Patent Description:
The disclosure relates to the field of wireless communication technologies, and in particular, to a wireless device snooping method and apparatus.

With the continuous development of wireless communication technologies, there are various wireless transmission methods. In the existing audio transmission system, data transmission is usually implemented by the following method.

Referring to <FIG>, after establishing a wireless link connection with a sound source, the sound-emitting unit <NUM> of the stereo then establishes a wireless link connection with the sound-emitting unit <NUM>, so that the sound-emitting unit <NUM> can obtain corresponding data by snooping link data between the sound-emitting unit <NUM> and the sound source.

However, for establishing a wireless link connection between the sound-emitting unit <NUM> and the sound-emitting unit <NUM>, connected point-to-point communication is required, thus creating a certain limitation. For example, if the Bluetooth technology is used, there can be only <NUM> slave devices due to the limitation of the Bluetooth Piconet, thus the sound-emitting unit <NUM> can only perform the point-to-point communication with at most <NUM> devices. For another example, if a wireless mesh network is used, the real-time performance and the reliability of the system will be affected.

It can be seen that a new solution needs to be designed to overcome the above-mentioned defects.

In patent application <CIT>, it discloses wireless audio systems and methods for operation mode switch of wireless headphones. In one example, a wireless audio system includes a first wireless headphone and a second wireless headphone. The first wireless headphone is configured to establish a first short-range wireless link with an audio source; transmit, to a second wireless headphone, link information associated with the first short-range wireless link; and remove the first short-range wireless link with the audio source in response to the second wireless headphone successfully establishing a second short-range wireless link with the audio source based on the link information. The second wireless headphone is configured to receive, from the first wireless headphone, the link information associated with the first short-range wireless link; and establish the second short-range wireless link with the audio source based on the link information.

In patent application <CIT>, it discloses methods and devices for wireless transmission of content using Wi-Fi infrastructure to multiple user-devices devices that does not require maintaining a Wi-Fi session with each user-device.

In patent application <CIT>, it discloses a voice information collection and reporting control method and system of audio equipment, a first audio device connected to the terminal device via a first link and collecting and reporting voice information via the first audio device, and at least one second audio device connected to the first audio device via the second link and sharing synchronization information of the first link, the method comprising detecting a connection state of the first link, the second link, or communication information of the first audio device, the second audio device; a third link between the second audio device and the terminal device is established and switched to the second audio device to collect and report the voice information when the connection state or the communication information meets the preset condition.

Patent application <CIT> discloses a communication method for a wireless earphone, the wireless earphone and wireless equipment. The communication method includes the following steps: establishing a wireless link between a main earphone and another device; and transmitting the related communication parameters of the wireless link to the slave earphone by utilizing another device, so that the slave earphone can monitor the wireless link by utilizing the received related communication parameters of the wireless link. According to the communication method for the wireless earphone, the other device is used as an information forwarding/relaying device between the master earphone and the slave earphone, relay is performed between the master earphone and the slave earphone for related communication parameters of a wireless link between the master earphone and another device.

The disclosure provides a wireless device snooping method and apparatus, so as to solve the problem that the number of wireless devices is limited due to the need to establish a wireless link connection between wireless devices.

In the embodiments of the disclosure, the first wireless device establishes a connection of a wireless link with the data source end, and generates corresponding parameter(s) of the wireless link; the first wireless device broadcasts the parameter(s) of the wireless link, to trigger at least one second wireless device to receive the parameter(s) of the wireless link and snoop the wireless link based on the parameter(s) of the wireless link. The connection of the wireless link is established between the first wireless device and the data source end, so that the second wireless device can obtain the relevant service data by snooping the wireless link between the data source end and the first wireless device. Further, the first wireless device transmits the parameter(s) of the wireless link to at least one second wireless device through broadcasting, so that a plurality of second wireless devices can snoop the wireless link simultaneously, breaking through the limitation on the number of second wireless devices and improving the real-time performance and reliability of transmission.

