CN111161523A

CN111161523A - Processing method and device

Info

Publication number: CN111161523A
Application number: CN201911416384.4A
Authority: CN
Inventors: 徐杰
Original assignee: Lenovo Beijing Ltd
Current assignee: Lenovo Beijing Ltd
Priority date: 2019-12-31
Filing date: 2019-12-31
Publication date: 2020-05-15

Abstract

The application discloses a processing method and a processing device, which are used for controlling electronic equipment through sound waves. The method comprises the following steps: obtaining a control signal for controlling at least one second electronic device in case it is determined that the processing condition is met; processing the control signal into a first acoustic signal; outputting the first sound wave signal to at least one second electronic device along with a second sound wave signal output by the first electronic device in a determined output mode so as to control the second electronic device to execute corresponding operation at least based on the control signal; wherein the first acoustic signal has a frequency greater than the second acoustic signal. By adopting the scheme provided by the application, the effect of controlling the electronic equipment through the sound waves is realized, a wireless communication environment is not needed, a plurality of instructions are not needed to be generated by the first electronic equipment and are respectively sent to all the second electronic equipment, the sound waves are only needed to be output, the requirements on the communication environment and the performance of the first electronic equipment are effectively reduced, and the cost is saved.

Description

Processing method and device

Technical Field

The present disclosure relates to the field of acoustic wave identification, and in particular, to a processing method and apparatus.

Background

With the continuous development of intelligent communication technology, the control technology of the device is more and more mature, for example, the wireless communication technology can be used for controlling other various devices by the master control device, so that the devices can complete corresponding actions according to the specified processing and manufacturing process requirements. Therefore, the automation degree of the equipment can be greatly improved, the product quality and the production efficiency are effectively ensured, and the economic benefit is improved. Thus. The equipment control technology is widely applied in the production process and other fields.

At present, because the technique of controlling equipment needs total control equipment to carry out radio communication with other equipment, therefore, requirement to communication environment is higher, secondly, need total control equipment statistics all rather than radio communication's equipment, then generate many control command, send for different equipment, it is also higher to total control equipment performance requirement, the hypothesis can pass through sound wave signal controlgear, then total control equipment just need not carry out radio communication with equipment and is connected, also need not to generate many control command and control different equipment, and only need send away the sound wave, just can control the equipment in the sound wave effective transmission range, can effectively reduce the requirement to communication environment and equipment performance, and the cost is saved. In addition, in some specific occasions, such as a concert, a evening party and the like, if the electronic equipment carried by the user can be controlled through the master control equipment, the light effect of the light stick can be well replaced, the waste of the light stick is effectively reduced, and the cost is further saved. Therefore, how to provide a method for controlling an electronic device by using sound waves is a technical problem to be solved.

Disclosure of Invention

The embodiment of the application provides the following technical scheme:

a processing method, applied to a first electronic device, the method comprising:

obtaining a control signal for controlling at least one second electronic device in case it is determined that the processing condition is met;

processing the control signal into a first acoustic signal;

outputting the first sound wave signal to the at least one second electronic device along with a second sound wave signal output by the first electronic device in a determined output mode so as to control the second electronic device to execute corresponding operation at least based on the control signal;

wherein the first acoustic signal has a frequency greater than the second acoustic signal.

In one embodiment, determining that the processing condition is satisfied includes:

determining that the processing condition is satisfied based on at least one of spatial environment information in which the first electronic device is located, runtime information, connection information with the second electronic device, and received operation information.

In one embodiment, obtaining a control signal for controlling at least a second electronic device comprises:

obtaining the control signal at least based on instruction information input to the first electronic device; or the like, or, alternatively,

acquiring quantity information of second electronic equipment, and acquiring a corresponding control signal based on the quantity information; or the like, or, alternatively,

obtaining output parameters of a second acoustic signal, and generating a corresponding control signal at least based on the output parameters; or the like, or, alternatively,

and obtaining the environment information of the second electronic equipment, and generating a corresponding control signal based on the environment information.

In one embodiment, the outputting the first acoustic signal with the second acoustic signal output by the first electronic device to the at least one second electronic device in a determined output manner includes:

outputting the first sound wave signal to the second electronic device through a first output channel of the first electronic device, and outputting the second sound wave signal to the second electronic device through a second output channel of the first electronic device; or the like, or, alternatively,

and adjusting the power and/or frequency of the first sound wave signal and/or the second sound wave signal at least based on the space environment information where the first electronic equipment is located, and outputting the adjusted first sound wave signal and second sound wave signal to the second electronic equipment.

