CN114071663B

CN114071663B - Signal processing method, router and storage medium

Info

Publication number: CN114071663B
Application number: CN202010771216.3A
Authority: CN
Inventors: 吕天榆
Original assignee: Shenzhen TCL New Technology Co Ltd
Current assignee: Shenzhen TCL New Technology Co Ltd
Priority date: 2020-08-04
Filing date: 2020-08-04
Publication date: 2024-11-22
Anticipated expiration: 2040-08-04
Also published as: CN114071663A

Abstract

The invention discloses a signal processing method, a router and a storage medium, wherein the signal processing method comprises the following steps: when the access of the terminal equipment to the wireless network set by the intelligent router is monitored, determining the equipment type of the terminal equipment; judging the use state of a user according to the equipment type of the terminal equipment, and switching a signal transmission mode based on the use state of the user; and adjusting signal transmission parameters according to the switched signal transmission modes. The invention determines the use state of the user through the network-access terminal equipment, adjusts the signal transmitting power of the router based on the use state of the user and the number of the connected terminal equipment, and reduces the power consumption of the router.

Description

Signal processing method, router and storage medium

Technical Field

The present invention relates to the field of router applications, and in particular, to a signal processing method, a router, and a storage medium.

Background

With the development of intelligent home, the life style of people is being silently changed, and more intelligent devices are connected to the home Internet of things; however, with the development of intelligent internet of things, intelligent home routing systems are also facing more and more terminal devices accessing wireless networks.

In general, an intelligent router is in a 5G and 2.4G strong coverage network mode under the condition that there is a device connection, so that the intelligent router has unstable operation due to high power consumption for a long time, for example: the phenomenon of broken net occurs; how to reduce the power consumption of an intelligent router system has become a problem to be solved in the current internet of things technology.

Accordingly, the prior art is still in need of improvement and development.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a signal processing method, a router and a storage medium, wherein the use state of a user is determined through terminal equipment accessing to the network, and the signal transmitting power of the router is adjusted based on the use state of the user so as to reduce the power consumption of the router.

The technical scheme adopted for solving the technical problems is as follows:

in a first aspect, the present invention provides a signal processing method, wherein the signal processing method includes the steps of:

when the access of the terminal equipment to the wireless network set by the intelligent router is monitored, determining the equipment type of the terminal equipment;

Judging the use state of a user according to the equipment type of the terminal equipment, and switching a signal transmission mode based on the use state of the user;

and adjusting signal transmission parameters according to the switched signal transmission modes.

Further, the method further comprises the following steps:

and receiving a user instruction, and starting to monitor the networking state of the terminal equipment connected with the intelligent router according to the user instruction.

Further, when the access of the terminal equipment to the wireless network set by the intelligent router is monitored, determining the equipment type of the terminal equipment, specifically comprising the following steps:

When the access of the terminal equipment to the wireless network set by the intelligent router is monitored, acquiring equipment information of the terminal equipment;

and determining the equipment type of the terminal equipment according to the equipment information.

Further, the terminal device includes: heart rate sensor device and temperature sensor device.

Further, when the terminal device is the heart rate sensor device, the method judges a use state of a user according to a device type of the terminal device, and switches a signal transmission mode based on the use state of the user, and specifically includes the following steps:

When the terminal equipment is heart rate sensor equipment, acquiring heartbeat data of the user;

Judging whether the heartbeat data is larger than a preset heartbeat threshold value or not;

when the heartbeat data is larger than the preset heartbeat threshold value, entering a user movement mode;

and when the heartbeat data is smaller than the preset heartbeat threshold value, entering a user dormancy mode.

Further, when the terminal device is the heart rate sensor device, the signal transmission parameter is adjusted according to the switched signal transmission mode, and the method specifically includes the following steps:

When entering the user mobile mode, accumulating and increasing the radiation amplification coefficient according to the increase of the number of the access devices;

when the user sleep mode is entered, the radiation amplification factor is cumulatively reduced according to the reduction of the number of access devices.