In order to illustrate the technical solutions in the embodiments of the disclosure or in the prior art more clearly, the accompanying figures which need to be used in describing the embodiments or the prior art will be introduced below briefly. Obviously, the accompanying figures described below merely illustrate some embodiments of the disclosure, and other accompanying figures can also be obtained by those ordinary skilled in the art according to these accompanying figures without creative labor.

Aiming at the problem of the limitation on the number of wireless devices due to the need to establish a wireless link connection between wireless devices in the prior art, in order to break through the limitation on the number of wireless devices, a solution for snooping wireless devices is provided in the embodiments of the disclosure.

The solution is as follows: a first wireless device establishes a connection of a wireless link with a data source end; and the first wireless device broadcasts parameter(s) of the wireless link to trigger at least one second wireless device to snoop the wireless link based on the parameter(s) of the wireless link.

It should be noted that the disclosure is applicable to all application scenarios in which the wireless broadcast can be realized. For example, if the application scenario is an audio transmission system, the wireless device is a sound-emitting unit, and the data source end is an audio source. If the application scenario is a smart home system, the wireless device is a smart home, and the data source end is a corresponding control device. In the following, for the convenience of description, only the audio transmission system is taken as an example for illustration.

In order to enable those ordinary skilled in the art to better understand the technical solutions of the disclosure, the technical solutions in the embodiments of the disclosure will be described clearly and completely with reference to the accompanying drawings.

Referring to <FIG>, a process of a wireless device snooping method provided in an embodiment of the disclosure is as follows.

Step S201: a first wireless device establishes a connection of a wireless link with a data source end, and generates corresponding parameter(s) of the wireless link.

It should be noted that, in the embodiments of the disclosure, when there are a plurality of wireless devices, the wireless device that establishes a wireless link connection with the data source end is called the first wireless device, and the wireless device that has no wireless link connection with the data source end is called the second wireless device.

In some embodiments of the disclosure, the wireless link connection may be established in but not limited to two following ways.

In the first way: the first wireless device sends a wireless link connection request to the data source end.

The first wireless device sends a wireless link connection request to the data source end, and establishes a wireless link connection with the data source end when receiving a wireless link connection response fed back by the data source end.

For example, referring to <FIG>, it is assumed that there are only a sound-emitting unit <NUM>, a sound-emitting unit <NUM> and a sound source. The sound-emitting unit <NUM> sends a wireless link connection request to the sound source, and establishes a wireless link connection with the sound source when receiving a wireless link connection response fed back by the sound source. In such a case, the sound-emitting unit <NUM> is the first wireless device, and the sound-emitting unit <NUM> is the second wireless device.

In the second way: the data source end sends a wireless link connection request to the first wireless device.

The first wireless device feeds back a wireless link connection response to the data source end when receiving a wireless link connection request sent by the data source end, to trigger the data source end to establish a wireless link connection.

For example, referring to <FIG>, it is assumed that there are only a sound-emitting unit <NUM>, a sound-emitting unit <NUM> and a sound source. The sound-emitting unit <NUM> feeds back a wireless link connection response to the sound source when receiving a wireless link connection request sent by the sound source, to trigger the sound source to establish a wireless link connection. In such a case, the sound-emitting unit <NUM> is the first wireless device, and the sound-emitting unit <NUM> is the second wireless device.

Further, the first wireless device establishes a wireless link connection with the data source end, and generates corresponding wireless link parameter(s).

It should be noted that, when the first wireless device establishes a wireless link connection with the data source end, it may adopt but not limited to the Wireless-Fidelity (WiFi) technology, Bluetooth technology, Zigbee technology and other existing wireless technology. After the wireless link connection is established, different wireless technologies are used to generate different wireless link parameters, which will not be repeated here.