In one embodiment, said controlling said second electronic device to perform a corresponding operation based on at least said control signal comprises:

under the condition that the second electronic equipment has the first number, controlling the first number of the second electronic equipment to synchronously output the first form of light effect based on the control signal;

and in the case that the second electronic equipment has a second number, controlling the second electronic equipment to asynchronously output a second form of light effect based on the control signal.

The application also provides a processing method applied to a second electronic device, and the method comprises the following steps:

the method comprises the steps of receiving a first sound wave signal and a second sound wave signal output by first electronic equipment, and executing corresponding operation based on the first sound wave signal, wherein the frequency of the first sound wave signal is greater than that of the second sound wave signal.

In one embodiment, further comprising:

the second electronic equipment at the first position outputs the received first sound wave signal and/or second sound wave signal to the second electronic equipment at the second position, so that the second electronic equipment at the second position executes corresponding operation;

and the first distance between the second electronic equipment at the first position and the first electronic equipment is smaller than the second distance between the second electronic equipment at the second position and the first electronic equipment.

In one embodiment, the second electronic device performing the corresponding operations includes:

under the condition that the second electronic equipment has the first number, synchronously outputting a first form of light effect;

in the case where the second electronic device has a second number, asynchronously outputting a second form of light effect.

The present application further provides a processing apparatus, the apparatus comprising:

the obtaining module is used for obtaining a control signal for controlling at least one second electronic device under the condition that the processing condition is determined to be met;

the processing module is used for processing the control signal into a first sound wave signal;

the output module is used for outputting the first sound wave signal to the at least one second electronic device along with a second sound wave signal output by the first electronic device in a determined output mode so as to control the second electronic device to execute corresponding operation at least based on the control signal;

In one embodiment, an obtaining module includes:

a first obtaining submodule for obtaining the control signal based on at least instruction information input to the first electronic device;

the second obtaining submodule is used for obtaining the quantity information of the second electronic equipment and obtaining a corresponding control signal based on the quantity information;

the third obtaining submodule is used for obtaining an output parameter of the second acoustic signal and generating a corresponding control signal at least based on the output parameter;

and the fourth obtaining submodule is used for obtaining the environment information of the second electronic equipment and generating a corresponding control signal based on the environment information.

In one embodiment, the output module includes:

the first output sub-module is used for outputting the first sound wave signal to the second electronic equipment through a first output sound channel of the first electronic equipment and outputting the second sound wave signal to the second electronic equipment through a second output sound channel of the first electronic equipment; or the like, or, alternatively,

and the second output sub-module is used for adjusting the power and/or frequency of the first sound wave signal and/or the second sound wave signal at least based on the space environment information where the first electronic equipment is located, and outputting the adjusted first sound wave signal and second sound wave signal to the second electronic equipment.

In one embodiment, the output module further includes:

the first control submodule is used for controlling the first number of the second electronic devices to synchronously output the first form of light effect based on the control signal under the condition that the second electronic devices have the first number;

and the second control submodule is used for controlling a second quantity of the second electronic equipment to asynchronously output the light effect in the second form based on the control signal under the condition that the second electronic equipment has the second quantity.

the receiving module is used for receiving a first sound wave signal and a second sound wave signal output by first electronic equipment and executing corresponding operation based on the first sound wave signal, wherein the frequency of the first sound wave signal is greater than that of the second sound wave signal.

In one embodiment, the apparatus further comprises:

The present application further provides a first electronic device, comprising:

a processor;

a memory for storing processor-executable instructions;

wherein the processor executes the executable instructions to implement the steps of:

processing the control signal into a first acoustic signal;

The present application further provides a second electronic device, comprising:

a processor;

a memory for storing processor-executable instructions;

The present application also provides a non-transitory readable storage medium having instructions that, when executed by a processor within a device, enable the device to perform a method of processing, the method comprising:

processing the control signal into a first acoustic signal;

Drawings

FIG. 1A is a flow chart of a processing method in an embodiment of the present application;

FIG. 1B is a flowchart illustrating a scenario for implementing a concert recourse according to an embodiment of the present application;

FIG. 1C is a schematic diagram of interaction between a first electronic device and a second electronic device, and the second electronic device in different positions;

FIG. 2 is a flow chart of a processing method in another embodiment of the present application;

FIG. 3 is a flow chart of a processing method in another embodiment of the present application;

fig. 4 is a block diagram of a processing device according to an embodiment of the present application.

