The response echo.

According to another aspect of the present invention, the present invention further provides a control method of electric equipment, wherein the control method includes the following steps:

(A) radiate a detection microwave to the active space through a microwave detector of a power outlet; and

(B) Receive a response echo generated based on the detection microwave to detect the user's action in the activity space, wherein the working mode of the electric device is associated with the user's action in the activity space.

According to an embodiment of the present invention, in the step (B), the microwave detector of the power supply socket receives the response echo generated based on the detection microwave.

According to an embodiment of the present invention, in the step (B), the power supply socket detects the user's action in the activity space by analyzing the response echo.

According to an embodiment of the present invention, in the step (B), the electric device detects the user's action in the activity space by analyzing the response echo.

According to an embodiment of the present invention, in the step (B), the power outlet determines the user's behavior state in the activity space according to the user's action, so as to allow the working mode of the electric device to be based on the user's behavior The state is controlled.

According to an embodiment of the present invention, in the step (B), the electric device judges the user's behavior state in the activity space according to the user's actions, so as to allow the working mode of the electric device to be based on the user's The behavior state is controlled.

According to an embodiment of the present invention, in the above method, the behavior state of the user in the activity space is determined according to the user's actions in a continuous period of time.

According to another aspect of the present invention, the present invention further provides a power supply socket, which includes:

A socket body, wherein the socket body has a mains interface mechanism; and

At least one microwave detector, wherein the microwave detector is disposed on the socket body, wherein the microwave detector further includes a reference board, a radiation source and a driving circuit, the reference board has a reference surface, and The radiation source is arranged on the reference plate, and the radiation source and the reference surface of the reference plate can respond to each other, wherein the driving circuit is electrically connected to the feeding point of the radiation source and the The mains interface mechanism of the socket body.

According to an embodiment of the present invention, the socket body includes a socket body and a cover plate, the socket body has the mains interface mechanism and at least one set of plug receiving mechanisms, and the cover plate has at least one set of perforations, The cover plate is provided on the socket main body, and the perforation of the cover plate corresponds to the plug receiving mechanism of the socket main body.

According to an embodiment of the present invention, the cover plate has a radiation source through hole, wherein the microwave detector is held between the socket body and the cover plate, and the radiation of the microwave detector The source corresponds to the radiation source through hole of the cover plate.

According to an embodiment of the present invention, the radiation source of the microwave detector extends to the radiation source through hole of the cover plate.

According to an embodiment of the present invention, the extension direction of the radiation source is perpendicular to the reference plane of the reference ground.

According to an embodiment of the present invention, the microwave detector is arranged on the socket body.

According to an embodiment of the present invention, the power supply socket further includes a voltage converter, wherein the voltage converter is electrically connected to the mains interface mechanism of the socket body, and the drive of the microwave detector The circuit is electrically connected to the voltage converter to allow the driving circuit of the microwave detector to be electrically connected to the mains interface mechanism of the socket body through the voltage converter.

According to an embodiment of the present invention, the power supply socket further includes a communication mechanism, wherein the communication mechanism is electrically connected to the voltage converter, and the communication mechanism is communicably connected to the microwave detector.

According to an embodiment of the present invention, the power socket further includes a computing device, wherein the computing device is communicably connected to the communication mechanism, and the computing device is configured to control the operation of at least one electrical device mode.

According to an embodiment of the present invention, the computing device includes at least one processor, at least one memory, and at least one communication interface, wherein the memory stores instructions for controlling the corresponding electrical equipment, wherein the processing The device is configured to process the instructions stored in the memory and control the communication interface to transmit corresponding instructions to the electrical equipment.

According to an embodiment of the present invention, wherein the communication interface is further configured to be able to receive a control instruction for the corresponding electric device, and generate the corresponding control instruction in the memory after receiving the control instruction for the corresponding electric device. To allow the power supply socket to match with different electrical equipment in a self-learning manner.

According to an embodiment of the present invention, wherein the processor includes a filter, wherein the filter is set to allow a fluctuating frequency to pass less than 25 Hz, so that the microwave detector can avoid interference from the mains circuit and can be It works stably while being integrated in the power supply socket.

Description of the drawings

Fig. 1A is a schematic diagram of an existing electricity usage environment.

FIG. 1B is a schematic diagram of another existing electricity usage environment.

Fig. 2 is a block diagram of a power utilization system according to a preferred embodiment of the present invention.

Fig. 3 is a schematic diagram of an application state of the electrical equipment according to the above-mentioned preferred embodiment of the present invention, which describes an electrical environment.

4 is a schematic diagram of the above-mentioned application state of the electric device according to the above-mentioned preferred embodiment of the present invention, which describes one of the processes of the electric device and the user interaction.

FIG. 5 is a schematic diagram of the above-mentioned application state of the electric device according to the above-mentioned preferred embodiment of the present invention, which describes the second process of the interaction between the electric device and the user.

6 is a schematic diagram of the above-mentioned application state of the electric device according to the above-mentioned preferred embodiment of the present invention, which describes the third process of the interaction between the electric device and the user.

Fig. 7 is a flow chart of a control method of an electrical equipment according to a preferred embodiment of the present invention.

FIG. 8 is a perspective schematic view of a power supply socket according to a preferred embodiment of the present invention.

FIG. 9 is a three-dimensional schematic diagram of the power supply socket according to the above-mentioned preferred embodiment of the present invention from another perspective.

Fig. 10 is an exploded schematic view of the power supply socket according to the above preferred embodiment of the present invention.

11 is a schematic cross-sectional view of the power supply socket according to the above-mentioned preferred embodiment of the present invention.

Fig. 12 is a perspective view of the power supply socket according to another preferred embodiment of the present invention.

FIG. 13 is a perspective view of the power supply socket according to another preferred embodiment of the present invention.