For example, the sound-emitting unit <NUM> establishes a wireless link connection with the sound source by using the Bluetooth technology, and generates the corresponding wireless link parameter(s).

Further, after the step S201 is performed, due to different application scenarios, there are, but not limited to, two following cases.

Case <NUM>: the both-way communication is performed between the first wireless device and at least one second wireless device.

In the audio transmission scenario, the first wireless device and the second wireless device are sound-emitting units. In such a case, the both-way communication must be performed between the first wireless device and at least one second wireless device. Next, the Case <NUM> will be explained by taking the audio transmission scenario as an example.

The first wireless device broadcasts the first broadcast configuration information, and triggers the at least one second wireless device to configure corresponding data sending and receiving modes based on the first broadcast configuration information. The at least one second wireless device performs broadcast communication with the first wireless device in the corresponding data receiving and sending modes.

It should be noted that in embodiments of the disclosure, the first broadcast configuration information at least includes a data receiving mode of the first wireless device and a data sending mode of the first wireless device.

For example, referring to <FIG>, it is assumed that there are only a sound-emitting unit <NUM>, a sound-emitting unit <NUM> and a sound source. The first broadcast configuration information includes the data receiving mode of the sound-emitting unit <NUM> and the data sending mode of the sound-emitting unit <NUM>. The data sending mode of the sound-emitting unit <NUM> is to be in the data sending state within <NUM>-<NUM> milliseconds (ms), and the data receiving mode of the sound-emitting unit <NUM> is to be in the data receiving state within <NUM>-<NUM>. The sound-emitting unit <NUM> broadcasts the first broadcast configuration information, and triggers the sound-emitting unit <NUM> to configure the data receiving mode of the sound-emitting unit <NUM> to be in the data receiving state within <NUM>-<NUM> and the data sending mode of the sound-emitting unit <NUM> to be in the data sending state within <NUM>-<NUM> based on the first broadcast configuration information. The sound-emitting unit <NUM> performs broadcast communication with the sound-emitting unit <NUM> in the data receiving mode and the data sending mode of the sound-emitting unit <NUM>.

Further, when the broadcast communication is performed between the first wireless device and the at least one second wireless device, the protocol interaction data for data synchronization and clock synchronization may be transmitted but not limited thereto.

For example, referring to <FIG>, it is assumed that there are only a sound-emitting unit <NUM>, a sound-emitting unit <NUM> and a sound source. When the broadcast communication is performed between the sound-emitting unit <NUM> and the sound-emitting unit <NUM>, the sound-emitting unit <NUM> broadcasts the local clock and the actual operating clock frequency of the sound-emitting unit <NUM> to the sound-emitting unit <NUM> within <NUM>-<NUM>, and the sound-emitting unit <NUM> broadcasts the local clock and the actual operating clock frequency of the sound-emitting unit <NUM> to the sound-emitting unit <NUM> within <NUM>-<NUM>.

Case <NUM>: the one-way communication is performed between the first wireless device and at least one second wireless device.

If it is determined, according to the actual requirements of the application scenario, that the one-way communication is performed between the first wireless device and the at least one second wireless device, the step S202 may be directly executed.

For example, in the smart home scenario, the first wireless device and the second wireless device are smart homes, and there is no need to perform the both-way communication between the first wireless device and the second wireless device.

Step S202: the first wireless device broadcasts the parameter(s) of the wireless link to trigger at least one second wireless device to perform: receiving the parameter(s) of the wireless link and snooping the wireless link based on the parameter(s) of the wireless link.

It should be noted that different methods are used for snooping due to different wireless networks when the at least one second wireless device snoops the wireless link. Therefore, the disclosure does not limit the implementation of snooping, and the detailed description thereof will be omitted here.

The first wireless device may broadcast the wireless link parameter(s) in but not limited to the following ways.

In the first way: the first wireless device encrypts the wireless link parameter(s) by using a preset encryption algorithm, and broadcasts encrypted wireless link parameter(s).