Detailed Description

Various aspects and features of the present application are described herein with reference to the drawings.

It will be understood that various modifications may be made to the embodiments of the present application. Accordingly, the foregoing description should not be construed as limiting, but merely as exemplifications of embodiments. Those skilled in the art will envision other modifications within the scope and spirit of the application.

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the application and, together with a general description of the application given above and the detailed description of the embodiments given below, serve to explain the principles of the application.

These and other characteristics of the present application will become apparent from the following description of preferred forms of embodiment, given as non-limiting examples, with reference to the attached drawings.

It should also be understood that, although the present application has been described with reference to some specific examples, a person of skill in the art shall certainly be able to achieve many other equivalent forms of application, having the characteristics as set forth in the claims and hence all coming within the field of protection defined thereby.

The above and other aspects, features and advantages of the present application will become more apparent in view of the following detailed description when taken in conjunction with the accompanying drawings.

Specific embodiments of the present application are described hereinafter with reference to the accompanying drawings; however, it is to be understood that the disclosed embodiments are merely exemplary of the application, which can be embodied in various forms. Well-known and/or repeated functions and constructions are not described in detail to avoid obscuring the application of unnecessary or unnecessary detail. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present application in virtually any appropriately detailed structure.

The specification may use the phrases "in one embodiment," "in another embodiment," "in yet another embodiment," or "in other embodiments," which may each refer to one or more of the same or different embodiments in accordance with the application.

Fig. 1A is a flowchart of a processing method according to an embodiment of the present application, where the method is applicable to a first electronic device, and the first electronic device may be a master device in a device control scenario, and the method includes the following steps S11-S13:

in step S11, in a case where it is determined that the processing condition is satisfied, obtaining a control signal for controlling at least one second electronic device;

in step S12, the control signal is processed into a first acoustic wave signal;

in step S13, outputting the first acoustic signal to at least one second electronic device in a determined output manner along with a second acoustic signal output by the first electronic device, so as to control the second electronic device to perform a corresponding operation based on at least the control signal;

In this embodiment, in a case where it is determined that the processing condition is satisfied, a control signal for controlling at least one second electronic device is obtained; specifically, the processing condition may be determined based on at least one of spatial environment information in which the first electronic device is located, runtime information, connection information with the second electronic device, and received operation information.

Processing the control signal into a first acoustic signal; in particular, the control signal may be encoded into the first acoustic signal. Generally, the first sound wave signal is a high frequency sound wave signal, and the frequency of the high frequency sound wave signal is out of the frequency range that can be heard by human ears, but the frequency range of the sound wave that can be received by the microphone interface is much higher, so the microphone interface can receive the first sound wave signal.

Outputting the first sound wave signal to at least one second electronic device along with a second sound wave signal output by the first electronic device in a determined output mode so as to control the second electronic device to execute corresponding operation at least based on the control signal; wherein the frequency of the first acoustic signal is greater than the second acoustic signal; specifically, the second acoustic signal may be a signal to be output by the first electronic device itself, for example, an acoustic device at the scene of a concert, and the second acoustic signal may be singing voice and accompaniment to be output by the acoustic device itself.

For example, the first electronic device is a sound device or a central control device at a concert site, and the second electronic device is a mobile phone or other electronic devices of audiences at the concert site. As shown in fig. 1B, before the concert starts, the first electronic device may first perform the recourse encoding, i.e. generate the supporting recourse data, and then release the recourse data, for example, the recourse data may be released to the official website platform, and the second electronic device (i.e. the mobile phone of the live audience) installs the recourse App (i.e. the corresponding computer executable instructions stored in the control program or storage medium of the memory of the present application) and downloads the supporting recourse data; the matched recourse data and APP can control the mobile phone or other equipment of the audience to analyze the first sound wave signal into a corresponding control signal and execute the corresponding control signal. When the concert starts, the first electronic device detects that the first electronic device enters the concert site based on a positioning technology, a control signal for controlling a mobile phone of a field audience can be obtained, specifically, a corresponding control signal can be obtained based on a second sound wave signal sent by the sound device, the obtained signal can be a control signal generated by the sound device, for example, when the singing voice of the concert enters a chorus part, a control signal which enables the mobile phone of the audience to twinkle light can be generated, the control signal is coded into a first sound wave signal, then the first sound wave signal is sent to the mobile phone of the audience along with the second sound wave signal (such as singing voice and accompaniment) output by the sound device, when the mobile phone of the audience receives the first sound wave signal, the sound wave is analyzed into the corresponding control signal, even if the mobile phone of the audience flickers the control signal of the light, then the mobile phone of the audience executes the, to flash itself. Thereby being capable of replacing a light stick to set off the scene atmosphere of the concert. When the second electronic device interprets the sound wave, the sound wave is propagated to the second electronic device farther away as a relay device.

