CN111885447A

CN111885447A - Electronic device, control method thereof, control device thereof, and readable storage medium

Info

Publication number: CN111885447A
Application number: CN202010687686.1A
Authority: CN
Inventors: 赵祥军
Original assignee: Goertek Techology Co Ltd
Current assignee: Goertek Techology Co Ltd
Priority date: 2020-07-16
Filing date: 2020-07-16
Publication date: 2020-11-03
Anticipated expiration: 2040-07-16
Also published as: CN111885447B

Abstract

The invention discloses an electronic equipment control method, which comprises the following steps: acquiring characteristic parameters of an application scene corresponding to the current working state of the electronic equipment; the characteristic parameters of the application scene comprise personnel information in a space where the electronic equipment is located and/or interaction state information between the electronic equipment and the wireless communication equipment; when the personnel information and/or the interaction state information meet the set conditions of state switching, determining a target working state corresponding to the personnel information and/or the interaction state information; controlling the electronic equipment to be switched from the current working state to the target working state; wherein, different target operating states correspond to different energy consumptions of the electronic device. The invention also discloses an electronic equipment control device, electronic equipment and a readable storage medium. The invention aims to realize effective consideration of meeting the use requirements of users and saving energy.

Description

Electronic device, control method thereof, control device thereof, and readable storage medium

Technical Field

The present invention relates to the field of electronic device technologies, and in particular, to an electronic device control method, an electronic device control apparatus, an electronic device, and a readable storage medium.

Background

The field of electronic equipment has developed to be mature nowadays, and more electronic equipment can be brought into the lives of people to provide great convenience. In order to ensure the endurance of the electronic device and the user requirement, the electronic device is generally set with a plurality of working states, for example, working states such as a sleep state and an operating state can be set in the intelligent sound box, most functions can be closed in the sleep state to save energy, and most functions can be opened in the operating state to ensure that the intelligent sound box can meet the user requirement.

However, at present, the switching between different working states of the electronic device is generally timed or manually triggered by a user, the electronic device cannot be automatically switched to the running state in time when the user needs to use the electronic device, which affects the satisfaction of the user's requirements, and the electronic device also cannot be automatically switched to the dormant state in time when the user does not need to use the electronic device, which results in unnecessary power consumption. Therefore, the current electronic equipment cannot meet the use requirements of users and effectively take energy conservation into consideration.

Disclosure of Invention

The invention mainly aims to provide an electronic equipment control method, aiming at effectively meeting the use requirements of users and saving energy.

In order to achieve the above object, the present invention provides an electronic device control method, including:

acquiring characteristic parameters of an application scene corresponding to the current working state of the electronic equipment; the characteristic parameters of the application scene comprise personnel information in a space where the electronic equipment is located and/or interaction state information between the electronic equipment and the wireless communication equipment;

when the personnel information and/or the interaction state information meet set conditions of state switching, determining a target working state corresponding to the personnel information and/or the interaction state information;

controlling the electronic equipment to be switched from a current working state to the target working state;

wherein the different target operating states correspond to different energy consumptions of the electronic device.

Optionally, the step of obtaining the characteristic parameter of the application scene corresponding to the current working state of the electronic device includes:

when the current working state is a dormant state, acquiring scanning state information corresponding to scanning operation currently executed on wireless communication equipment by the electronic equipment as the interaction state information;

when the personnel information and/or the interaction state information meet set conditions of state switching, the step of determining a target working state corresponding to the personnel information and/or the interaction state information comprises the following steps:

when the scanning state information is that the electronic equipment scans the wireless communication equipment, determining that the interaction state information meets a set condition of state switching, and determining a first running state corresponding to the scanning state information as the target working state;

and the energy consumption corresponding to the first running state is greater than the energy consumption corresponding to the dormant state.

Optionally, the step of acquiring the current scanning status information of the electronic device on the wireless communication device includes:

acquiring the people number change characteristic information of the space where the electronic equipment is located;

when the number of people is increased, controlling the electronic equipment to increase the scanning frequency of the wireless communication equipment to perform scanning operation;

and taking the scanning result of the scanning operation corresponding to the scanning frequency as the scanning state information.

Optionally, the step of obtaining the people number change feature information of the space where the electronic device is located includes:

sequentially acquiring first temperature detection information of a space where the electronic equipment is located;

determining the number variation trend of objects with the temperature in the human body temperature range in the space where the electronic equipment is located according to the first temperature detection information acquired successively;

and taking the number change trend as the people number change characteristic information.

when the current working state is a first running state, acquiring communication state information of the electronic equipment and wireless communication equipment as the interaction state information;

when the communication state information is disconnected, determining that the interaction state information meets a set condition of state switching, and determining a second running state corresponding to the communication state information as the target working state; and the energy consumption corresponding to the first operation state is greater than the energy consumption corresponding to the second operation state.