For example, the sound-emitting unit <NUM> encrypts the wireless link parameter(s) by using an Advanced Encryption Standard (AES) algorithm, and broadcasts the encrypted wireless link parameter(s).

It should be noted that, in the embodiments of the disclosure, the wireless link parameter(s) may be encrypted by using but not limited to the existing encryption algorithms such as AES algorithm, thus avoiding the leakage of the wireless link parameter(s) effectively, and ensuring the security between the first wireless device and the data source end.

In the second way: the first wireless device broadcasts the wireless link parameter(s) directly.

For example, the sound-emitting unit <NUM> broadcasts the wireless link parameter(s) directly.

In the second way, the first wireless device broadcasts the wireless link parameter(s) directly without encrypting the broadcast wireless link parameter(s), thus reducing the data processing time and improving the snooping efficiency.

When the first wireless device broadcasts the wireless link parameter(s), at least one second wireless device receives the wireless link parameter(s) in the corresponding data receiving mode, and snoops the wireless link based on the wireless link parameter(s).

For example, referring to <FIG>, it is assumed that there are only a sound-emitting unit <NUM>, a sound-emitting unit <NUM> and a sound source. When the sound-emitting unit <NUM> broadcasts the wireless link parameter(s), the sound-emitting unit <NUM> receives the wireless link parameter(s) at <NUM>, and snoops the wireless link based on the wireless link parameter(s).

Further, the first wireless device receives the service data sent by the data source end, and triggers the at least one second wireless device to obtain the service data and execute a corresponding instruction based on the service data.

For example, referring to <FIG>, it is assumed that there are only a sound-emitting unit <NUM>, a sound-emitting unit <NUM> and a sound source. The sound-emitting unit <NUM> receives the audio data <NUM> sent by the sound source, and triggers the sound-emitting unit <NUM> to obtain the audio data <NUM> and perform the playback instruction based on the audio data <NUM>.

Further, the first wireless device sends a wireless link connection request to the data source end when it does not receive the service data sent by the data source end within a preset time interval.

For example, assuming that the preset time interval is <NUM> hours, the sound-emitting unit <NUM> sends a wireless link connection request to the sound source when it does not receive the service data sent by the sound source within <NUM> hours.

When establishing a wireless link connection with the data source end again, the first wireless device generates new wireless link parameter(s), and broadcasts the new wireless link parameter(s) based on the first broadcast configuration information, to trigger the at least one second wireless device to receive the new wireless link parameter(s) in the corresponding data receiving mode and snoop the wireless link based on the new wireless link parameter(s).

For example, when establishing a wireless link connection with the sound source again, the sound-emitting unit <NUM> generates new wireless link parameter(s), and broadcasts the new wireless link parameter(s) at <NUM> based on the first broadcast configuration information, to trigger the sound-emitting unit <NUM> to receive the new wireless link parameter(s) at <NUM> and snoop the wireless link based on the new wireless link parameter(s).

It should be noted that the broadcast technology used in the embodiments of the disclosure may be any broadcast method implemented by the wireless communication technology, including but not limited to Bluetooth Low Energy (BLE) broadcast, Basic Rate/Enhanced Data Rate (BR/EDR) broadcast, broadcast implemented based on Bluetooth Connectionless Slave Broadcast (CSB), etc..

Next, the disclosure will be described by still taking the audio transmission system as an example. Referring to <FIG>, there are a sound-emitting unit <NUM>, a sound-emitting unit <NUM>, a sound-emitting unit <NUM> and a sound source in some embodiments of the disclosure.

The sound-emitting unit <NUM> sends a wireless link connection request to the sound source, and establishes a connection of a wireless link with the sound source when receiving a wireless link connection response fed back by the sound source. In such a case, the sound-emitting unit <NUM> is the first wireless device, and the sound-emitting unit <NUM> and the sound-emitting unit <NUM> are the second wireless devices.