The optical wand is used as a disposable tool, after a concert or evening party is finished, the optical wand is usually directly discarded to cause serious waste, and the mobile terminal becomes indispensable equipment for people, so that when the mode is used for the concert or the evening party on site, electronic equipment carried by users such as the mobile terminal can replace the optical wand, the waste of the optical wand is reduced, and the cost is further saved.

The beneficial effect of this application lies in: the obtained control signal can be processed into a first sound wave signal; then, the first sound wave signal is output to the second electronic equipment together with the second sound wave signal, and then the second electronic equipment is controlled to execute corresponding operation based on the control signal corresponding to the first sound wave signal, so that the effect of controlling the electronic equipment through sound waves is achieved, a wireless communication environment is not needed, a plurality of instructions are not needed to be generated by the first electronic equipment and are respectively sent to all the second electronic equipment, only the sound waves need to be output, the requirements on the communication environment and the performance of the first electronic equipment are effectively reduced, and the cost is saved.

In one embodiment, the determination in the above step S11 that the processing condition is satisfied may be implemented as the following steps:

In this embodiment, it is determined that the processing condition is satisfied based on at least one of spatial environment information in which the first electronic device is located, runtime information, connection information with the second electronic device, and received operation information.

The process condition is determined to be satisfied in several cases:

detecting that a first electronic device enters a first space environment, and determining that a processing condition is met; or the like, or, alternatively,

detecting that the first electronic equipment runs to a first moment, and determining that a processing condition is met; or the like, or, alternatively,

detecting that the first electronic equipment operates for a first time period in a second space environment, and determining that a processing condition is met; or the like, or, alternatively,

detecting that the first electronic equipment enters a third space environment at a second moment, and determining that a processing condition is met; or the like, or, alternatively,

detecting that the first electronic equipment is connected with at least one second electronic equipment, and determining that the processing conditions are met; or the like, or, alternatively,

detecting that the first electronic equipment enters a third space environment and establishes connection with at least one second electronic equipment, and determining that a processing condition is met; or the like, or, alternatively,

detecting at least one operation which meets the condition and acts on the first electronic equipment, and determining that the processing condition is met; or the like, or, alternatively,

at least one operation which meets the condition and acts on the first electronic equipment is detected at the third time and/or the fourth space environment, and the processing condition is determined to be met.

Of course, it is understood that the above listed information of the first electronic device and the above listed trigger mechanisms based on the above listed information are only for the convenience of describing the present application more clearly, and are not used to limit the present application, and those skilled in the art may set more trigger mechanisms as needed.

In the following, still taking the concert scene as an example, the above trigger mechanisms are exemplarily described, where the first electronic device takes an audio device used in the concert as an example, and the second electronic device takes a mobile phone of an audience as an example:

1. and detecting that the first electronic equipment enters the first space environment, and determining that the processing condition is met.

For example, if the sound equipment determines that the mobile terminal enters the concert site based on positioning technologies such as gps, satellite navigation positioning, wifi positioning, location change in a mobile network service area, and the like, the sound equipment determines that the processing conditions are met, and at this time, the operation of obtaining the control signal for controlling the mobile phone of the audience by the user is executed.

2. Detecting that the first electronic equipment runs to a first moment, and determining that a processing condition is met;

the first time may be a start time of the concert, for example, the start time of the concert is 17:00, that is, when it is detected that the audio apparatus has operated to 17:00, it is determined that the processing condition is satisfied, and at this time, an operation of obtaining a control signal for controlling the mobile phone of the viewer by the user is performed.

3. Detecting that the first electronic equipment operates for a first time period in a second space environment, and determining that a processing condition is met;

for example, after the sound equipment determines to enter the concert site based on positioning technologies such as gps, satellite navigation positioning, wifi positioning, mobile network service area and the like, whether the running time of the first electronic equipment reaches the first time is continuously determined, and when the first time is reached, the processing condition is determined to be met.