when the current working state is a second running state, acquiring scanning state information corresponding to scanning operation currently executed on wireless communication equipment by the electronic equipment and duration time for which the electronic equipment does not scan the wireless communication equipment as the interaction state information;

when the personnel information and/or the interaction state information are matched with corresponding set conditions, the step of determining the target working state corresponding to the personnel information and/or the interaction state information comprises the following steps:

when the duration reaches a set duration, determining that the interaction state information meets the set condition of state switching, and determining a third running state corresponding to the duration as the target working state; the energy consumption corresponding to the second operation state is greater than the energy consumption corresponding to the third operation state;

when the scanning state information is that the electronic equipment scans the wireless communication equipment, determining that the interaction state information meets a set condition of state switching, and determining a first running state corresponding to the scanning state information as the target working state; and the energy consumption corresponding to the first operation state is greater than the energy consumption corresponding to the second operation state.

when the current working state is a third running state, acquiring scanning state information corresponding to scanning operation currently executed on wireless communication equipment by the electronic equipment as the interaction state information, and acquiring the number of people in the space where the electronic equipment is located as the personnel information;

when the scanning state information is that the electronic equipment does not scan the wireless communication equipment and the number of people is less than or equal to the set number of people, determining that the personnel information and the interaction state information accord with the set condition of state switching, and determining the dormant state corresponding to the number of people and the scanning state information as the target working state; the energy consumption corresponding to the third running state is greater than the energy consumption corresponding to the dormant state;

when the scanning state information is that the electronic equipment scans the wireless communication equipment, determining that the interaction state information meets a set condition of state switching, and taking a first running state corresponding to the scanning state information as the target working state to be a first running state; and the energy consumption corresponding to the first operation state is greater than the energy consumption corresponding to the third operation state.

Optionally, the step of obtaining the number of people in the space where the electronic device is located includes:

acquiring second temperature detection information of a space where the electronic equipment is located;

and determining the number of objects with the temperature in the human body temperature range in the space where the electronic equipment is located according to the second temperature detection information, and taking the number as the number of people.

In order to achieve the above object, the present application also proposes an electronic device control apparatus including: a memory, a processor and an electronic device control program stored on the memory and executable on the processor, the electronic device control program, when executed by the processor, implementing the steps of the electronic device control method as claimed in any one of the above.

In addition, in order to achieve the above object, the present application also proposes an electronic device including the electronic device control apparatus as described above.

Optionally, the electronic device further includes a wireless communication module and a human body information detection module, and both the wireless communication module and the human body information detection module are connected to the electronic device control apparatus.

Further, in order to achieve the above object, the present application also proposes a readable storage medium having stored thereon an electronic device control program which, when executed by a processor, realizes the steps of the electronic device control method according to any one of the above.

The invention provides an electronic equipment control method, which is used for acquiring characteristic parameters of an application scene corresponding to the current working state of electronic equipment, wherein the acquired characteristic parameters of the application scene comprise personnel information in a space where the electronic equipment is located and/or interaction state information between the electronic equipment and wireless communication equipment, and when the acquired personnel information and/or the interaction state information meet set conditions of state switching, a target working state corresponding to the personnel information and/or the interaction state information is determined, and the electronic equipment is controlled to be switched from the current working state to the target working state. The characteristic parameters of the application scene can accurately represent the use requirements of the user on the electronic equipment, and the corresponding target working state is determined based on the representation, so that the electronic equipment can be timely and automatically switched to the energy consumption state matched with the use requirements of the user without user operation or waiting for set time length due to different energy consumptions of the electronic equipment corresponding to different target working states, and the effective consideration of meeting the use requirements of the user and saving energy is realized.

Drawings

Fig. 1 is a schematic diagram of a hardware structure involved in the operation of an embodiment of the electronic device control apparatus according to the present invention;

FIG. 2 is a flowchart illustrating an embodiment of a method for controlling an electronic device according to the present invention;

FIG. 3 is a flowchart illustrating a control method of an electronic device according to another embodiment of the present invention;

FIG. 4 is a flowchart illustrating a control method of an electronic device according to another embodiment of the present invention;

FIG. 5 is a flowchart illustrating a control method of an electronic device according to another embodiment of the present invention;

FIG. 6 is a flowchart illustrating a control method of an electronic device according to yet another embodiment of the present invention;

fig. 7 is a schematic diagram of the switching direction and the corresponding setting conditions for state switching when the electronic device control method of the present invention is applied to switching between different operating states of the electronic device.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The main solution of the embodiment of the invention is as follows: acquiring characteristic parameters of an application scene corresponding to the current working state of the electronic equipment; the characteristic parameters of the application scene comprise personnel information in a space where the electronic equipment is located and/or interaction state information between the electronic equipment and the wireless communication equipment; when the personnel information and/or the interaction state information meet set conditions of state switching, determining a target working state corresponding to the personnel information and/or the interaction state information; controlling the electronic equipment to be switched from a current working state to the target working state; wherein the different target operating states correspond to different energy consumptions of the electronic device.

In the prior art, the switching between different working states of the electronic equipment is generally timed or manually triggered by a user, the electronic equipment cannot be timely and automatically switched to the running state when the user needs to use, so that the user requirements are met, and the electronic equipment also cannot be timely and automatically switched to the dormant state when the user does not need to use, so that unnecessary electric energy is consumed. Therefore, the current electronic equipment cannot meet the use requirements of users and effectively take energy conservation into consideration.

The invention provides the solution, and aims to realize effective consideration of meeting the use requirements of users and saving energy.