Further, when the terminal device is the temperature sensor device, the method judges a use state of a user according to a device type of the terminal device, and switches a signal transmission mode based on the use state of the user, specifically including the following steps:

when the terminal equipment is temperature sensor equipment, acquiring body temperature data of the user;

Judging whether the body temperature data of the user is larger than a preset body temperature threshold value or not;

when the body temperature data of the user is larger than the preset body temperature threshold value, entering a normal mode;

and when the body temperature data of the user is smaller than the preset body temperature threshold value, entering a user sleep mode.

Further, when the terminal device is the temperature sensor device, the signal transmission parameter is adjusted according to the switched signal transmission mode, and the method specifically includes the following steps:

When entering the normal mode, accumulating and increasing the radiation amplification factor according to the increase of the number of the access devices;

In a second aspect, the present invention further provides a router, which includes a processor, and a memory connected to the processor, where the memory stores a signal processing program, where the signal processing program is executed by the processor to implement the operations of the signal processing method according to the first aspect.

In a third aspect, the present invention also provides a storage medium storing a signal processing program for implementing the operations of the signal processing method according to the first aspect when executed by a processor.

The technical scheme adopted by the invention has the following effects:

The invention determines the use state of the user through the network-access terminal equipment, adjusts the signal transmitting power of the router based on the use state of the user and the number of the connected terminal equipment, and reduces the power consumption of the router.

Drawings

Fig. 1 is a flowchart of a signal processing method in an embodiment of the present invention.

Fig. 2 is a functional schematic diagram of a router in an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clear and clear, the present invention will be further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Example 1

Along with the development of intelligent wireless technology, connection between internet of things equipment and terminal equipment becomes possible, the 5G technology discovers that the intelligent router is in a strong signal coverage state of 5G/2.4G under the condition that whether equipment is connected or not, and therefore the phenomenon that the intelligent router is unstable in operation due to high long-time power consumption of the intelligent router.

For example, there is a wireless router system in home, and the wireless router system is connected with mobile terminals such as a smart bracelet 1, a smart bracelet 2, a smart phone 1, a smart phone 2 and the like, no matter whether a wireless network is used or not, the router is in a high-radiation working state of 2.4G/5G, and the high-radiation signal state for a long time causes the power consumption of the router system to be very high, so that an unstable phenomenon or a disconnection phenomenon occurs in the whole wireless network system.

The main purpose of this embodiment is to: the signal processing method is provided, and under the condition that a plurality of terminal devices are connected with a wireless network, the normal working state of the router is ensured, the phenomenon that the router is disconnected is avoided, and the power consumption of the router is reduced.

As shown in fig. 1, in one implementation manner of the present embodiment, the signal processing method includes the following steps:

and step S100, when the access of the terminal equipment to the wireless network set by the intelligent router is monitored, determining the equipment type of the terminal equipment.

In this embodiment, the signal processing method is applied to a router, where a wireless network set by the router is connected to a plurality of terminal devices, and the terminal devices include, but are not limited to: and terminal equipment with wireless networking function such as a smart bracelet, a smart phone and a tablet personal computer.

The present embodiment classifies a plurality of the terminal devices into two types, one is a terminal device (e.g., a smart bracelet) provided with a heart rate sensor, and the type of terminal device may acquire heart rate data of a user through the heart rate sensor and determine a use state of the user based on the heart rate data; another is a terminal device (e.g., a smart phone) provided with a temperature sensor, through which the type of terminal device can acquire temperature data of a user and determine a use state of the user based on the temperature data.

In this embodiment, after the router is started, a wireless network may be created in a system setting of the router according to an operation of the user; and when the wireless network is created, a user instruction is also received, and the network connection state of the terminal equipment connected with the intelligent router is started to be monitored according to the user instruction, namely, the user can send out an instruction to start a network monitoring function, and only in the state that the network monitoring function is started, the router monitors the equipment type of the terminal equipment of the wireless network connected with the router. By monitoring the networking status of the terminal devices, it can be determined whether all terminal devices within the signal coverage of the router (terminal devices with WiFi turned on) are networked, i.e. whether all terminal devices have access to the wireless network of the router.

I.e. before said step S100, further comprises:

And S001, receiving a user instruction, and starting to monitor the networking state of the terminal equipment connected with the intelligent router according to the user instruction.