The sound-emitting unit <NUM> establishes the connection of the wireless link with the sound source by using the Bluetooth technology, and generates the parameter(s) of the wireless link.

The sound-emitting unit <NUM> broadcasts the first broadcast configuration information that includes the data receiving mode of the sound-emitting unit <NUM> and the data sending mode of the sound-emitting unit <NUM>. The data sending mode of the sound-emitting unit <NUM> is to be in the data sending state within <NUM>-<NUM>, and the data receiving mode of the sound-emitting unit <NUM> is to be in the data receiving state within <NUM>-<NUM>. Further, the first broadcast configuration information may also carry the identity information of the sound-emitting unit <NUM>.

Based on the first broadcast configuration information, the sound-emitting unit <NUM> configures the data receiving mode of the sound-emitting unit <NUM> to be in the data receiving state within <NUM>-<NUM> and the data sending mode of the sound-emitting unit <NUM> to be in the data sending state within <NUM>-<NUM>. Based on the first broadcast configuration information, the sound-emitting unit <NUM> configures the data receiving mode of the sound-emitting unit <NUM> to be in the data receiving state within <NUM>-<NUM> of the next transmission cycle and the data sending mode of the sound-emitting unit <NUM> to be in the data sending state within <NUM>-<NUM>.

The sound-emitting unit <NUM> broadcasts the parameter(s) of the wireless link at <NUM>. When the sound-emitting unit <NUM> broadcasts the parameter(s) of the wireless link, the sound-emitting unit <NUM> receives the parameter(s) of the wireless link at <NUM> and snoops the wireless link based on the parameter(s) of the wireless link, and the sound-emitting unit <NUM> receives the parameter(s) of the wireless link and snoops the wireless link based on the parameter(s) of the wireless link in the next transmission cycle.

The sound-emitting unit <NUM> receives a control instruction <NUM> sent by the sound source, and triggers the sound-emitting unit <NUM> and the sound-emitting unit <NUM> to obtain the control instruction <NUM> and perform the power-on operation based on the control instruction <NUM>.

Next, the disclosure will be described by taking a smart home system as an example. Referring to <FIG>, there are a smart home <NUM>, a smart home <NUM>, a smart home <NUM> and a control device in some embodiments of the disclosure.

When receiving a wireless link connection request sent by the control device, the smart home <NUM> feeds back a wireless link connection response to the control device to trigger the control device to establish a connection of a wireless link. The smart home <NUM> and the control device establish the connection of the wireless link by using the Bluetooth technology, and generate the corresponding parameter(s) of the wireless link.

The smart home <NUM> broadcasts the parameter(s) of the wireless link, the smart home <NUM> snoops the wireless link based on the parameter(s) of the wireless link when receiving the parameter(s) of the wireless link, and the smart home <NUM> snoops the wireless link based on the parameter(s) of the wireless link when receiving the parameter(s) of the wireless link.

The smart home <NUM> receives a control instruction <NUM> sent by the control device, and triggers the smart home <NUM> and the smart home <NUM> to obtain the control instruction <NUM> and perform the restart operation based on the control instruction <NUM>.

Next, the disclosure will be described again by taking a wearable device system as an example. Referring to <FIG>, there are a wearable device <NUM>, a wearable device <NUM>, a wearable device <NUM> and a data source end in some embodiments of the disclosure.

The wearable device <NUM> sends a wireless link connection request to the data source end, and establishes a connection of a wireless link with the data source end by using Bluetooth technology when receiving a wireless link connection response fed back by the data source end, and generates corresponding parameter(s) of the wireless link.

The wearable device <NUM> broadcasts the first broadcast configuration information that includes the data receiving mode of the wearable device <NUM> and the data sending mode of the wearable device <NUM>. The data sending mode of the wearable device <NUM> is to be in the data sending state within <NUM>-<NUM>, and the data receiving mode of the wearable device <NUM> is to be in the data receiving state within <NUM>-<NUM>. Further, the first broadcast configuration information may also carry the identity information of the wearable device <NUM>.