The embodiment of the invention provides electronic equipment. Specifically, in this embodiment, the electronic device is specifically a sound box. In other embodiments, the electronic device can be configured as other types of devices (such as a headset) according to actual needs.

In the present embodiment, the electronic device includes a wireless communication module 1 and a human body information detection module 2 in addition to a functional module (e.g., an audio module in a speaker box) that is required to implement a specific function. Specifically, the wireless communication module 1 is mainly used for wireless communication connection between the electronic device and an external device. The human body information detection module 2 is mainly used for detecting human body information in a space where the electronic device is located, and may specifically be an infrared sensor, a human body detection radar, and the like. In this embodiment, the wireless communication module 1 may specifically include a bluetooth module and a WIFI module. The Bluetooth module further comprises a low-power Bluetooth module and a traditional Bluetooth module, and the energy consumption of the low-power Bluetooth module is smaller than that of the traditional Bluetooth module.

Further, in this embodiment, the electronic device may further include some or all of the following operation modules 3: microprocessor (MPU), Digital Signal Processor (DSP), acoustic doppler flow profiler (ADCP), and telephony function modules (e.g., HSP, HFP, etc.).

Further, an embodiment of the present invention further provides an electronic device control apparatus, configured to control switching of operating states of the electronic device. In the present embodiment, the electronic device control apparatus is built in the electronic device. In other embodiments, the electronic device control apparatus may be further configured independently of the electronic device according to actual needs.

In an embodiment of the present invention, referring to fig. 1, an electronic device control apparatus includes: a processor 1001 (e.g., CPU), memory 1002, etc. The memory 1002 may be a high-speed RAM memory or a non-volatile memory (e.g., a disk memory). The memory 1002 may alternatively be a storage device separate from the processor 1001. In one embodiment, the microprocessor and the digital signal processor may be integrated with the processor 1001 to form a processing module.

The memory 1002, the wireless communication module 1, the human body information detection module 2 and the operation module 3 are all connected to the processor 1001.

Those skilled in the art will appreciate that the configuration of the device shown in fig. 1 is not intended to be limiting of the device and may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components.

As shown in fig. 1, the memory 1002, which is a readable storage medium, may include an electronic device control program therein. In the apparatus shown in fig. 1, the processor 1001 may be configured to call an electronic device control program stored in the memory 1002 and perform operations of the steps related to the electronic device control method in the following embodiments.

The embodiment of the invention also provides an electronic equipment control method, which is used for controlling the switching of the working state of the electronic equipment.

Referring to fig. 2, an embodiment of a method for controlling an electronic device according to the present application is provided. In this embodiment, the electronic device control method includes:

step S10, acquiring characteristic parameters of an application scene corresponding to the current working state of the electronic equipment; the characteristic parameters of the application scene comprise personnel information in a space where the electronic equipment is located and/or interaction state information between the electronic equipment and the wireless communication equipment;

the characteristic parameters of the application scenario specifically refer to characteristic parameters that characterize the current application situation or application requirement of the electronic device. In this embodiment, the characteristic parameters of the application scenario specifically include information of a person in a space where the electronic device is located and/or information of an interaction state between the electronic device and the wireless communication device. In other embodiments, in addition to the interaction state information and the person information, the feature parameters of the application scenario may further include more parameters according to actual situations (such as the type of the electronic device, different environments in which the electronic device is currently located, and the like), for example, the type of the scenario in which the electronic device is located (such as a meeting room, a bedroom, and the like).

The person information specifically refers to information characterizing the person in the space where the electronic device is located. The personnel information specifically comprises the number of people, the change trend of the number of people, the type of people and the like. The interaction state information specifically refers to feature information interacted between the electronic device and other wireless communication devices. The interaction state information may specifically include scan state information obtained by the electronic device scanning the other wireless communication device, communication state information of a communication situation between the electronic device and the other wireless communication device, interaction data information of an information transmission situation between the electronic device and the other wireless communication device, and the like.

Obtaining characteristic parameters of an application scene, such as interactive state information in the characteristic parameters of the application scene, by obtaining operating state parameters of a module (such as a wireless communication module) related to the application scene on the electronic equipment; in addition, the electronic device may further be provided with a detection module (e.g., a human body detection module) specially used for detecting a situation in the application scene, and obtain a characteristic parameter of the application scene, such as personnel information in the characteristic parameter of the application scene, based on data detected by the detection module.

The electronic device has different operating states, and in this embodiment, the different operating states of the electronic device are specifically divided based on different energy consumptions thereof. For example, the operating state of the electronic device specifically includes a sleep state, an active state, a ready state, and a standby state, where energy consumption of the electronic device corresponding to the operating state is greater than energy consumption of the electronic device corresponding to the ready state, energy consumption of the electronic device corresponding to the ready state is greater than energy consumption of the electronic device corresponding to the standby state, and energy consumption of the electronic device corresponding to the standby state is greater than energy consumption of the electronic device corresponding to the sleep state.

Different working states correspond to different characteristic parameters of the application scene. For example, when the working state is the running state, the ready state, or the dormant state, the interaction state information may be obtained as the characteristic parameter of the application scenario, and different working states may further correspond to different types of interaction state information; when the working state is the standby state, the interaction state information and the personnel information can be acquired as the characteristic parameters of the application scene.