In this embodiment, after the network monitoring function is set and started, when it is monitored that the terminal device accesses the wireless network set by the intelligent router, device information of the terminal device is obtained, and then a device type of the terminal device is determined according to the device information; the device information comprises information such as a device name and a device model, whether the terminal device is heart rate sensor device is determined according to the device name and the device model, or whether the terminal device is temperature sensor device is determined according to the device name and the device model.

Specifically, when monitoring terminal equipment in a designated area, the router monitors the terminal equipment with the WiFi function through the network monitoring function, and screens the terminal equipment accessed to the wireless network from the terminal equipment with the WiFi function; after screening to obtain terminal equipment accessed to a wireless network, acquiring corresponding equipment information from the connection information of the terminal equipment; and then, determining the type of the terminal equipment according to the equipment name and the equipment model in the acquired equipment information, namely determining whether the terminal equipment is equipment with a heart rate sensor or equipment with a temperature sensor.

When the type of the terminal equipment which is accessed to the network is determined, uploading the equipment name and the equipment model corresponding to the terminal equipment to a server, judging by the server, and further determining the type of the terminal equipment according to the judging result of the server; of course, a corresponding device type table may also be set in the router, and the type of the terminal device may be determined according to the comparison result by comparing the obtained device information (device name and device model) with the device information in the device type table.

Namely, the step S100 specifically includes the following steps:

step S110, when the terminal equipment is monitored to be accessed to a wireless network set by an intelligent router, acquiring equipment information of the terminal equipment;

And step S120, determining the equipment type of the terminal equipment according to the equipment information.

In this embodiment, the network connection state of each terminal device is monitored, and the device type of the terminal device that has access to the network is determined, so that the manner of acquiring the user use state is determined according to the device type of the terminal device, and the user use state is accurately acquired according to the type of the terminal device.

As shown in fig. 1, in one implementation manner of the present embodiment, the signal processing method further includes the following steps:

step S200, judging the use state of the user according to the equipment type of the terminal equipment, and switching the signal transmission mode based on the use state of the user.

In this embodiment, after determining the device type of the terminal device, the router determines a usage state of a user according to the device type of the terminal device, and switches a signal transmission mode based on the usage state of the user; the use state of the user can be divided into a normal use state and a dormant state.

Specifically, when switching signal transmission modes, different signal transmission modes are switched according to the device type of the terminal device.

When the terminal equipment is the heart rate sensor equipment, the router acquires the heart rate data of the user recorded in the terminal equipment, and then determines the use state of the user according to the heart rate data, namely, determines whether the user is in a dormant state according to the heart rate data.

After the heartbeat data are acquired, the router judges whether the heartbeat data are larger than a preset heartbeat threshold value, and if the heartbeat data are larger than the preset heartbeat threshold value, a user moving mode is entered; for example, whether the heartbeat data is greater than 70 times/min is judged, if the heartbeat data is greater than 70 times/min and is between 70 times/min and 120 times/min, the heartbeat data indicates that the user is in a normal use state currently, and at the moment, the router enters a user movement mode.

If the heartbeat data is smaller than the preset heartbeat threshold value, entering a user dormancy mode; for example, whether the heartbeat data is smaller than 70 times/min is judged, if the heartbeat data is smaller than 70 times/min and is between 50 times/min and 70 times/min, the heartbeat data indicates that the user is in a dormant state currently, and at the moment, the router enters a user dormant mode.

Namely, when the terminal device is the heart rate sensor device, the step S200 specifically includes the following steps:

Step S211, when the terminal equipment is heart rate sensor equipment, obtaining the heartbeat data of the user;

step S212, judging whether the heartbeat data is larger than a preset heartbeat threshold value;

step S213, when the heartbeat data is larger than the preset heartbeat threshold value, entering a user movement mode;

step S214, when the heartbeat data is smaller than the preset heartbeat threshold value, entering a user sleep mode.

Specifically, in another device type, the use state of the user is judged by acquiring body temperature data of the user; when the terminal equipment is temperature sensor equipment, the router acquires the body temperature data of the user, and then judges whether the user is in a dormant state or not according to the body temperature data.

When judging the use state of the user, judging whether the body temperature data of the user is larger than a preset body temperature threshold value, and if the body temperature data of the user is larger than the preset body temperature threshold value, entering a normal mode; for example, whether the body temperature data is greater than 32 ℃ is determined, if the body temperature data is greater than 32 ℃ and is between 32 ℃ and 37 ℃, the router enters a normal mode when the router is in a normal use state currently.