It should be noted that the first time period may be a time required from the start of the operation of the apparatus to the operation stability; the first time length can also be set to 0 second, namely after the sound equipment is determined to enter the concert scene, even if the sound equipment is just started, the sound equipment can also start to execute the operation of obtaining the control signal of the mobile phone of the user controlled audience; in some cases, the audio device may need to establish a wireless communication link with one or more of a singer's microphone, an electronic musical instrument, a spectator's cell phone, a wireless remote control device, etc., and in such cases, the first time period may be the time period needed to establish wireless communication.

4. Detecting that the first electronic equipment enters a third space environment at a second moment, and determining that a processing condition is met;

when the sound equipment enters the concert scene, the concert starting time may not be reached, or when the concert starting time is reached, the sound equipment may not enter the concert scene. In view of this, the trigger mechanism may be established based on both time and location metrics.

For example, when the sound equipment detects that the current time is the starting time of a concert, the sound equipment can continuously determine whether the sound equipment is in the concert site or not based on positioning technologies such as gps, satellite navigation positioning, wifi positioning, mobile network service area and the like, when the sound equipment is in the concert site, it is determined that the processing conditions are met, and at this time, the operation of obtaining the control signal of the user for controlling the mobile phone of the audience is executed.

5. Detecting that the first electronic equipment is connected with at least one second electronic equipment, and determining that the processing conditions are met;

for example, when the acoustic apparatus detects that a connection has been established with a cell phone of a viewer, it is determined that the processing condition is satisfied. Specifically, the sound equipment can send a detection signal to the mobile phone of the audience based on Bluetooth or infrared, and when a response signal fed back by the mobile phone of the audience is received, connection is established with the mobile phone of the audience based on an equipment identifier carried in the response signal; in addition, the sound equipment can also be connected with the mobile phones of audiences through various wireless communication technologies such as WIFI and mobile communication networks.

6. Detecting that the first electronic equipment enters a third space environment and establishes connection with at least one second electronic equipment, and determining that a processing condition is met;

for example, when it is detected that the audio apparatus enters the concert site and a connection is established with at least one of the viewer's handsets, it is determined that the processing condition is satisfied.

7. Detecting at least one operation which meets the condition and acts on the first electronic equipment, and determining that the processing condition is met;

for example, the operation that satisfies the condition is at least one of an operation to turn on the audio device, an operation to click a specific function button (e.g., a device control function button) on the audio device, an operation to establish a wireless connection between the audio device and a microphone, and the processing condition is determined to be satisfied when the at least one operation is performed on the audio device.

8. Detecting at least one operation which meets the condition and acts on the first electronic equipment at the third moment and/or the fourth space environment, and determining that the processing condition is met;

for example, the sound equipment operation time has reached the concert start time, and when a click operation of an equipment control function button acting on the sound equipment is detected, it is determined that the processing condition is satisfied; or the running time of the sound equipment reaches the starting time of the concert, the sound equipment is in the scene of the concert, and meanwhile, when the click operation of an equipment control function button acting on the sound equipment is detected, the processing condition is determined to be met.

In one embodiment, the obtaining of the control signal for controlling the at least one second electronic device in the step S11 can be implemented as the following steps a1, a2, A3, or a 4:

in step a1, obtaining a control signal based on at least instruction information input to the first electronic device;

the step is suitable for manually controlling first electronic equipment, for example, the first electronic equipment is sound equipment of a concert, buttons for controlling a mobile phone of a live audience to be on screen, flash and emit specific sound are arranged on the first electronic equipment, a user can input instruction information to the first electronic equipment based on the triggering of the buttons, and the first electronic equipment generates a control signal for correspondingly controlling the mobile phone of the live audience based on the instruction information.

In other embodiments, the instruction information may also be a voice instruction, a gesture instruction, a posture instruction, an ultrasonic instruction, a biometric instruction, and the like, and is not limited to the touch instruction in the above embodiments.

In step a2, obtaining quantity information of the second electronic device, and obtaining a corresponding control signal based on the quantity information;

for example, the first electronic device is a sound device of a concert, the second electronic device is a mobile phone of a live audience, the number information of the second electronic device can be obtained, and then it is determined which control signal is adopted to control the mobile phone of the audience based on the number information. For example, 2000 seats are available at the concert site, but if the number of the obtained second electronic devices is only 300, the number of the obtained second electronic devices indicates that the concert site is small, so that all the electronic devices can be controlled to be bright and have consistent brightness, thereby forming a light effect, and if the number of the obtained second electronic devices is 2000, the concert site is fully seated, at this time, an asynchronous control signal can be generated, different control signals are generated for the second electronic devices in different areas, for example, the brightness and the color of the device screens in different areas are controlled to be alternately changed, so that different shapes such as waves, marquees, characters, letters and the like are formed in the whole concert site. Specifically, a correspondence table between the second electronic device quantity information and the control signal may be established in advance, and then the correspondence table may be queried based on the quantity of the second electronic devices to obtain the corresponding control signal.