Step S20, when the personnel information and/or the interaction state information meet the set conditions of state switching, determining the target working state corresponding to the personnel information and/or the interaction state information;

the set condition of state switching refers to a target condition which is required to be achieved by the personnel information and/or the interaction state information when the current working state is switched to other working states. The setting conditions for switching the states may be different based on different working states allowed to be switched by the current working state of the electronic device, and based on this, the setting conditions for switching the states may be obtained based on the current working state of the electronic device, and if the current working states are different and the working states allowed to be switched are different, the obtained setting conditions for switching the states are different.

When the personnel information and/or the interaction state information meet the set conditions of state switching, it is indicated that the current working state is not matched with the use requirements of the user on the electronic equipment, and the working state of the electronic equipment needs to be switched to other working states. In different working states, the difference of the personnel information and/or the interaction state information indicates that the use requirements of the users are different, and the corresponding working states matched with the use requirements of the users are different, so that the working state corresponding to the personnel information and/or the interaction state information acquired in the current working state can be determined as the target working state.

Step S30, controlling the electronic equipment to switch from the current working state to the target working state; wherein the different target operating states correspond to different energy consumptions of the electronic device.

Specifically, the process of switching the working state may specifically include: determining at least one first target module which needs to operate in the electronic equipment in the target working state, taking modules except the first target module in the electronic equipment as second target modules, keeping the first target module which is opened in the current working state in an opening state or opening the first target module which is closed in the current working state, and simultaneously closing the second target module which is opened in the current working state or keeping the second target module which is closed in the current working state in a closing state, thereby enabling the electronic equipment to reach the target working state. In addition, the process of switching the working state may specifically include: and determining target operation parameters of different modules in the target working state electronic equipment, and controlling the modules to adjust the current operation parameters to the target operation parameters so as to enable the electronic equipment to reach the target working state.

The method for controlling the electronic equipment obtains the characteristic parameters of the application scene corresponding to the current working state of the electronic equipment, wherein the obtained characteristic parameters of the application scene comprise personnel information in a space where the electronic equipment is located and/or interaction state information between the electronic equipment and wireless communication equipment, determines a target working state corresponding to the personnel information and/or the interaction state information when the obtained personnel information and/or the interaction state information meet set conditions of state switching, and controls the electronic equipment to be switched from the current working state to the target working state. The characteristic parameters of the application scene can accurately represent the use requirements of the user on the electronic equipment, and the corresponding target working state is determined based on the representation, so that the electronic equipment can be timely and automatically switched to the energy consumption state matched with the use requirements of the user without user operation or waiting for set time length due to different energy consumptions of the electronic equipment corresponding to different target working states, and the effective consideration of meeting the use requirements of the user and saving energy is realized.

Further, based on the above embodiment, another embodiment of the electronic device control method of the present application is provided. In this embodiment, referring to fig. 3, the step S10 includes:

step S11, when the current working state is the dormant state, acquiring scanning state information corresponding to a scanning operation currently performed on the wireless communication device by the electronic device, as the interaction state information;

when the electronic device is in a dormant state, only the scanning module (such as a low-power-consumption Bluetooth module) of the wireless communication device can be kept on, and other functional modules are turned off. The scanning module continuously or at intervals sets time to transmit detection signals to scan the wireless communication module in the space where the electronic equipment is located. Here, the wireless communication device may be a designated device or an arbitrary device. And generating corresponding scanning state information based on the scanning result of the scanning module. Specifically, when the scanning module scans the physical address of the device, it may be determined that the scanning status information of the wireless communication device is that the electronic device currently scans the wireless communication device; when the scanning module does not scan the physical address of the device, it may be determined that the scanning status information of the wireless communication device is that the electronic device does not scan the wireless communication device.

Specifically, because the scanning module consumes more energy when the scanning module continuously scans or the interval time for sending the detection signal is too short, and the electronic device may delay the perception of other wireless communication devices when the interval time for sending the detection signal is too long, in another embodiment, the electronic device may further include a human body information detection module in addition to the wireless communication module. When the electronic device is in a dormant state, only the scanning module (such as a low-power-consumption Bluetooth module) and the human body information detection module of the wireless communication device can be kept on, and other functional modules are turned off. Based on this, the step of acquiring the scanning state information includes: acquiring the people number change characteristic information of the space where the electronic equipment is located; when the number of people is increased, controlling the electronic equipment to increase the scanning frequency of the wireless communication equipment to perform scanning operation; and taking the scanning result of the scanning operation corresponding to the scanning frequency as the scanning state information. Specifically, when the electronic device enters the sleep state, the scanning module may be controlled to scan the wireless communication device at a lower scanning frequency, so as to implement the scanning operation of the electronic device on the wireless communication device. And meanwhile, data detected by the human body information detection module are acquired in real time, the number of people in the electronic equipment and the change characteristics of the number of people along with time are determined based on the acquired data, when the change characteristic information of the number of people is that the number of people is increased, the scanning module is controlled to increase the scanning frequency to scan the wireless communication equipment in the space, and scanning state information is obtained according to the scanning result after the scanning frequency is increased. Wherein, increasing the scanning frequency means controlling the scanning module to send out the detection information to detect the wireless communication device at a shorter time interval than the current time interval. Specifically, the number of people in the space can be continuously acquired, and the scanning module of the scanning module can be continuously adjusted. In addition, if no wireless communication equipment is scanned within the set time after the scanning frequency is increased, the scanning module can be controlled to adjust to the original lower scanning frequency for scanning so as to save energy consumption. The scanning frequency of the electronic equipment for executing scanning operation is adjusted in real time based on the number change characteristic information of the space pairs, so that the follow-up state switching can be timely carried out based on accurate scanning state information, meanwhile, the energy consumption of a scanning module in a continuous operation state or an overhigh scanning frequency state is reduced, and the low energy consumption of the electronic equipment in a dormant state is ensured.