If the body temperature data of the user is smaller than the preset body temperature threshold value, entering a user dormancy mode; for example, whether the body temperature data is greater than 32 ℃ is determined, if the body temperature data is less than 32 ℃ and less than 20 ℃, the router enters a user sleep mode when the router is not in a normal use state currently.

Namely, when the terminal device is the temperature sensor device, the step S200 specifically includes the following steps:

Step S221, when the terminal equipment is temperature sensor equipment, acquiring body temperature data of the user;

Step S222, judging whether the body temperature data of the user is larger than a preset body temperature threshold value or not;

Step S223, when the body temperature data of the user is larger than the preset body temperature threshold value, entering a normal mode;

Step S224, when the body temperature data of the user is smaller than the preset body temperature threshold, entering a user sleep mode.

According to the embodiment, after the type of the terminal equipment is determined, different user state judging conditions are set according to the types of different terminal equipment, so that different router signal transmitting modes are entered according to the acquired actual data and judging conditions, and flexible switching of the router signal transmitting modes is realized.

Step S300, adjusting signal transmission parameters according to the switched signal transmission modes.

In this embodiment, after the router switches the signal transmission modes, different signal transmission parameters are set according to the different signal transmission modes, and then the set signal transmission parameters are stored in different memories.

Specifically, when the terminal device is the heart rate sensor device, the router adds up the radiation amplification factor according to the increase of the number of access devices under the condition of entering the user movement mode, and stores the added up radiation amplification factor into the first memory.

For example, in the user mobile mode, the 5G radiation power amplification factor of the router may be set to 1, and when the router detects that a mobile phone device joins the wireless network in the subsequent use of the wireless network of the router, the 5G radiation power amplification factor of the router is increased (i.e. 1 is added on the basis of the current 5G radiation power amplification factor) in an accumulated manner and stored in the first memory.

Specifically, when the terminal device is the heart rate sensor device, under the condition of entering the user sleep mode, the router accumulatively reduces the radiation amplification factor according to the reduction of the number of access devices, and stores the accumulated radiation amplification factor into the first memory.

For example, in the user sleep mode, the 5G radiated power amplification factor of the router may be set to-1, i.e., the user stops using the mobile phone mode; when a subsequent user uses the wireless network of the router, if the router detects that a mobile phone device is separated from the wireless network, the 5G radiation power amplification factor of the router is reduced in an accumulated mode (namely, 1 is reduced on the basis of the current 5G radiation power amplification factor), and the 5G radiation power amplification factor is stored in a first memory.

Namely, when the terminal device is the heart rate sensor device, the step S300 specifically includes the following steps:

Step S311, when entering the user mobile mode, accumulating and increasing the radiation amplification factor according to the increase of the number of the access devices, and storing the accumulated radiation amplification factor into a first memory;

Step S312, when entering the user sleep mode, accumulating and reducing the radiation amplification factor according to the reduction of the number of access devices, and storing the accumulated radiation amplification factor in the first memory.

In this embodiment, when the terminal device is the temperature sensor device, in the case of entering the normal mode, the router accumulates and increases the radiation amplification factor according to the increase of the number of access devices, and stores the accumulated radiation amplification factor in the second memory.

For example, in the normal mode, the 2.4G radiation power amplification factor of the router may be set to 1, i.e. the user normally uses the mobile phone mode; when the subsequent user uses the wireless network of the router, if the router detects that a mobile phone device joins the wireless network, the 2.4G radiation power amplification factor of the router is increased in an accumulated manner (namely, 1 is added on the basis of the current 2.4G radiation power amplification factor), and the 2.4G radiation power amplification factor is stored in a second memory.

Specifically, when the terminal device is the temperature sensor device, under the condition of entering the user sleep mode, the router accumulatively reduces the radiation amplification factor according to the reduction of the number of access devices, and stores the accumulated radiation amplification factor into the second memory.