In step a3, obtaining an output parameter of the second acoustic signal, and generating a corresponding control signal based on at least the output parameter;

for example, the first electronic device is a sound device of a concert, the second acoustic signal is a singing voice and an accompaniment of the concert site, and a corresponding control signal can be generated based on the rhythm, volume and the like of the singing voice and the accompaniment.

In step a4, environment information where the second electronic device is located is obtained, and a corresponding control signal is generated based on the environment information.

In this step, the environmental information where the second electronic device is located is obtained, for example, the environmental information is the audience clapping and the whooping at the concert site, and a control signal can be automatically generated based on the sound information in the environment, for example, when the audience clapping and the whooping are small, the bright screen or the flicker can be controlled for the purpose of activating the atmosphere.

It should be noted that, the above steps a1-a4 may be implemented individually or in combination, for example, when the steps a1 and a2 are implemented in combination, corresponding control signals may be obtained based on the instruction information input to the first electronic device and the number information of the second electronic devices at the same time, and when the steps a1, a2, and A3 are implemented in combination, corresponding control signals may be obtained based on the instruction information input to the first electronic device, the number information of the second electronic devices, and the output parameters of the second acoustic wave signal. It is understood that the above steps a1-a4 can be combined in any combination, and further combinations are not described herein.

The beneficial effect of this embodiment lies in: the mode that sets up multiple acquisition control signal for the acquisition mode of control model is more diversified, and can make control signal satisfy all kinds of different control demands.

In one embodiment, the step S13 of outputting the first acoustic signal to the at least one second electronic device along with the second acoustic signal output by the first electronic device in the determined output mode may be implemented as the following steps B1 or B2:

in step B1, outputting the first acoustic signal to the second electronic device through the first output channel of the first electronic device, and outputting the second acoustic signal to the second electronic device through the second output channel of the first electronic device;

in step B2, the power and/or frequency of the first acoustic wave signal and/or the second acoustic wave signal are adjusted based on at least the spatial environment information where the first electronic device is located, and the adjusted first acoustic wave signal and second acoustic wave signal are output to the second electronic device.

In this embodiment, when the first acoustic signal is output to at least one second electronic device in a certain output manner along with a second acoustic signal output by the first electronic device, the first acoustic signal is output to the second electronic device through a first output channel of the first electronic device, and the second acoustic signal is output to the second electronic device through a second output channel of the first electronic device; for example, the first output channel may be a left channel or a right channel, the second output channel being a right channel in case the first channel is a left channel, and the second output channel being a left channel in case the first channel is a right channel. Therefore, the first sound wave signal and the second sound wave signal can be respectively output through the left sound channel and the right sound channel, and output confusion and mutual interference caused by the fact that the sound wave signals are output through the same sound channel are avoided.

In addition, in the present embodiment, the power and/or frequency of the first acoustic wave signal and/or the second acoustic wave signal is adjusted based on at least the spatial environment information where the first electronic device is located, and the adjusted first acoustic wave signal and second acoustic wave signal are output to the second electronic device. Therefore, the power and/or the frequency of the first sound wave signal and/or the second sound wave signal can be adjusted according to the space environment information, and the transmission quality and the coverage range of the first sound wave signal and/or the second sound wave signal are guaranteed.

It should be noted that the second electronic device may also serve as a relay device to continue forwarding the first acoustic signal and the second acoustic signal to a second electronic device that is further away. As shown in fig. 1C, when the first electronic device is closer to the second electronic device in the first location and farther from the second electronic device in the second and third locations, the second electronic device in the first location may forward the first acoustic signal and/or the second acoustic signal to the second electronic device in the second location and the third location when receiving the first acoustic signal and/or the second acoustic signal transmitted by the first electronic device, and of course, may forward the first acoustic signal and/or the second acoustic signal only to the second electronic device in the second location, and forward the first acoustic signal and/or the second acoustic signal to the second electronic device in the third location by the second electronic device in the second location.