In this embodiment, the human body information detection module is specifically an infrared sensor, and based on this, the process of obtaining the number-of-people change feature information of the space where the electronic device is located may be: sequentially acquiring first temperature detection information of a space where the electronic equipment is located; determining the number variation trend of objects with the temperature in the human body temperature range in the space where the electronic equipment is located according to the first temperature detection information acquired successively; and taking the number change trend as the people number change characteristic information. Specifically, data detected by the infrared sensor is acquired as first sub-temperature detection information at a first time, data detected by the infrared sensor is acquired as second sub-temperature detection information at a second time, the first moment is earlier than the second moment, the first sub-temperature detection information and the second sub-temperature detection information can be respectively identified based on the human body temperature interval, the first number of the objects located in the human body temperature interval in the space where the electronic equipment is located at the first moment is determined based on the identification result of the first sub-temperature detection information, the second number of the objects located in the human body temperature interval in the space where the electronic equipment is located at the second moment is determined based on the identification result of the second sub-temperature detection information, and if the second number is larger than the first number, the number change trend can be determined to be increased, and the number of people in the space is indicated to be increased, the number change characteristic information can be determined to be the number of people to be increased; if the second number is less than or equal to the first number, the trend of the number change is determined to be not increased, which indicates that the number of people in the space is possibly reduced or not changed, the characteristic information of the change of the number of people is determined to be that the number of people is not increased.

Further, based on the step S11, when the current operating state of the electronic device is the sleep state, the step S20 includes:

step S21, when the scanning status information indicates that the electronic device scans the wireless communication device, determining that the interaction status information meets a set condition for status switching, and determining a first operating status corresponding to the scanning status information as the target operating status;

The first operating state is specifically an operating state allowed to be switched by the electronic device in the dormant state, specifically refers to a state in which most functional modules of the electronic device are turned on, and may be defined as an active state. For example, when the electronic device is a sound box, the first operating state is a state in which the user can use the sound box to play audio.

When the current working state is the dormant state, the electronic device scans the wireless communication device, which indicates that there may be a user turning on the wireless communication device and needs to control the operation of the electronic device through the wireless communication device, for example, needs to play audio data in the wireless communication device by using a sound box. Based on this, the electronic apparatus can scan the setting condition for switching the state corresponding to the wireless communication apparatus as the sleep state. When the scanning state information is that the electronic device scans the wireless communication device, the first operation state can be adapted to the user use requirement of the electronic device corresponding to the scanning state information, and therefore the first operation state can be used as the target working state.

And controlling the electronic equipment to switch from the dormant state to the first running state. In a first operating state, a large number of modules of the electronic device are switched on, in particular the energy supply of the main control module. Specifically, in this embodiment, when entering the first operating state, the control electronic device turns on the conventional bluetooth module and the WIFI module that are used for performing communication connection with the wireless communication device, and turns off the human body information detection module (such as the infrared sensor). Under the first running state, the electronic equipment can establish wireless communication connection with the wireless communication equipment through wireless communication modules such as a traditional Bluetooth module and a WIFI module, and the wireless communication equipment can control the electronic equipment to run based on the wireless communication connection. On the basis, the functional modules such as the MPU, the DSP, the ADCP, the HSP, the HFP, the audio transmission module and the like can be controlled to be started when the electronic equipment is connected with the wireless communication equipment.

In this embodiment, when the electronic device is in the sleep state, whether the state switching of the electronic device is needed is determined based on the scanning state information of the electronic device to the wireless communication device, and when the electronic device scans the wireless communication device, the electronic device is automatically switched from the sleep state to the first operation state, so that the electronic device is automatically wakened up, and the electronic device can timely enter the normal operation state, thereby facilitating the use of a user.

Further, based on any of the above embodiments, a further embodiment of the electronic device control method of the present application is provided. In this embodiment, referring to fig. 4, the step S10 includes:

step S12, when the current operating state is the first operating state, acquiring communication state information of the electronic device and the wireless communication device as the interaction state information;

the first operating state here and the first operating state in the above-described embodiment may specifically refer to the same state. The communication state information refers to state information characterizing a wireless connection situation between the electronic device and the wireless communication device. The communication status information may specifically include disconnection and connection.

The communication status information may be obtained by acquiring current operating parameters of a wireless communication module in the electronic device. In the first operating state, the communication state information may characterize whether the user uses the electronic device, and based on this, when the current operating state of the electronic device is the first operating state, it indicates that the user has a need to use the electronic device by using the wireless communication device, so that the communication state information is obtained as a characteristic parameter of an application scene corresponding to the current operating state.