Fig. 14 is a perspective view of the power supply socket according to another preferred embodiment of the present invention.

15 is a perspective view of the power supply socket according to another preferred embodiment of the present invention.

Detailed ways

The following description is used to disclose the present invention so that those skilled in the art can implement the present invention. The preferred embodiments in the following description are only examples, and those skilled in the art can think of other obvious variations. The basic principles of the present invention defined in the following description can be applied to other embodiments, modifications, improvements, equivalents, and other technical solutions that do not depart from the spirit and scope of the present invention.

Those skilled in the art should understand that, in the disclosure of the present invention, the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", " The orientation or positional relationship indicated by "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. are based on the orientation or positional relationship shown in the drawings, which is only for the convenience of describing the present invention and The description is simplified, rather than indicating or implying that the pointed device or element must have a specific orientation, be constructed and operated in a specific orientation, and therefore the above terms should not be construed as limiting the present invention.

It can be understood that the term "a" should be understood as "at least one" or "one or more", that is, in one embodiment, the number of an element may be one, while in other embodiments, The number can be multiple, and the term "one" cannot be understood as a restriction on the number.

2 and 3, at least one electric device 100 is arranged in an activity space 200 for users to move to form an electric system, wherein the electric device 100 is electrically connected to the mains circuit, and the The electric device 100 has multiple working modes. It can be understood that when the electric device 100 is in different working modes, the activity space 200 has different states. In other words, the working mode of the electric device 100 and the state of the activity space 200 correspond to each other.

For example, in some examples of the present invention, the electrical equipment 100 may be an air conditioner 100a or an air conditioner group formed by two or more air conditioners 100a, which are electrically connected to the mains circuit, and the When power is supplied to the air conditioner 100a, the air conditioner 100a can be switched from the off state (or standby state) to the working state to change the working mode of the air conditioner 100a, so that the temperature of the active space 200 can be adjusted. It is understandable that the heating temperature and/or cooling temperature of the air conditioner 100a in the working state can be adjusted up or down to further change the working mode of the air conditioner 100a, so that the temperature of the activity space 200 can be Was further adjusted.

For another example, in some other examples of the present invention, the electrical equipment 100 may be a lamp or a lamp group formed by two or more lamps, which is electrically connected to the mains circuit, wherein the When power is supplied to the lamp, the lamp can be switched from the off state (or standby state) to the working state to change the working mode of the lamp, so that the brightness and/or chromaticity of the activity space 200 can be adjusted. It is understandable that the brightness and/or lighting mode of the lamp 100 in the working state can be adjusted to further change the working mode of the lamp, so that the brightness and/or chromaticity of the activity space 200 can be further adjusted. adjust.

It is understandable that the electrical equipment 100 described in the present invention may be the air conditioner 100a or the lamp is only an example for exposing the content and features of the present invention in more detail and clearly, but in the present invention The electrical equipment 100 described as the air conditioner 100a and the lamp may also be other equipment or equipment groups, which should not be regarded as affecting the content and scope of the electrical equipment 100 of the present invention. limit.

In the present invention, the working mode of the electric device 100 can be controlled based on the behavior state of the user in the activity space 200, so that by allowing the electric device 100 to interact with the user in the activity space 200 The working mode of the electric device 100 can be accurately controlled, so that the working mode of the electric device 100 can meet the needs of the user. Compared with the manner in which the user controls the working mode of the electrical equipment 100 through a remote control device or a switch device, the present invention provides a method of automatically controlling the electrical equipment 100 based on the user's behavior in the activity space 200. The working mode can make the working mode of the electric device 100 meet the actual needs of the user, and the process of adjusting the working mode of the electric device 100 does not require the user to actively participate. In other words, the working mode of the electric device 100 is automatically adjusted based on the user's behavior state in the activity space 200.

Further, the activity space 200 may be provided with at least one power supply socket 300, wherein the power supply socket 300 may be fixedly installed on a wall used to form the activity space 200, and the power supply socket may be fixedly installed When 300 is used to form the wall of the activity space 200, it is electrically connected to the power supply socket 300 to the mains circuit. It is worth mentioning that the manner in which the power supply socket 300 is fixedly arranged on the wall used to form the activity space 200 is not limited in the present invention. For example, in some examples, the power supply socket 300 may be a wall socket. Therefore, when decorating the wall, the power supply socket 300 can be fixedly arranged on the wall. In other examples, the power supply socket 300 can be a conversion socket, so that the power supply socket 300 is installed in a wall socket. It is fixedly arranged on the wall. In other embodiments of the present invention, the power supply socket may be a power socket, so that the power supply socket 300 extends from the wall socket by being plugged into the wall socket.

Specifically, the power supply socket 300 includes a socket body 301, the socket body 301 is used to define the general appearance of the power supply socket 300, in particular, the socket body 301 is used to define the length and width of the power supply socket 300 , High size, wherein the socket body 301 is fixedly arranged on the wall used to form the activity space 200, and the socket body 301 is electrically connected to the mains circuit. The electrical equipment 100 can be electrically connected to the socket body 301, so that city power can be supplied to the electrical equipment 100 through the socket body 301.

Furthermore, the power supply socket 300 includes at least one microwave detector 302, wherein the microwave detector 302 is disposed on the socket body 301 and is electrically connected to the mains circuit. The microwave detector 302 is configured to radiate a detection microwave to the active space 200 and receive a response echo generated based on the detection microwave. Specifically, after the microwave detector 302 radiates the detection microwave to the active space 200, the body of the user in the active space 200 can generate the response echo in response to the detection microwave, and the The response echo can be received by the microwave detector 302 for subsequent detection of the user's action in the activity space 200 based on the response echo. For example, the user's body can generate the response echo in response to the detection microwave by reflecting the detection microwave. Those skilled in the art can understand that, based on the principle of the Doppler effect, when the user's body generates the response echo in response to the detection microwave, it will cause the frequency and/or phase of the microwave fluctuation to change, thereby causing the The fluctuating frequency and/or phase of the detection microwave are different from the fluctuating frequency and/or phase of the response echo, so that the user's actions in the activity space 200 can be detected by analyzing the response echo later.