Based on the first broadcast configuration information, the wearable device <NUM> configures the data receiving mode of the wearable device <NUM> to be in the data receiving state within <NUM>-<NUM> and the data sending mode of the wearable device <NUM> to be in the data sending state within <NUM>-<NUM>, Then, the wearable device <NUM> broadcasts the second broadcast configuration information carrying the data receiving mode of the wearable device <NUM>. Based on the first broadcast configuration information and the second broadcast configuration information, the wearable device <NUM> configures the data receiving mode of the wearable device <NUM> to be in the data receiving state within <NUM>-<NUM> and the data sending mode of the wearable device <NUM> to be in the data sending state within <NUM>-<NUM>.

The wearable device <NUM> broadcasts the parameter(s) of the wireless link at <NUM> and <NUM>. When the wearable device <NUM> broadcasts the parameter(s) of the wireless link, the wearable device <NUM> receives the parameter(s) of the wireless link at <NUM> and snoops the wireless link based on the parameter(s) of the wireless link, and the wearable device <NUM> receives the parameter(s) of the wireless link at <NUM> and snoops the wireless link based on the parameter(s) of the wireless link.

The wearable device <NUM> receives a control instruction <NUM> sent by the data source end, and triggers the wearable device <NUM> and the wearable device <NUM> to obtain the control instruction <NUM> and perform the shutdown operation based on the control instruction <NUM>.

Based on the same inventive concept, embodiments of the disclosure provide a wireless device snooping apparatus, as shown in <FIG>, including at least a connection unit <NUM> and a broadcast unit <NUM>.

The connection unit <NUM> is configured to establish a connection of a wireless link with a data source end, and generate corresponding parameter(s) of the wireless link.

The broadcast unit <NUM> is configured to broadcast the parameter(s) of the wireless link to trigger at least one second wireless device to perform operations of: receiving the parameter(s) of the wireless link and snooping the wireless link based on the parameter(s) of the wireless link.

Optionally, when establishing the connection of the wireless link with the data source end, the connection unit <NUM> is configured to:.

After establishing the connection of the wireless link with the data source end and before broadcasting the parameter(s) of the wireless link, the broadcast unit <NUM> is further configured to:
broadcast first broadcast configuration information, and trigger the at least one second wireless device to configure corresponding data receiving and sending modes based on the first broadcast configuration information.

The at least one second wireless device performs broadcast communication with the first wireless device in the data receiving and sending modes.

Optionally, when broadcasting the parameter(s) of the wireless link, the broadcast unit <NUM> is configured to:.

Optionally, after broadcasting the parameter(s) of the wireless link, the broadcast unit <NUM> is further configured to:
receive service data sent by the data source end, and trigger the at least one second wireless device to obtain the service data and execute a corresponding instruction based on the service data.

Based on the same inventive concept, embodiments of the disclosure provide a wireless device snooping apparatus, as shown in <FIG>, including at least a processor <NUM>, a memory <NUM>, a transceiver <NUM> and a bus interface <NUM>. The processor <NUM> is configured to read computer instructions in the memory <NUM> to perform any method implemented by the wireless device snooping apparatus in the above process.

The processor <NUM> is responsible for managing the bus architecture and general processing, and the memory <NUM> may store the data used by the processor <NUM> when performing the operations. The transceiver <NUM> is configured to receive and send the data under the control of the processor <NUM>.

The bus architecture may include any numbers of interconnected buses and bridges, and link various circuits of one or more processors represented by the processor <NUM> and the memory represented by the memory <NUM>. The bus architecture may further link various other circuits such as peripheral device, voltage regulator and power management circuit, which are all well known in the art and thus will not be further described again herein. The bus interface provides an interface.