Further, based on the step S12, when the current operating state of the electronic device is the first operating state, the step S20 includes:

step S22, when the communication status information is disconnected, determining that the interaction status information meets a set condition for status switching, and determining a second operation status corresponding to the communication status information as the target operating status; and the energy consumption corresponding to the first operation state is greater than the energy consumption corresponding to the second operation state.

The second operating state is specifically an operating state that the electronic device is allowed to switch in the first operating state, specifically refers to a state in which the electronic device is disconnected from the wireless communication device and a functional module in the electronic device that is not related to the wireless communication device is closed, and may be defined as a ready state of the electronic device.

When the current working state is the first running state, the communication connection between the electronic equipment and the wireless communication equipment is disconnected, which indicates that the user does not need to use the wireless communication equipment to control the electronic equipment. Based on this, disconnection of communication between the electronic apparatus and the wireless communication apparatus can be set as a setting condition for state switching corresponding to the first operation state. When the communication state information is disconnected, the second operation state can be adapted to the user use requirement of the electronic equipment corresponding to the current communication state information, and therefore the second operation state can be used as the target working state.

The control electronics switch from a first operating state to a second operating state. In the second operation state, most of the functional modules of the electronic device that can be implemented only when the electronic device is connected to the wireless communication device are turned off, for example, ADCP, HSP, HFP, audio transmission module, etc. in the sound box may be turned off, and only modules related to the connection between the wireless communication device and the electronic device, such as the human body information detection module (e.g., infrared sensor) and the scanning module (e.g., BLE module), may be turned on.

In this embodiment, when the electronic device is in the first operating state, it is determined whether the state switching of the electronic device is required based on the communication state information between the electronic device and the wireless communication device, and when the communication state information is disconnected, the electronic device is automatically switched from the first operating state to the second operating state with lower energy consumption, so as to save energy consumption of the electronic device. In addition, because the module related to communication is controlled to be started in the second operation state, the device can be quickly restored to the first operation state when the electronic device and the wireless communication device are restored to be connected while saving energy.

It should be noted that, after the step S21, step S12 may be executed to implement switching to a state with lower power consumption after the electronic device automatically wakes up when the user does not need to use the electronic device, so as to save energy.

Further, based on any of the above embodiments, a further embodiment of the electronic device control method is provided. In this embodiment, referring to fig. 5, the step S10 further includes:

step S13, when the current operating state is the second operating state, acquiring scanning state information corresponding to a scanning operation that is currently performed on the wireless communication device by the electronic device, and a duration that the wireless communication device is not scanned by the electronic device, as the interaction state information;

the second operating state here may specifically refer to the same state as the second operating state in the above-described embodiment. In the second operation state, the scanning state information may represent whether the user has a demand for using the electronic device, and the duration of the wireless communication device being not scanned may represent the demand for using the electronic device. Therefore, when the current operation state of the electronic device is the second operation state, it is indicated that the user does not connect the wireless communication device with the electronic device to use the electronic device, and therefore the scanning state information and the duration of the wireless communication device which is not scanned are obtained as the characteristic parameters of the application scene corresponding to the current operation state and used as the representation of the user on the use requirement condition of the electronic device.

Further, based on the step S13, when the current operating state of the electronic device is the second operating state, the step S20 includes:

when the duration reaches a set duration, performing step S23; when the scanning status information indicates that the electronic device has scanned the wireless communication device, step S24 is executed.

Step S23, determining that the interaction state information meets the set condition of state switching, and determining a third running state corresponding to the duration as the target working state; the energy consumption corresponding to the second operation state is greater than the energy consumption corresponding to the third operation state;

step S24, determining that the interaction state information meets a set condition for state switching, and determining a first operation state corresponding to the scanning state information as the target operating state; and the energy consumption corresponding to the first operation state is greater than the energy consumption corresponding to the second operation state.

The third operation state and the first operation state are both the operation states allowed to be switched by the electronic equipment in the second operation state. The third operating state specifically refers to a state in which the electronic device is disconnected from the wireless communication device and the function of the electronic device related to the data processing transmitted by the wireless communication device is turned off, and may be defined as a standby state of the electronic device.

In a second operating state, the scanning module and the human body information detection module can operate to scan the wireless communication device in a manner similar to that in a reference sleep state. The electronic device scans the wireless communication device again, which indicates that the user needs to control the electronic device by using the wireless communication device, and based on this, the electronic device can scan the wireless communication device as a setting condition for switching one of the states corresponding to the second operation state. In addition, because the communication between the electronic device and the wireless communication device is already in the disconnected state when the electronic device enters the second operation state, if the wireless communication between the two devices is not recovered for a long time, it indicates that the possibility that the user uses the electronic device is low, and based on this, a set time length can be preset, and the duration that the electronic device does not scan the wireless communication device reaches the set time length is taken as a set condition for switching another state corresponding to the second operation state. When the scanning state information indicates that the electronic equipment scans the wireless communication equipment, the first running state can be adapted to the user using requirement of the electronic equipment corresponding to the current scanning state information, so that the first running state can be used as a target working state; when the duration of the wireless communication device is not scanned by the electronic device to reach the set duration, the sleep state can be adapted to the user use requirement of the electronic device corresponding to the disconnected duration, and therefore the sleep state can be used as the target working state. It should be noted that the electronic device needs to scan the physical address of the wireless communication device first, and then establish a wireless communication connection with the wireless communication device based on the scanned address.