For example, in the user sleep mode, the 2.4G radiated power amplification factor of the router may be set to-1, i.e., the user stops using the mobile phone mode; when the subsequent user uses the wireless network of the router, if the router detects that the mobile phone equipment is separated from the wireless network, the 2.4G radiation power amplification factor of the router is reduced in an accumulated mode (namely, reduced by 1 on the basis of the current 2.4G radiation power amplification factor) and is stored in a second memory.

Namely, when the terminal device is the temperature sensor device, the step S300 specifically includes the following steps:

Step S321, when entering the normal mode, accumulating and increasing the radiation amplification factor according to the increase of the number of the access devices, and storing the accumulated radiation amplification factor into a second memory;

Step S22, when entering the user sleep mode, accumulating and reducing the radiation amplification factor according to the reduction of the number of access devices, and storing the accumulated radiation amplification factor into the second memory.

In this embodiment, after setting the signal transmission parameters of the router, the router adds the value in the first memory to the value in the second memory, and then stores the added value in the third memory.

Among the values stored in the third memory, if the value is smaller than 0, the router is in the sleep mode currently; and if the numerical value is greater than 1, indicating that the router is currently in a normal working mode.

And in the process of processing the transmitting power and reducing the power consumption by the router, the router acquires the value which is less than 0 and is identified in the third memory, and starts a corresponding power consumption reduction algorithm module so as to process the operation power consumption by the power consumption reduction algorithm module.

The router creates different sleep modes for different terminal devices.

First category: the router starts and creates a 5G dynamic dormancy mode, acquires a 5G radiation power amplification factor in the first memory, and performs the following processing according to the 5G radiation power amplification factor:

1. a deep sleep mode (the value is smaller than 1), the router acquires the coefficient number of the first memory, if the coefficient number is more than one time of the equipment number connected with a wireless network, the working mode of the router is set to be the deep sleep mode, and the power amplifier value of the 5G transmitting antenna is set to be 0; after the setting is completed, the mark 1 is set and stored in the fourth memory.

2. A moderate sleep mode (the value is smaller than 1), the router acquires the coefficient number of the first memory, if the coefficient number is approximately equal to the equipment number connected with a wireless network, the working mode of the router is set to be the moderate sleep mode, and the power amplifier value of the 5G transmitting antenna is set to be the value radiation of the first memory; after the setting is completed, the mark 2 is set and stored in the fifth memory.

The second category: the router starts and creates a 2.4G dynamic sleep mode, acquires a 2.4 radiation power amplification factor in the second memory, and performs the following processing according to the 2.4G radiation power amplification factor:

1. A deep sleep mode (the value is smaller than 1), the router acquires the coefficient number of the second memory, if the coefficient number is more than one time of the equipment number connected with the wireless network, the working mode of the router is set to be the deep sleep mode, and the power amplifier value of the 2.4G transmitting antenna is set to be 0; after the setting is completed, the identification 1 is set and stored in the sixth memory.

2. A moderate sleep mode (the value is smaller than 1), the router acquires the coefficient number of the second memory, if the coefficient number is approximately equal to the equipment number connected with a wireless network, the working mode of the router is set to be the moderate sleep mode, and the power amplifier value of the 2.4G transmitting antenna is set to be the value radiation of the second memory; after the setting is completed, the mark 2 is set and stored in the seventh memory.

After low power consumption calculation and processing, the router starts a corresponding display module to display information such as a current mode, a device name, power consumption and the like.

Specifically, in the deep sleep mode (5G portion), the router obtains information such as an identifier and a 5G device name in the fourth memory, obtains sleep to reduce power consumption, and displays the obtained information content on a screen connected to the router for display.

In the moderate sleep mode (5G part), the router acquires information such as the identifier of the fifth memory, the name of the 5G device and the like, acquires sleep to reduce power consumption, and displays the acquired information content on a screen connected with the router for display.

Specifically, in the deep sleep mode (2.4G portion), the router obtains information such as the identifier and the name of the 2.4G device in the sixth memory, obtains sleep to reduce power consumption, and displays the obtained information content on a screen connected with the router for display.

In the moderate sleep mode (2.4G part), the router acquires information such as the identifier of the seventy-five memory, the name of the 2.4G device and the like, acquires sleep to reduce power consumption, and displays the acquired information content on a screen connected with the router for display.