Based on the same inventive concept, embodiments of the disclosure provide a storage medium. Instructions in the storage medium, when executed by a processor, enable the processor to perform any method implemented by the wireless device snooping apparatus in the above process.

In the embodiments of the disclosure, the first wireless device establishes a wireless link connection with the data source end, and generates the corresponding wireless link parameter(s). The first wireless device broadcasts the wireless link parameter(s), to trigger at least one second wireless device to receive the wireless link parameter(s) and snoop the wireless link based on the wireless link parameter(s). The wireless link connection is established between the first wireless device and the data source end, so that the second wireless device can obtain the relevant service data by snooping the wireless link between the data source end and the first wireless device. Further, the first wireless device transmits the wireless link parameter(s) to at least one second wireless device through broadcasting, so that the plurality of second wireless devices snoop the wireless link simultaneously, breaking through the limitation on the number of second wireless devices and improving the real-time performance and reliability of transmission.

For the system/apparatus embodiments, they are substantially similar to the method embodiments, so the description thereof is relatively simple, and the related parts may refer to the partial illustration of the method embodiments.

It should be noted that the relational terms such as first and second herein are only used to distinguish one entity or operation from another and do not necessarily require or imply any such actual relationship or sequence between these entities or operations.

It should be understood by those skilled in the art that the embodiments of the disclosure can be provided as a method, apparatuses and storage medium. Thus the disclosure can take the form of hardware embodiments alone, software embodiments alone, or embodiments combining the software and hardware aspects. Also, the disclosure can take the form of computer program products implemented on one or more computer usable storage mediums (including but not limited to magnetic disk memory, Compact Disc Read-Only Memory (CD-ROM), optical memory, etc.) containing computer usable program codes therein.

The disclosure is described by reference to the flow charts and/or the block diagrams of the methods, the devices (systems) and the computer program products according to the embodiments of the disclosure. It should be understood that each process and/or block in the flow charts and/or the block diagrams, and a combination of processes and/or blocks in the flow charts and/or the block diagrams can be implemented by the computer program instructions. These computer program instructions can be provided to a general-purpose computer, a dedicated computer, an embedded processor, or a processor of another programmable data processing device to produce a machine, so that an apparatus for implementing the functions specified in one or more processes of the flow charts and/or one or more blocks of the block diagrams is produced by the instructions executed by the computer or the processor of another programmable data processing device.

These computer program instructions can also be loaded onto the computer or another programmable data processing device, so that a series of operation steps are performed on the computer or another programmable device to produce the computer-implemented processing. Thus the instructions executed on the computer or another programmable device provide steps for implementing the functions specified in one or more processes of the flow charts and/or one or more blocks of the block diagrams.

Although the preferred embodiments of the disclosure have been described, those skilled in the art can make additional alterations and modifications to these embodiments once they learn about the basic creative concepts. Thus the attached claims are intended to be interpreted to include the preferred embodiments as well as all the alterations and modifications falling within the scope of the disclosure.

Claim 1:
A wireless device snooping method, comprising:
establishing (S201), by a first wireless device, a connection of a wireless link with a data source end, and generating a corresponding parameter of the wireless link; and
characterized in that the method further comprises:
broadcasting (S202), by the first wireless device, the parameter of the wireless link to trigger at least one second wireless device to perform:
receiving the parameter of the wireless link; and
snooping the wireless link based on the parameter of the wireless link;
wherein after the first wireless device establishes the connection of the wireless link with the data source end, and before the first wireless device broadcasts the parameter of the wireless link, the method further comprises:
broadcasting, by the first wireless device, first broadcast configuration information at least comprising a data receiving mode of the first wireless device and a data sending mode of the first wireless device, for triggering the at least one second wireless device to configure data receiving and sending modes of the at least one second wireless device based on the first broadcast configuration information;
wherein the at least one second wireless device performs broadcast communication with the first wireless device in the data receiving and sending modes of the at least one second wireless device.