And controlling the electronic equipment to be switched from the second running state to the first running state, specifically, when the electronic equipment is a sound box, recovering the running of modules such as ADCP (advanced digital content control protocol), HSP (high frequency range), HFP (HFP) and audio transmission modules in the sound box, and closing a scanning module and a human body information detection module corresponding to the detection application scene characteristic information.

And controlling the electronic equipment to be switched from the second operation state to the third operation state, specifically, closing the DSP module, keeping most work of the MPU, and simultaneously keeping the work of the scanning module and the human body information detection module.

In this embodiment, when the electronic device is in the second operating state, it is determined whether the state switching of the electronic device is required based on the scanning state information corresponding to the scanning operation performed by the electronic device on the wireless communication device and the duration of the non-scanning of the wireless communication device. When the scanning state information is that the electronic equipment scans the wireless communication equipment, the user can be considered to possibly use the electronic equipment, and the electronic equipment is automatically switched from the second running state to the first running state with more started functional modules, so that the electronic equipment can be quickly restored to the normal running state, and the subsequent use of the user is facilitated. In addition, when the duration that the electronic device does not scan the wireless communication device reaches the set duration, it indicates that the user has a low demand for the use of the electronic device, and the electronic device is automatically switched to a third operating state with lower energy consumption, so as to further save the energy consumption of the electronic device.

It should be noted that, after the step S22, the step S13 may be executed, and after the step S24, the step S12 may be executed again, so that the electronic device may gradually reduce the energy consumption of the electronic device after the electronic device is disconnected from the wireless communication device and if the electronic device is not connected, and if the electronic device and the wireless communication device interact again, the electronic device may be switched to a normal operation state in time to ensure the user requirement, thereby ensuring that the electronic device can meet the user requirement and save energy regardless of the operation state of the electronic device.

Further, based on any of the above embodiments, another embodiment of the electronic device control method of the present application is provided. In this embodiment, referring to fig. 6, the step S10 further includes:

step S14, when the current operating state is the third operating state, acquiring scanning state information corresponding to a scanning operation currently performed by the electronic device on the wireless communication device as the interaction state information, and acquiring the number of people in the space where the electronic device is located as the people information;

the third operating state here may specifically refer to the same state as the third operating state in the above-described embodiment. In a third operation state, the scanning state information can represent whether the user has a use requirement on the electronic equipment, and the number of people in the electronic equipment can represent whether the user has a use requirement on the electronic equipment. Based on this, the current operating state of the electronic device is the third operating state, which indicates that the user has not connected the wireless communication device with the electronic device for a long time to use the electronic device, so that the scanning state information and the number of people in the space where the electronic device is located are obtained as the characteristic parameters of the application scene corresponding to the current operating state.

Specifically, the step of obtaining the number of people in the space where the electronic device is located includes: acquiring second temperature detection information of a space where the electronic equipment is located; and determining the number of objects with the temperature in the human body temperature range in the space where the electronic equipment is located according to the second temperature detection information, and taking the number as the number of people. Specifically, the second temperature detection information is obtained by acquiring detection data of an infrared sensor on the electronic device. And analyzing the second temperature detection information based on the human body temperature interval, wherein the number of the objects with the analyzed temperature in the human body temperature interval is used as the number of people in the space.

Further, based on the step S14, when the current operating state of the electronic device is the third operating state, the step S20 includes:

when the scanning status information indicates that the electronic device does not scan the wireless communication device and the number of people is less than or equal to a set number of people, executing step S25; when the scanning status information indicates that the electronic device has scanned the wireless communication device, step S26 is executed.

Step S25, determining that the personnel information and the interaction state information meet the set conditions of state switching, and determining the sleep state corresponding to the personnel number and the scanning state information as the target working state; the energy consumption corresponding to the third running state is greater than the energy consumption corresponding to the dormant state;

step S26, determining that the interaction state information meets a set condition for state switching, and taking a first operation state corresponding to the scanning state information as the target operation state as a first operation state; and the energy consumption corresponding to the first operation state is greater than the energy consumption corresponding to the third operation state.

The dormant state and the first operation state are both operation states which are allowed to be switched by the electronic equipment in the third operation state. Here, the sleep state and the sleep state in the above embodiment may specifically refer to the same operating state.

In a third operating state, the scanning module and the human body information detecting module can operate to scan the wireless communication device in a manner similar to that in the reference sleep state. The electronic device scans the wireless communication device again, which indicates that the user needs to control the electronic device by using the wireless communication device, and based on this, the electronic device can scan the wireless communication device as a setting condition for switching one of the states corresponding to the third operation state. In addition, since the communication between the electronic device and the wireless communication device is already in a state of long-term disconnection when the electronic device enters the third operation state, if the number of people in the space where the electronic device is located is extremely small, for example, the number of people is 0, it indicates that the user does not need to use the electronic device, based on which the set number of people can be preset, and the number of people less than or equal to the set number of people is set as the setting condition for switching the other state corresponding to the third operation state. When the scanning state information is that the electronic equipment does not scan the wireless communication equipment and the number of people is less than or equal to the set number of people, the dormant state can be adapted to the current scanning state information and the user using requirements of the electronic equipment corresponding to the number of people, so that the dormant state can be used as a target working state; when the electronic device scans the wireless communication device, the first operation state can be adapted to the user usage requirement of the electronic device corresponding to the current scanning state information, and therefore the first operation state can be used as the target operation state.

And controlling the electronic equipment to be switched from the third running state to the first running state, specifically, when the electronic equipment is a sound box, recovering the running of modules such as ADCP (advanced digital content control protocol), HSP (high frequency range), HFP (HFP) and audio transmission modules in the sound box, and closing a scanning module and a human body information detection module corresponding to the detection application scene characteristic information.

And controlling the electronic equipment to be switched from the third running state to the dormant state, only keeping the work of the scanning module and the human body information detection module, and stopping the functions of all other modules.

In this embodiment, when the electronic device is in the third operating state, it is determined whether the state switching of the electronic device is required based on the scanning state information corresponding to the scanning operation performed by the electronic device on the wireless communication device and the number of people in the space where the electronic device is located. When the scanning state information is that the electronic equipment scans the wireless communication equipment, the user can be considered to possibly use the electronic equipment, and the electronic equipment is automatically switched from the third running state to the first running state which meets the starting of most modules for realizing normal functions, so that the electronic equipment can be quickly restored to the normal running state, and the subsequent use of the user is facilitated. In addition, when the number of people in the space where the electronic equipment is located is very small, the fact that the user does not need to use the electronic equipment is indicated, and the electronic equipment is automatically switched to the dormant state with the lowest energy consumption, so that the energy consumption of the electronic equipment is further saved.

It should be noted that, after the step S23, the step S14 may be executed, and after the step S26, the step S12 may be executed again, so that after the electronic device is disconnected from the wireless communication device, if the electronic device is not connected and the number of users is reduced or even reduced to 0, the energy consumption of the electronic device is gradually reduced, and if the electronic device and the wireless communication device interact again, the electronic device is timely switched to a normal operation state to ensure the user requirement, thereby ensuring that the electronic device can meet the user requirement and save energy in any operating state.

Further, the switching of the electronic device in four different operating states based on the scheme involved in the above embodiment is more intuitively explained with reference to fig. 7. Specifically, arrows indicate the switching directions between different operating states, and straight lines indicate the setting conditions for switching the states corresponding to the different state switching processes. As can be seen from fig. 7, the electronic device can adapt to the change of the characteristic parameters of different application scenarios, and automatically switch between different operating states, where the energy consumption in the active state is greater than that in the ready state, the energy consumption in the ready state is greater than that in the standby state, and the energy consumption in the standby state is greater than that in the dormant state. When the demand of a user on the use of the electronic equipment is gradually reduced, the electronic equipment can be switched from active mode, ready mode, standby mode and dormant mode step by step, and the effective reduction of energy consumption is realized; in addition, when the situation that the user needs to use the electronic equipment can be monitored in any one of the ready state, the standby state and the dormant state, the electronic equipment can be switched to the active state in time, so that the user can use the electronic equipment conveniently, and the use requirement of the user is met.

In addition, an embodiment of the present invention further provides a readable storage medium, where an electronic device control program is stored on the readable storage medium, and when the electronic device control program is executed by a processor, the electronic device control program implements the relevant steps of any embodiment of the electronic device control method.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) as described above and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. An electronic device control method, characterized by comprising:

2. The method for controlling electronic equipment according to claim 1, wherein the step of obtaining the characteristic parameters of the application scenario corresponding to the current operating state of the electronic equipment comprises:

3. The electronic device control method of claim 2, wherein the step of obtaining the current scanning status information of the electronic device for the wireless communication device comprises:

4. The electronic device control method according to claim 3, wherein the step of acquiring the person number change feature information of the space where the electronic device is located includes:

5. The method for controlling electronic equipment according to claim 1, wherein the step of obtaining the characteristic parameters of the application scenario corresponding to the current operating state of the electronic equipment comprises:

6. The method for controlling electronic equipment according to claim 1, wherein the step of obtaining the characteristic parameters of the application scenario corresponding to the current operating state of the electronic equipment comprises:

7. The method for controlling electronic equipment according to claim 1, wherein the step of obtaining the characteristic parameters of the application scenario corresponding to the current operating state of the electronic equipment comprises:

8. The electronic device control method of claim 7, wherein the step of obtaining the number of people in the space where the electronic device is located comprises:

9. An electronic device control apparatus, characterized in that the electronic device control apparatus comprises: memory, a processor and an electronic device control program stored on the memory and executable on the processor, the electronic device control program, when executed by the processor, implementing the steps of the electronic device control method according to any one of claims 1 to 8.

10. An electronic device characterized in that the electronic device comprises the electronic device control apparatus according to claim 9.

11. The electronic device according to claim 10, wherein the electronic device comprises a wireless communication module and a human body information detection module, and both the wireless communication module and the human body information detection module are connected with the electronic device control apparatus.

12. A readable storage medium, characterized in that the readable storage medium has stored thereon an electronic device control program that, when executed by a processor, implements the steps of the electronic device control method according to any one of claims 1 to 8.