In the embodiment, the use state of the user is determined through the terminal equipment accessing the network, and the signal transmitting power of the router is adjusted based on the use state of the user and the number of the connected terminal equipment, so that the power consumption of the router is reduced.

Example two

As shown in fig. 2, the present embodiment provides a router, which includes a processor 10, and a memory 20 connected to the processor 10, where the memory 20 stores a signal processing program, and the signal processing program is used to implement the operations of the signal processing method according to the first embodiment when executed by the processor 10; as described in detail above.

Example III

The present embodiment provides a storage medium storing a signal processing program for implementing the operations of the signal processing method according to the first embodiment when executed by a processor; as described in detail above.

In summary, the present invention determines the use status of the user through the terminal device accessing the network, and adjusts the signal transmitting power of the router based on the use status of the user and the number of the connected terminal devices, thereby reducing the power consumption of the router.

Of course, those skilled in the art will appreciate that implementing all or part of the above-described methods may be implemented by a computer program for instructing relevant hardware (such as a processor, a controller, etc.), where the program may be stored in a computer-readable storage medium, and where the program may include the steps of the above-described method embodiments when executed. The storage medium may be a memory, a magnetic disk, an optical disk, or the like.

It is to be understood that the invention is not limited in its application to the examples described above, but is capable of modification and variation in light of the above teachings by those skilled in the art, and that all such modifications and variations are intended to be included within the scope of the appended claims.

Claims

1. A signal processing method, characterized in that the signal processing method comprises the steps of:

When the access of the terminal equipment to the wireless network set by the intelligent router is monitored, determining the equipment type of the terminal equipment; the terminal device includes: a heart rate sensor device and a temperature sensor device;

Judging the use state of a user according to the equipment type of the terminal equipment, and switching a signal transmission mode based on the use state of the user; the signal transmission mode comprises a user mobile mode, a user dormancy mode and a normal mode;

adjusting signal transmission parameters according to the switched signal transmission modes, including:

When the terminal equipment is the heart rate sensor equipment and enters the user movement mode, setting a radiation amplification coefficient to be 1, accumulating and increasing the radiation amplification coefficient according to the increase of the number of access equipment, and storing the accumulated radiation amplification coefficient into a first memory;

Setting the radiation amplification factor to be-1 when entering the user sleep mode, accumulating and reducing the radiation amplification factor according to the reduction of the number of access equipment, and storing the accumulated radiation amplification factor into the first memory;

When the terminal equipment is temperature sensor equipment and enters the normal mode, setting the radiation amplification factor to be 1, accumulating the radiation amplification factor according to the increase of the number of access equipment, and storing the accumulated radiation amplification factor into a second memory;

setting the radiation amplification factor to-1 when entering the user sleep mode, accumulating and reducing the radiation amplification factor according to the reduction of the number of access equipment, and storing the accumulated radiation amplification factor into the second memory;

Adding the numerical value in the first memory to the numerical value in the second memory, and storing the added numerical value in a third memory, wherein if the numerical value in the third memory is greater than 1, the router is in a normal working mode currently; and if the numerical value in the third memory is smaller than 0, the router is in the sleep mode currently, and the power consumption reduction algorithm module is started to process the running power consumption.

2. The signal processing method according to claim 1, wherein when it is monitored that the terminal device accesses the wireless network set by the intelligent router, determining the device type of the terminal device further includes:

3. The signal processing method according to claim 1, wherein when it is monitored that the terminal device accesses the wireless network set by the intelligent router, determining the device type of the terminal device specifically includes the following steps:

4. The signal processing method according to claim 1, wherein when the terminal device is the heart rate sensor device, the method judges a use state of a user according to a device type of the terminal device, and switches a signal transmission mode based on the use state of the user, specifically comprising the steps of:

5. The signal processing method according to claim 1, wherein when the terminal device is the temperature sensor device, the method judges a use state of a user according to a device type of the terminal device, and switches a signal transmission mode based on the use state of the user, specifically comprising the steps of:

6. A router comprising a processor and a memory coupled to the processor, the memory storing a signal processing program that, when executed by the processor, is operable to implement the operations of the signal processing method of any of claims 1-5.

7. A storage medium storing a signal processing program which, when executed by a processor, is adapted to carry out the operations of the signal processing method according to any one of claims 1 to 5.