That is, in a preferred example of the present invention, the power supply socket 300 is arranged to integrate the socket body 301 and the microwave detector 302, so that the socket body 301 is fixedly arranged for forming When the wall of the active space 200 is used, the position of the microwave detector 302 in the active space 200 and the angle of the microwave detector 302 relative to the active space 200 can both be fixed.

In addition, the power supply socket 300 is configured to integrate the socket body 301 and the microwave detector 302, so that the socket body 301 and the microwave detector 302 of the power supply socket 300 can be simultaneously connected to the mains circuit In this way, the simplicity and reliability of the circuit of the electrical system can be guaranteed. Preferably, the microwave detector 302 is electrically connected to the socket body 301, so that while the socket body 301 is connected to the mains circuit, the microwave detector 302 can be connected to the mains circuit.

Preferably, in a preferred example of the present invention, the power supply socket 300 is arranged to integrate the socket body 301 and the microwave detector 302, so that there is no need to provide additional influence on the activity in the activity space 200. For the aesthetics of the space 200, for example, there is no need to provide an additional microwave antenna in the activity space 200.

Optionally, in another preferred example of the present invention, the socket body 301 and the microwave detector 302 may also be independent structures, so that the socket body 301 and the microwave detector 302 are respectively It is fixedly arranged on the wall used to form the activity space 200. For example, the external shape, length, width, and height of the microwave detector 302 are consistent with the external shape, length, width, and height of the socket body 301, so that the socket body 301 and the microwave After the detector 302 is used to form the wall of the movable space 200, the socket body 301 and the microwave detector 302 have similar appearances.

Further, the microwave detector 302 and the electrical equipment 100 of the power supply socket 300 are respectively communicatively connected to a computing device 400, wherein the computing device 400 is configured to be able to download from the microwave detector 302 The response echo is received, and the working mode of the electric device 100 is set to be able to control.

Specifically, referring to FIG. 2, the computing device 400 includes at least one processor 401, at least one memory 402, and at least one communication interface 403. The processor 401, the memory 402, and the communication interface 403 can interact with each other. To realize mutual communication among the processor 401, the memory 402, and the communication interface 403. The memory 402 may be a volatile memory or a non-volatile memory, which is configured to represent instructions of an operating system, instructions to represent processing logic, instructions to represent control commands, etc., wherein the processor 401 is configured to process The instructions stored in the memory 402 and the instructions transmitted through the communication interface 403 are processed. In addition, the communication interface 403 can transmit instructions generated by the processor 401.

It is understandable that the communication interface 403 can be set as a communication component with wireless transmission function such as a Bluetooth module, a Wi-Fi module and an infrared transmitter, and when the communication interface 403 is set as a Bluetooth module or Wi-Fi When the Fi module is used, the communication interface 403 can be hidden from the computing device 400 and installed in the power socket 300.

Particularly, in some embodiments of the present invention, the communication interface 403 is further configured to be able to receive control instructions to the corresponding electrical equipment 100. For example, the communication interface 403 is configured as an infrared pair tube to receive The corresponding control instructions are generated in the memory 402 in a learning manner for the control instructions corresponding to the electrical equipment 100, so as to realize the matching between the power supply socket 300 and the different electrical equipment 100.

It is worth mentioning that the interconnection mode of the processor 401, the memory 402, and the communication interface 403 of the computing device 400 is not limited, for example, the processor 401, the memory 402 and the The interconnection manner of the communication interface 403 may be, but is not limited to, physical interconnection, communicative interconnection, or operative interconnection.

The microwave detector 302 of the power supply socket 300 and the communication interface 403 of the computing device 400 are communicably connected. For example, the microwave detector 302 of the power supply socket 300 and the communication interface 403 of the computing device 400 may be communicatively connected through a wired connection. Preferably, the microwave detector 302 of the power supply socket 300 and the communication interface 403 of the computing device 400 may be communicatively connected through a wireless connection. Specifically, the power supply socket 300 includes a communication mechanism 303, wherein the microwave detector 302 is connected to the communication mechanism 303, and the power supply socket 300 is configured to transmit the microwave detector through the communication mechanism 303 302 The response echo received. The communication mechanism 303 of the power supply socket 300 and the communication interface 403 of the computing device 400 are communicably connected to each other to allow the computing device 400 to receive the response echo from the power supply socket 300 . For example, the communication mechanism 303 of the power supply socket 300 and the communication interface 403 of the computing device 400 may be communicably connected to each other based on a communication protocol such as a Bluetooth communication protocol. Optionally, the computing device 400 is disposed in the power supply socket 300, so that the computing device 400 and the power supply socket 300 are integrated into an integrated socket.

Correspondingly, the communication interface 403 of the electrical equipment 100 and the computing device 400 are communicably connected. For example, the electrical equipment 100 and the communication interface 403 of the computing device 400 may be communicably connected through a wired connection. Preferably, the electrical equipment 100 and the communication interface 403 of the computing device 400 may be communicably connected in a wireless connection manner. More preferably, the computing device 400 is provided in the electrical equipment 100, so that the computing device 400 and the electrical equipment 100 are integrated into an integrated electrical device.