In addition, the second electronic device may also increase the loudness of sound by changing the amplification of the speaker in addition to adjusting the power and/or frequency of the first and/or second acoustic signals, thereby enhancing the sound by the second electronic device.

The embodiment has the advantages that the power and/or the frequency of the first sound wave signal and/or the second sound wave signal can be adjusted according to the space environment information, and the transmission quality and the coverage range of the first sound wave signal and/or the second sound wave signal are guaranteed.

In one embodiment, as shown in fig. 2, the step S13 of controlling the second electronic device to perform corresponding operations based on at least the control signal may be implemented as the following steps S21-S22:

in step S21, in the case that the second electronic device has the first number, controlling the first number of second electronic devices to synchronously output the first form of light effect based on the control signal;

in step S22, in the case that the second electronic device has the second number, the second electronic device of the second number is controlled to asynchronously output the light effect of the second form based on the control signal.

In this embodiment, when the second electronic devices have the first number, the first number of second electronic devices are controlled to synchronously output the first form of light effect based on the control signal; in the case where the second electronic device has a second number, the second number of second electronic devices is controlled to asynchronously output the second form of light effect based on the control signal.

For example, the first electronic device is a sound device of a concert, the second electronic device is a mobile phone of a live audience, the quantity information of the second electronic device can be obtained, and then it is determined which control signal is adopted to control the mobile phone of the audience based on the quantity information. For example, there are 2000 seats at the concert site, but if the number of the second electronic devices obtained is only 300, the number of the second electronic devices at the concert site is small, so that all the second electronic devices can be controlled synchronously, for example, the second electronic devices are simultaneously lighted and have consistent color and brightness, or the second electronic devices are synchronously flashed; if the number of the obtained second electronic devices is more than 1800, it indicates that the concert site is almost full, at this time, an asynchronous control signal can be generated, and different control signals can be generated for the second electronic devices in different areas, for example, the brightness and the color of the device screens in different areas are controlled to be alternately changed, so that different shapes such as wave-shaped light, light-up and light-out modes moving from the periphery to the center, a horse-walking light, characters, English words and the like can be formed in the whole meeting place.

The beneficial effect of this embodiment lies in: the second electronic equipment can be controlled to output different light effects based on the different quantity of the second electronic equipment, so that the second electronic equipment can output different types of light effects, and the applicable scene of the light effects is wider.

Fig. 3 is a flowchart of a processing method according to an embodiment of the present application, where the method is applicable to a second electronic device, and the second electronic device may be a controlled device in a device control scenario, and the method includes the following steps S31-S32:

in step S31, receiving a first acoustic signal and a second acoustic signal output by a first electronic device, wherein the frequency of the first acoustic signal is greater than that of the second acoustic signal;

in step S32, a corresponding operation is performed based on the first acoustic wave signal.

In this embodiment, a first acoustic signal and a second acoustic signal output by a first electronic device are received, and a corresponding operation is performed based on the first acoustic signal, where the frequency of the first acoustic signal is greater than that of the second acoustic signal.

Specifically, as shown in fig. 1B, after receiving a first sound wave signal and a second sound wave signal output by a first electronic device, a second electronic device may parse the first sound wave signal into a corresponding control instruction, then perform an operation corresponding to the control instruction, and broadcast the first sound wave signal, so that the second electronic device that is far away from the first electronic device may receive the first sound wave signal and the second sound wave signal. It should be noted that the number of the second electronic devices is not limited to one, if the control instruction corresponding to the first sound wave signal is to control the second electronic devices to synchronously output the first light effect, the control instructions received by all the second electronic devices are the same, and if the control instruction corresponding to the first sound wave signal is to control the second electronic devices to asynchronously output the second light effect, the control instructions received by the second electronic devices are different, for example, the second light effect is a ticker effect, then the second electronic device a may receive a control signal for lighting at 18:00:00, and a next second electronic device B adjacent to the second electronic device a may receive a control signal for lighting at 18:00: 01. If the second lighting effect is the effect of lighting the lamp moving from the periphery to the center, the second electronic device at the outermost circle of the scene may receive the control signal of lighting the lamp at 18:00:00, the second electronic device at the next outermost circle of the scene may receive the control signal of lighting the lamp at 18:00:01, and so on.

The beneficial effect of this application lies in: corresponding operation can be executed based on the first sound wave model output by the first electronic equipment, so that the first electronic equipment can control the second electronic equipment through sound waves, the requirements on the communication environment and the performance of the first electronic equipment during equipment control are reduced, and the cost is saved.