After the communication interface 403 of the computing device 400 receives the response echo from the microwave detector 302 from the communication mechanism 303 of the power supply socket 300, the processor 401 is configured to analyze The response echo is used to detect specific actions of the user in the activity space 200. Those skilled in the art can understand that, according to the principle of the Doppler effect, the user can generate the response echo in response to the detection microwave radiated to the active space 200, and the response echo records the user’s The corresponding actions of the activity space 200 (including action type, action amplitude, action frequency, etc.), such as walking action, arm swing action, head shaking action, breathing action, heartbeat action, etc. can all be recorded in the response echo. It should be noted that the user's corresponding action in the activity space 200 is recorded in the response echo by means of shape and/or frequency, that is, the user's action and the characteristics of the response echo (wave The shape and frequency) correspond to each other. Therefore, the processor 401 can detect the specific actions of the user in the activity space 200 after analyzing the response echo.

It should be noted that when the microwave detector 302 of the power supply socket 300 radiates the detection microwave to the active space 200 and the user responds to generate the response echo, other objects in the active space 200 (Such as rotating fans, blown curtains, etc.) will produce interference and adversely affect the response echo, so that the response echo may not accurately reflect the user’s specific information in the activity space 200. action. In a preferred example of the present invention, the processor 401 is configured to trend the response echo to reduce or even remove the interference of clutter on the response echo representing the specific action of the user, thereby The processor 401 is configured to classify the fluctuating frequency of the trended response echo to analyze the response echo, and then to detect a specific action used in the activity space 200.

It is worth mentioning that trending the content of the response echo includes trending the response echo based on the amplitude change of the response echo, or based on the phase change of the response echo Trending the response echo, or trending the response echo based on the change in the pulse width of the response echo, or trending the response echo based on the change in the frequency of the response echo Trending in response to echoes.

Specifically, the processor 401 is configured to allow the trended response echo to pass through at least one filter (for example, but not limited to, an analog low-pass filter and a digital low-pass filter). The response echo is classified by the fluctuation frequency, and the standard for classifying the fluctuation frequency of the response echo can be adjusted by changing the filter parameter of the filter. For example, the resting breathing rate of an adult is generally 0.2-0.4 times/sec. Therefore, if the fluctuating frequency of the response echo that is trended is lower than 1 Hz, the user's breathing action in the activity space 200 can be detected . For another example, in a quiet state, the heart rate of a normal adult is 1.0-1.7 beats/sec, most of which are 1.0-1.3 beats/sec. The heart rate of a normal child (under 3 years old) is above 1.3 beats/sec, usually lower than 2.5 times/sec. Therefore, if the fluctuating frequency of the response echo that is trended is lower than 3 Hz, the user's heartbeat movement in the activity space 200 can be detected, and based on the breathing and/or heartbeat movement of different people Differently, the number of users in the activity space 200 can be identified. In particular, the corresponding action frequency based on the duration of each micro-movement of the human body in a normal state, such as walking, arm swing, body/head shaking, is less than 25 Hz, so if the response is trended back When the wave frequency is between 3 Hz and 25 Hz, the user's fretting motion in the activity space 200 can be detected.

That is to say, the fluctuation frequency of the response echo corresponding to the user's action in the activity space 200 obtained by performing fluctuation frequency classification of the trended response echo by at least one filter is lower than 25 Hz , And the AC frequency provided by the current mains circuit is 50Hz or 60Hz. Therefore, when the power supply socket 300 is electrically connected to the mains circuit, the AC frequency provided by the mains circuit will not affect the fluctuation frequency of 25Hz or less. The response echo caused interference, that is, the response echo processed by trending and classification will not be interfered by the alternating current provided by the mains circuit, so that the microwave detector 302 can be integrated in the power supply socket 300 Stable work at the same time.

According to the specific actions and/or the number of users in the activity space 200, the processor 401 is configured to further determine the behavior state of the users in the activity space 200. Those skilled in the art can understand that the behavior state of the user in the activity space 200 is embodied as the specific actions of the user in the activity space 200. For example, in the activity space 200, if the user's legs and arms are constantly swinging and the user's position changes, it indicates that the user's behavior state may be a walking behavior state. If the user's legs do not swing but only the arms swing When the user’s behavior state may be a reading behavior state, if the user’s limbs are not swinging but only the chest cavity moves back and forth regularly, it indicates that the user’s behavior state may be a sleep behavior state. If the user’s heartbeat is stable, It indicates that the user's behavior state may be a deep sleep behavior state. Therefore, when the processor 401 detects a specific action of the user in the activity space 200, it can determine the behavior state of the user in the activity space 200 according to the specific action of the user.

Preferably, the processor 401 can detect the specific actions of the user in the activity space 200 within a continuous period of time (for example, but not limited to, 1 minute, 5 minutes, 10 minutes, etc.), so as to accurately determine whether the user is in the activity The behavior state of space 200. For example, it may not be accurate enough to determine that the user’s behavior state is a sleep behavior state based only on the user’s limbs not swinging and only the movement of the chest cavity, because the user may be in a state of thinking behavior while reading. Therefore, if it is based on continuous During the period of time, the user's limbs are not swinging and only the action of chest movement determines that the user's behavior state is a sleep behavior state, and the accuracy is higher. Preferably, the processor 401 can detect more than two actions of the user in the activity space 200, and accurately determine the behavior state of the user in the activity space 200 according to the combination of these actions.

According to the behavior state of the user in the activity space 200, the processor 401 is configured to further control the working mode of the electric device 100 to accurately match the working mode of the electric device 100 and the user's own state, In this way, the interaction between the electric device 100 and the user is realized.

Figures 3 to 6 show a specific example of the power utilization system, in which a plurality of walls 201 define the approximate scope of the activity space 200, for example, the length of two oppositely arranged walls 201 defines the The approximate length dimension of the activity space 200, the length dimensions of the other two oppositely disposed walls 201 define the approximate width dimension of the activity space 200, and the height dimensions of these walls 201 define the approximate height dimension of the activity space 200 . The activity space 200 is further arranged with a bed 202 and a bookshelf 203 adjacent to the bed 202. The power supply socket 300 is fixedly arranged on the wall 201, and the socket body 301 and the microwave detector 302 of the power supply socket 300 are electrically connected to the mains circuit to allow the microwave detector 302 The detection microwave can be radiated to the active space 200 and the response echo generated in the active space 200 can be received. The electric device integrating the air conditioner 100a and the computing device 400 is hung on the wall 201, and the air conditioner 100a is electrically connected to the socket body 301 of the power supply socket 300 to allow the city Electricity is supplied to the air conditioner 100a through the socket body 301.

Referring to FIG. 4, the detection microwave radiated by the microwave detector 302 to the active space 200 can be responded to by a user to generate the response echo, and the microwave detector 302 can receive the response echo. The response echo received by the microwave detector 302 can be sent to the communication interface 403 of the computing device 400 through the communication mechanism 303 of the power supply socket 300, so as to be subsequently used by the computing device 400. The processor 401 processes. The processor 401 can determine that the behavior state of the user in the activity space 200 is a walking behavior state after performing a series of processing on the response echo. For example, the processor 401 can determine that the behavior state of the user in the activity space 200 is a walking behavior state after performing analysis processing, detection processing, and judgment processing on the response echo. At this time, the processor 401 can control the working mode of the air conditioner 100a to be the on state based on the user's walking behavior state, and the cooling temperature of the air conditioner 100a is 23°C.

Referring to FIG. 5, the detection microwave radiated by the microwave detector 302 to the active space 200 can be responded to by a user to generate the response echo, and the microwave detector 302 can receive the response echo. The response echo received by the microwave detector 302 can be sent to the communication interface 403 of the computing device 400 through the communication mechanism 303 of the power supply socket 300, so as to be subsequently used by the computing device 400. The processor 401 processes. The processor 401 can determine that the behavior state of the user in the activity space 200 is the reading behavior state after performing a series of processing on the response echo. At this time, the processor 401 can control the working mode of the air conditioner 100a to be the on state based on the user's reading behavior state, and the cooling temperature of the air conditioner 100a is 25°C.

Referring to FIG. 6, the detection microwave radiated by the microwave detector 302 to the active space 200 can be responded to by a user to generate the response echo, and the microwave detector 302 can receive the response echo. The response echo received by the microwave detector 302 can be sent to the communication interface 403 of the computing device 400 through the communication mechanism 303 of the power supply socket 300, so as to be subsequently used by the computing device 400. The processor 401 processes. The processor 401 can determine that the behavior state of the user in the activity space 200 is a sleep behavior state after performing a series of processing on the response echo. At this time, the processor 401 can control the working mode of the air conditioner 100a to be the on state based on the sleep behavior state of the user, and the cooling temperature of the air conditioner 100a is 27°C.

Referring to FIG. 7, according to another aspect of the present invention, the present invention further provides a control method 700 of the electrical equipment 100, wherein the control method 700 includes the following steps:

Step 701: After the microwave detector 302 radiates the detection microwave to the active space 200, receive the response echo generated based on the detection microwave;

Step 702: Analyze the response echo to detect the user's actions in the activity space 200;

Step 703: Determine the behavior state of the user in the activity space 200 according to the user's actions; and

Step 704: Control the working mode of the electric device 100 according to the behavior state of the user.

Those skilled in the art can understand that, in the step 701, based on the principle of the Doppler effect, when the user's body generates the response echo in response to the detection microwave, the frequency and/or phase of the microwave will fluctuate. Changes so that the fluctuating frequency and/or phase of the detection microwave are different from the fluctuating frequency and/or phase of the response echo, so that in the future, the user can be detected by analyzing the response echo. The actions of the activity space 200 are described.

In the step 702, firstly the response echoes are trended, and then the trended response echoes are classified by fluctuation frequency to analyze the response echoes, which can accurately detect that the user is in the The movement of the activity space 200, in particular, can accurately detect the user's micro movement in the activity space 200. Specifically, the way of processing the response echo by trending can reduce or even remove the interference of clutter on the specific actions of the user, so as to allow the trended response echo to pass through at least one of the filters. After the trended response echoes are classified, the user's actions can be accurately detected, especially the user's micro-movements can be accurately detected. For example, after categorizing the fluctuating frequency of the response echo that is trended, the fluctuating frequency range obtained is within 1 Hz, it can be detected that the user's action in the activity space 200 is a breathing action; After the fluctuation frequency of the response echo is classified, the fluctuation frequency range obtained is 1 Hz-3 Hz, and it can be detected that the user's action in the activity space 200 is a heartbeat action.

In addition, according to some examples of the control method 700 of the present invention, the microwave detector 302 and the socket body 301 for supplying power to the electrical equipment 100 form the power supply socket 300, which is fixedly arranged It is used to form the wall of the activity space 200, and the socket body 301 and the microwave detector 302 of the power supply socket 300 are electrically connected to a mains circuit. According to other examples of the control method 700 of the present invention, the microwave detector 302 and the socket body 301 for supplying power to the electric device 100 are mutually independent devices, so that the socket body 301 It is only used to supply power to the electrical equipment 100, and the microwave detector 302 is only used to radiate the detection microwave to the active space 200 and receive the response echo generated based on the detection microwave .

It is worth mentioning that in the step 702, trending the content of the response echo includes trending the response echo based on the amplitude change of the response echo, or based on the response echo. Trending the response echo based on the phase change of the echo, or trending the response echo based on the change in the pulse width of the response echo, or based on the response echo The response echo is trended based on the frequency change.

In the step 703, the behavior state of the user in the activity space 200 is determined according to the user's actions in a continuous time period (for example, but not limited to, 1 minute, 5 minutes, 10 minutes, etc.). For example, even if it can be detected in the step 703 that the user only has micro movements such as heartbeat and breathing in the activity space 200, if the user only has micro movements such as heartbeat and breathing in the activity space 200, If the action is an instant action or an action within a short period of time (for example, but not limited to within 10 seconds, within 20 seconds, etc.), the user's behavior state in the activity space 200 may be a sleeping behavior state or a reading behavior. If the user has only micro movements such as heartbeat and breathing in the activity space 200 for a long time, the behavior state of the user in the activity space 200 is a sleep behavior The state has the greatest possibility, and the longer the continuous time period is defined, the more likely the user's behavior state in the activity space 200 is the sleep behavior state.

It is worth mentioning that in some examples of the control method 700, the computing device 400 and the power supply socket 300 may be integrated, so that the power supply socket 300 can trend the response echo. , Analyze and process the trended response echoes to detect specific actions of the user in the activity space 200, be able to determine the behavior state of the user in the activity space 200 based on the user's actions, and be able to determine the behavior state of the user in the activity space 200 Control the working mode of the electrical equipment 100. In some examples of the control method 700, the computing device 400 and the electrical equipment 100 may be integrated, so that the electrical equipment 100 can trend the response echo and analyze the trended The response echo is analyzed and processed to detect the specific actions of the user in the activity space 200, to determine the behavior state of the user in the activity space 200 based on the user’s actions, and to control the user based on the user’s behavior state. The working mode of the electric device 100. In some examples of the control method 700, a part of the computing device 400 and the electrical equipment 100 may be integrated, and another part of the computing device 400 and the power supply socket 300 may be integrated, so that all The power supply socket 300 and the electrical equipment 100 cooperate with each other to be able to trend the response echo and analyze and process the trended response echo to detect the details of the user in the activity space 200. The action can determine the behavior state of the user in the activity space 200 based on the user's action, and can control the working mode of the electric device 100 according to the user's behavior state.

Referring to FIGS. 8 to 11, according to another aspect of the present invention, the present invention further provides the power supply socket 300, wherein the power supply socket 300 includes the socket body 301 and at least one of the socket body 301 The microwave detector 302. The socket body 301 and the microwave detector 302 of the power supply socket 300 can be electrically connected to the mains circuit, wherein the socket body 301 is configured to supply electric energy to the electric device 100, and the microwave The detector 302 is configured to radiate the detection microwave to the active space 200 and receive the response echo generated based on the detection microwave.

Further, the socket body 301 includes a socket body 3011 and a cover plate 3012 arranged on the socket body 3011, wherein when the socket body 3011 is fixedly arranged on the wall 201, the cover plate 3012 is exposed to the outside of the wall 201 to form the appearance of the power supply socket 300 in use.

The socket body 3011 has at least one set of plug receiving mechanism 30111 and a mains interface mechanism 30112, wherein the mains circuit is allowed to be connected to the mains interface mechanism 30112 of the socket body 3011, so that the socket body 301 It is electrically connected to the mains circuit. The cover 3012 has at least one set of perforations 30121, wherein the perforations 30121 of the cover 3012 correspond to the plug receiving mechanism 30111 of the socket main body 3011, so as to allow the plug of the electrical equipment 100 to pass through. The perforation 30121 of the cover 3012 extends to the plug receiving mechanism 30111 of the socket body 3011 and is received by the plug receiving mechanism 30111 of the socket body 3011 to electrically connect the electrical equipment 100 to The socket body 301 of the power supply socket 300 so that commercial power can be supplied to the electrical equipment 100 through the socket body 301.

The microwave detector 302 includes a reference board 3021, a radiation source 3022, and a driving circuit 3023. The reference board 3021 forms a reference surface 30211, and the radiation source 3022 is held on a side of the reference surface 30211. The side way is set on the reference board 3021, wherein the drive circuit 3023 is connected to the feeding point of the radiation source 3022, so that the excitation electrical signal can be supplied to the radiation source 3022 via the drive circuit 3023, The radiation source 3022 and the reference surface 30211 of the reference plate 3021 can respond to each other to radiate the detection microwave to the active space 200 and receive the response echo generated based on the detection microwave. Preferably, the driving circuit 3023 is disposed on the reference board 3021, for example, the driving circuit 3023 can be formed on the reference board 3021 through an etching process or a printing process.

Preferably, the drive circuit 3023 of the microwave detector 302 is electrically connected to the mains interface mechanism 30112 of the socket body 3011, so when the socket body 301 is electrically connected to the mains circuit, the The microwave detector 302 is electrically connected to the mains circuit at the same time. Those skilled in the art can understand that the power supply socket 300 may also be a voltage converter 304 to allow the driving circuit 3023 of the microwave detector 302 to be electrically connected to the socket via the voltage converter 304 The mains 3011 mains interface mechanism 30112. In other words, the driving circuit 3023 of the microwave detector 302 is electrically connected to the voltage converter 304, and the voltage converter 304 is electrically connected to the mains interface mechanism 30112 of the socket body 3011. Preferably, the voltage converter 304 is arranged between the socket body 3011 and the cover 3012 of the socket body 301 to hide the voltage converter 304.

In the power supply socket 300 shown in FIGS. 8 to 11, the extension direction of the radiation source 3022 of the microwave detector 302 is perpendicular to the reference plane 30211 of the reference plate 3021, so that the The microwave detector 302 may be a cylindrical antenna. Optionally, in other examples of the power supply socket 300 of the present invention, the extension direction of the radiation source 3022 of the microwave detector 302 and the reference surface 30211 of the reference plate 3021 are parallel to each other, so that The microwave detector 302 forms a flat antenna.

Preferably, the cover plate 3012 of the socket body 301 has a radiation source through hole 30122, wherein the microwave detector 302 is held between the socket body 3011 and the cover plate 3012 of the socket body 301 In addition, the radiation source 3022 of the microwave detector 302 corresponds to the radiation source through hole 30122 of the cover plate 3012, so when the microwave detector 302 is hidden inside the socket body 301 This can ensure that the microwave detector 302 reliably radiates the detection microwave to the active space 200 and reliably receives the response echo generated based on the detection microwave. More preferably, the radiation source 3022 of the microwave detector 302 extends to the radiation source through hole 30122 of the cover plate 3012. For example, in some examples of the power supply socket 300 of the present invention, the free end of the radiation source 3022 of the microwave detector 302 extends to the radiation source through hole 30122 of the cover plate 3012, so that The radiation source 3022 of the microwave detector 302 extends to the radiation source through hole 30122 of the cover plate 3012. In other examples of the power supply socket 300 of the present invention, the radiation source 3022 of the microwave detector 302 extends to the outside of the cover plate 3012 through the radiation source through hole 30122 of the cover plate 3012 It protrudes from the cover plate 3012 so that the radiation source 3022 of the microwave detector 302 extends to the radiation source through hole 30122 of the cover plate 3012.

In this specific example of the power supply socket 300 shown in FIGS. 8 to 11, the microwave detector 302 is provided in the socket body 3011, and the microwave detector 302 is held in the socket body Between 3011 and the cover 3012. Optionally, in other examples of the power supply socket 300, the microwave detector 302 is disposed on the cover plate 3012, and the microwave detector 302 is held on the socket body 3011 and the cover plate Between 3012.

Further, the power supply socket 300 includes the communication mechanism 303, wherein the communication mechanism 303 is provided in the socket body 301, and the communication mechanism 303 is electrically connected to the voltage converter 304 and is capable of communicating Ground is connected to the microwave detector 302, wherein the communication mechanism 303 is configured to transmit the response echo received by the microwave detector 302. For example, the communication mechanism 303 of the power supply socket 300 and the communication interface 403 of the computing device 400 can be communicably connected to transmit the response echo received by the microwave detector 302 to the Computing device 400.

It is worth mentioning that the type of the communication mechanism 303 is not limited in the power supply socket 300 of the present invention. For example, the communication mechanism 303 may be, but not limited to, a Bluetooth communication module.

FIG. 12 shows a modified example of the power supply socket 300, wherein the power supply socket 300 is also a wall socket, so that the power supply socket 300 can be fixedly arranged on the wall when decorating the wall, as shown in FIG. 8 The difference from the wall-type power supply socket 300 shown in FIG. 11 is that the microwave detector 302 of the power supply socket 300 shown in FIG. 12 is a flat antenna. Specifically, in this embodiment of the present invention In the example, corresponding to the microwave detector 302 configured as a flat panel antenna, the radiation source through hole 30122 is configured as a square. It is understandable that based on the penetration characteristics of the detected microwave, in some embodiments of the present invention In an example, the radiation source through hole 30122 may be set to a material that can be penetrated by microwaves, or when the socket body 301 is made of a material that can be penetrated by microwaves, the radiation source through hole 30122 may not be provided. The present invention does not limit this.

FIG. 13 shows another modified example of the power supply socket 300. Unlike the wall-type power supply socket 300 shown in FIG. 12, the power supply socket 300 shown in FIG. 13 is a conversion type. The power supply socket 300. Specifically, referring to FIG. 13, the mains interface mechanism 30112 of the socket body 3011 of the socket body 301 of the power supply socket 300 is set as a corresponding pin to be able to be inserted into an existing fixed in The jack of the wall socket.

FIG. 14 shows another modified embodiment of the power supply socket 300. The difference from the conversion type power supply socket 300 shown in FIG. 13 is that the power supply socket 300 shown in FIG. The microwave detector 302 is movably arranged on the socket body 301. Specifically, in this modified embodiment of the present invention, the microwave detector 302 is separately arranged on the outside of the socket body 301 , And are movably arranged to form a structural relationship in which the microwave detector 302 is movably integrated into the power supply socket 300, so that the coverage direction of the detection microwave in the movable space can be adjusted.

Fig. 15 shows another modified embodiment of the power supply socket. The difference from the power supply socket 300 shown in Figs. 8 to 14 is that the power supply socket shown in Fig. 15 is a power plug. Specifically, referring to FIG. 15, the mains interface mechanism 30112 of the socket body 3011 of the socket body 301 of the power supply socket 300 is configured as a wire extending from the socket body 301 and having a plug, Connect the power supply socket 300 to the mains circuit by inserting the plug into the socket of an existing wall socket, and freely adjust the coverage of the microwave detector 302 in the active space .

Those skilled in the art can understand that the above embodiments are only examples, in which the features of different embodiments can be combined with each other to obtain implementations that are easily conceivable according to the disclosure of the present invention but are not clearly indicated in the drawings.

Those skilled in the art should understand that the above description and the embodiments of the present invention shown in the accompanying drawings are only examples and do not limit the present invention. The purpose of the present invention has been completely and effectively achieved. The functions and structural principles of the present invention have been shown and explained in the embodiments. Without departing from the principles, the embodiments of the present invention may have any deformation or modification.

Claims

A control method of electrical equipment, characterized in that the control method includes the following steps:

(a) After a microwave detector radiates a detection microwave to an active space, receiving a response echo generated based on the detection microwave;

(b) Analyze the response echo to detect the user's actions in the activity space;

(c) Judging the user's behavior state in the activity space according to the user's actions; and

(d) Control the working mode of the electrical equipment according to the user's behavior state.
The control method according to claim 1, wherein said step (b) further comprises the step of:

(b.1) Trending the response echo; and

(b.2) Classify the fluctuating frequency of the response echo that is trended to analyze the response echo.
The control method according to claim 2, wherein in the step (b.1), trending the content of the response echo includes performing the response echo on the basis of the amplitude change of the response echo Trending, or trending of the response echo based on the phase change of the response echo, or trending of the response echo based on the pulse width change of the response echo Or perform trending processing on the response echo based on the frequency change of the response echo.
The control method according to claim 2, wherein in the step (b.2), the trended response echo is allowed to pass through at least one filter to classify the trended response echo Frequency of fluctuations.
The control method according to claim 4, wherein in the step (b.2), the filter is set to be trended after the trended response echo passes through the filter. The fluctuation frequency of the response echo is less than 25 Hz.
The control method according to any one of claims 1 to 5, wherein in the step (c), the behavior state of the user in the activity space is determined according to the user's actions in a continuous period of time.
The control method according to any one of claims 1 to 5, wherein in the step (a), the detection microwave is radiated to the active space through the microwave detector integrated in a power supply socket and received The response echo generated based on the probe microwave.
A control method of electrical equipment, characterized in that the control method includes the following steps:

(A) radiate a detection microwave to the active space through a microwave detector of a power outlet; and

(B) Receive a response echo generated based on the detection microwave to detect the user's action in the activity space, wherein the working mode of the electric device is associated with the user's action in the activity space.
The control method according to claim 8, wherein in the step (B), the microwave detector of the power supply socket receives the response echo generated based on the detection microwave.
The control method according to claim 9, wherein in the step (B), the power supply socket detects the user's action in the activity space by analyzing the response echo.
The control method according to claim 9, wherein in the step (B), the electric device detects the user's action in the activity space by analyzing the response echo.
The control method according to claim 10, wherein in the step (B), the power outlet determines the user's behavior state in the activity space according to the user's action, so as to allow the working mode of the electric device to be based on The user's behavior status is controlled.
The control method according to claim 11, wherein in the step (B), the electric device judges the user's behavior state in the activity space according to the user's action, so as to allow the working mode of the electric device The state is controlled based on the user's behavior.
The control method according to claim 12 or 13, wherein in the above method, the behavior state of the user in the activity space is determined based on the user's actions in at least one continuous time period.
A power supply socket, characterized in that it includes:

A socket body, wherein the socket body has a mains interface mechanism; and

At least one microwave detector, wherein the microwave detector is disposed on the socket body, wherein the microwave detector further includes a reference board, a radiation source and a driving circuit, the reference board has a reference surface, and The radiation source is arranged on the reference plate, and the radiation source and the reference surface of the reference plate can respond to each other, wherein the driving circuit is electrically connected to the feeding point of the radiation source and the The mains interface mechanism of the socket body.
The power supply socket according to claim 15, wherein the socket body comprises a socket body and a cover plate, the socket body has the mains interface mechanism and at least one set of plug receiving mechanisms, and the cover plate has at least one A set of perforations, wherein the cover plate is disposed on the socket body, and the perforation of the cover plate corresponds to the plug receiving mechanism of the socket body.
The power supply socket according to claim 16, wherein the extending direction of the radiation source of the microwave detector and the reference plane of the reference plate are parallel to each other.
The power supply socket according to claim 16, wherein the cover plate has a radiation source through hole, wherein the microwave detector is held between the socket body and the cover plate, and the microwave detector The radiation source corresponds to the radiation source through hole of the cover plate.
The power supply socket according to claim 18, wherein the radiation source of the microwave detector extends to the radiation source through hole of the cover plate.
The power supply socket according to claim 19, wherein the extension direction of the radiation source is perpendicular to the reference plane of the reference ground.
The power supply socket according to any one of claims 16 to 20, wherein the microwave detector is movably arranged on the socket body.
The power supply socket according to any one of claims 15 to 19, further comprising a voltage converter, wherein the voltage converter is electrically connected to the mains interface mechanism of the socket body, and the microwave detector The driving circuit is electrically connected to the voltage converter to allow the driving circuit of the microwave detector to be electrically connected to the mains interface mechanism of the socket body through the voltage converter.
The power supply socket according to claim 21, further comprising a voltage converter, wherein the voltage converter is electrically connected to the mains interface mechanism of the socket body, and the drive circuit of the microwave detector is It is electrically connected to the voltage converter to allow the driving circuit of the microwave detector to be electrically connected to the mains interface mechanism of the socket body through the voltage converter.
The power supply socket according to claim 22, further comprising a communication mechanism, wherein the communication mechanism is electrically connected to the voltage converter, and the communication mechanism is communicably connected to the microwave detector.
The power supply socket according to claim 23, further comprising a communication mechanism, wherein the communication mechanism is electrically connected to the voltage converter, and the communication mechanism is communicably connected to the microwave detector.
The power outlet according to claim 24, further comprising a computing device, wherein the computing device is communicably connected to the communication mechanism, and the computing device is configured to control the working mode of at least one electrical device.
The power outlet according to claim 26, wherein the computing device includes at least one processor, at least one memory, and at least one communication interface, wherein the memory stores instructions for controlling the corresponding electrical equipment, wherein The processor is configured to process instructions stored in the memory and control the communication interface to transmit corresponding instructions to the electrical equipment.
The power supply socket according to claim 27, wherein the communication interface is further configured to be able to receive a control instruction to the corresponding electrical equipment, and to access the memory after receiving the control instruction to the corresponding electrical equipment Generate the corresponding instructions.
The power outlet according to claim 27, wherein the processor includes a filter, and the filter is set to allow a fluctuation frequency of less than 25 Hz.