In one embodiment, the method may also be implemented as the steps of:

the second electronic equipment at the first position outputs the received first sound wave signal and/or second sound wave signal to the second electronic equipment at the second position so that the second electronic equipment at the second position can execute corresponding operation;

In this embodiment, as shown in fig. 1C, a first distance between the second electronic device at the first location and the first electronic device is smaller than a second distance between the second electronic device at the second location and the first electronic device, at this time, the second electronic device at the second location may not receive the first acoustic wave signal and/or the second acoustic wave signal sent by the first electronic device, and therefore, the second electronic device at the first location outputs the received first acoustic wave signal and/or the received second acoustic wave signal to the second electronic device at the second location, so that the second electronic device at the second location performs a corresponding operation; therefore, the second electronic equipment at the first position can be used as relay equipment to forward the first sound wave signal and/or the second sound wave signal, and the control distance of the first electronic equipment is increased.

It should be noted that the second electronic device at the first location may directly output the first acoustic signal and/or the second acoustic signal to the second electronic device at the second location, or may adjust the power and/or frequency of the first acoustic signal and/or the second acoustic signal and then send the adjusted first acoustic signal and/or second acoustic signal to the second electronic device, so as to enhance the first acoustic signal and/or second acoustic signal. And may in particular depend on the distance between the first and second position. Of course, the sound amplitude of the first sound signal and/or the second sound signal can also be enhanced.

The beneficial effect of this embodiment lies in: the second electronic device at the first position outputs the received first sound wave signal and/or second sound wave signal to the second electronic device at the second position, so that the second electronic device at the second position executes corresponding operation, the second electronic device at the first position can be used as relay equipment, the first sound wave signal and/or second sound wave signal can be forwarded, and the control distance of the first electronic device is increased.

In one embodiment, the above step S32 can be implemented as the following steps C1-C2:

in step C1, in the case that the second electronic device has the first number, synchronously outputting the first form of light effect;

in step C2, in the event that the second electronic device has a second number, the second form of light effect is output asynchronously.

Fig. 4 is a block diagram of a processing apparatus according to an embodiment of the present application, where the apparatus is applicable to a first electronic device, and the first electronic device may be a master device in a device control scenario, and the apparatus includes:

an obtaining module 41, configured to obtain a control signal for controlling at least one second electronic device if it is determined that the processing condition is satisfied;

a processing module 42 for processing the control signal into a first acoustic signal;

the output module 43 is configured to output the first acoustic signal to at least one second electronic device in a determined output manner along with a second acoustic signal output by the first electronic device, so as to control the second electronic device to perform a corresponding operation based on at least the control signal;

In one embodiment, an obtaining module includes:

a first obtaining submodule for obtaining a control signal based on at least instruction information input to the first electronic device;

In one embodiment, an output module includes:

In one embodiment, the output module further comprises:

the first control submodule is used for controlling the first number of second electronic equipment to synchronously output the first form of light effect based on the control signal under the condition that the second electronic equipment has the first number;

and the second control submodule is used for controlling the second electronic equipment of the second number to asynchronously output the light effect of the second form based on the control signal under the condition that the second electronic equipment has the second number.

The present application further provides a processing apparatus, which may be used for a second electronic device, where the second electronic device may be a controlled device in a device control scenario, the apparatus including:

In one embodiment, the apparatus further comprises:

The present application further provides a first electronic device, comprising:

a processor;

a memory for storing processor-executable instructions;

processing the control signal into a first acoustic signal;

a processor;

a memory for storing processor-executable instructions;

processing the control signal into a first acoustic signal;

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims

1. A processing method, applied to a first electronic device, the method comprising:

processing the control signal into a first acoustic signal;

2. The method of claim 1, wherein determining that a processing condition is satisfied comprises:

3. The method of claim 1, obtaining a control signal for controlling at least a second electronic device, comprising:

4. The method of claim 1, the outputting the first acoustic signal with a second acoustic signal output by the first electronic device to the at least a second electronic device in a determined output manner, comprising:

5. The method of any of claims 1-4, the controlling the second electronic device to perform a corresponding operation based at least on the control signal, comprising:

6. A processing method is applied to a second electronic device, and comprises the following steps:

7. The method of claim 6, further comprising:

8. The method of claim 6 or 7, wherein the second electronic device performing the corresponding operation comprises:

9. A processing apparatus, the apparatus comprising:

10. A processing apparatus, the apparatus comprising: