阅读说明：本技术 无线音频同步方法、播放设备和收发系统 (Wireless audio synchronization method, playing device and transceiving system ) 是由 郑明剑 金海鹏 于 2021-08-24 设计创作，主要内容包括：本申请提供一种无线音频同步方法、播放设备和收发系统。该方法包括：按照无线音频播放设备本地的第一时钟信号对接收到的无线信号进行采样；确定当前无线数据包对应的峰值时刻；根据第一时钟信号对当前无线数据包对应的峰值时刻与前一无线数据包对应的峰值时刻的时间差进行计数,根据计数结果调整第一时钟信号的快慢,以使相邻两个峰值时刻的时间差的计数结果趋近于预设计数值；从峰值时刻起,预设数量的第一时钟信号的时钟周期之后,根据无线音频播放设备本地的第二时钟信号播放数据段或者数据段的预定位置数据,其中,第一时钟信号与第二时钟信号的频率倍数关系是固定的。本申请的方法能够实现高精度音频同步。(The application provides a wireless audio synchronization method, a playing device and a transceiving system. The method comprises the following steps: sampling the received wireless signal according to a local first clock signal of the wireless audio playing equipment; determining the peak value moment corresponding to the current wireless data packet; counting the time difference between the peak time corresponding to the current wireless data packet and the peak time corresponding to the previous wireless data packet according to the first clock signal, and adjusting the speed of the first clock signal according to the counting result so as to enable the counting result of the time difference between two adjacent peak times to approach to a preset counting value; and playing the data segment or the preset position data of the data segment according to a second clock signal local to the wireless audio playing equipment after the preset number of clock cycles of the first clock signal from the peak time, wherein the frequency multiple relation between the first clock signal and the second clock signal is fixed. The method can realize high-precision audio synchronization.)

1. A wireless audio synchronization method is applied to a wireless audio playing device, and is characterized in that the method comprises the following steps:

sampling a received wireless signal according to a local first clock signal of the wireless audio playing device to obtain a sampling sequence, demodulating the sampling sequence to obtain a wireless data packet, wherein the wireless data packet comprises a synchronization section and a data section, the synchronization section comprises a fixed-mode synchronization sequence, the data section comprises audio codes, and the wireless signal is sent by a wireless audio sending device at regular time according to the local clock signal;

intercepting the sampling sequence according to a time sliding window, performing similarity matching on the intercepted sequence and a local preset synchronization sequence of the wireless audio playing device, and taking a moment corresponding to the maximum value in a plurality of obtained matching values as a peak moment, wherein the length of the sequence intercepted by the time sliding window is equal to the length of the preset synchronization sequence, and the preset synchronization sequence corresponds to a fixed position of the synchronization segment;

counting the time difference between the peak time corresponding to the current wireless data packet and the peak time corresponding to the previous wireless data packet according to the first clock signal, and adjusting the speed of the first clock signal according to the counting result so as to enable the counting result of the time difference between two adjacent peak times to approach to a preset counting value;

and playing the data segment or the preset position data of the data segment according to a local second clock signal of the wireless audio playing device after a preset number of clock cycles of the first clock signal from the peak time, wherein the frequency multiple relation between the first clock signal and the second clock signal is fixed.

2. The method of claim 1, wherein counting a time difference between a peak time corresponding to a current wireless data packet and a peak time corresponding to a previous wireless data packet according to the first clock signal, and adjusting a speed of the first clock signal according to the counting result so that a counting result of the time difference between two adjacent peak times approaches a preset counting value, comprises:

when the counting result is smaller than the preset counting value, reducing the clock period of the first clock signal;

and when the counting result is greater than the preset counting value, increasing the clock period of the first clock signal.

3. The method of claim 2, wherein the first clock signal and the second clock signal are both down-converted by a fixed multiple based on a reference clock signal, the reference clock signal is generated by a phase-locked loop according to a clock signal of a local crystal oscillator, and the first clock signal is adjusted by adjusting a clock period of the local crystal oscillator.

4. A wireless audio playback device, comprising:

the wireless audio playing device comprises a sampling demodulation module, a wireless audio sending device and a sampling demodulation module, wherein the sampling demodulation module is used for sampling a received wireless signal according to a local first clock signal of the wireless audio playing device to obtain a sampling sequence and demodulating the sampling sequence to obtain a wireless data packet, the wireless data packet comprises a synchronization section and a data section, the synchronization section comprises a synchronization sequence in a fixed mode, the data section comprises audio codes, and the wireless signal is sent by the wireless audio sending device at regular time according to the local clock signal;

the matching module is used for intercepting the sampling sequence according to a time sliding window, performing similarity matching on the intercepted sequence and a local preset synchronization sequence of the wireless audio playing device, and taking a moment corresponding to the maximum value in a plurality of obtained matching values as a peak value moment, wherein the length of the sampling sequence intercepted by the time sliding window is equal to the length of the preset synchronization sequence, and the preset synchronization sequence corresponds to a fixed position of the synchronization segment;

the adjusting module is used for counting the time difference between the peak time corresponding to the current wireless data packet and the peak time corresponding to the previous wireless data packet according to the first clock signal, and adjusting the speed of the first clock signal according to the counting result so as to enable the counting result of the time difference between two adjacent peak times to approach to a preset counting value;

and the playing module is configured to play the data segment or the predetermined position data of the data segment according to a second local clock signal of the wireless audio playing device after a preset number of clock cycles of the first clock signal from the peak time, where a frequency multiple relationship between the first clock signal and the second clock signal is fixed.

5. The device of claim 4, wherein the adjustment module is specifically configured to:

when the counting result is smaller than the preset counting value, reducing the clock period of the first clock signal;

and when the counting result is greater than the preset counting value, increasing the clock period of the first clock signal.

6. The apparatus of claim 5, wherein the first clock signal and the second clock signal are both down-converted by a fixed multiple based on a reference clock signal, the reference clock signal is generated by a phase-locked loop according to a clock signal of a local crystal oscillator, and the clock period of the local crystal oscillator is adjusted to adjust the speed of the first clock signal.

7. A wireless audio playback device comprising a memory and a processor, the memory storing instructions that the processor executes to perform the method of any of claims 1 to 3.

8. A wireless audio transceiving system, comprising a wireless audio transmitting device and a plurality of wireless audio playing devices according to any one of claims 4 to 7, wherein the wireless audio transmitting device is configured to periodically transmit a wireless signal to each of the wireless audio playing devices according to a local clock signal thereof, the wireless signal is sampled and demodulated by the wireless audio playing devices to obtain a wireless data packet, the wireless data packet includes a synchronization segment and a data segment, the synchronization segment includes a synchronization sequence in a fixed pattern, the data segment includes an audio code and increases with time, a counting result of a time difference between two adjacent peak time by each wireless audio playing device approaches to a preset counting value, and clock periods of a second clock signal local to each wireless audio playing device approach to equal or completely equal.

Technical Field

The application belongs to the technical field of audio signal processing and wireless communication, and particularly relates to a wireless audio synchronization method, playing equipment and a transceiving system.

Background

A wireless audio transceiving system generally includes a wireless audio transmitting device and a plurality of wireless audio playing devices. The plurality of wireless audio playing devices are, for example, a left earphone and a right earphone, and are, for example, a plurality of wireless speakers. If the playing of each wireless audio playing device is not synchronous, the sound quality is reduced.

Most of the existing synchronization methods are implemented by exchanging clock signals among wireless audio playing devices. This wireless audio synchronization method has limited time accuracy and requires additional control data interaction.

Disclosure of Invention

The present application is directed to a wireless audio synchronization method, a playing device and a transceiving system, so as to at least partially solve the technical problems in the prior art. In the present application, it is not necessary to transmit time control data between the transmission apparatus and the playback apparatus and between the playback apparatus and the playback apparatus, but it is only necessary to perform local automatic adjustment based on the reception time of a wireless packet containing audio data that is originally to be transmitted. In addition, in the application, the high-speed clock required in the radio frequency receiving is adopted to determine and adjust the time error of the audio signal, and compared with the common method based on the time synchronization of the audio signal, the method is more accurate in precision.

In order to solve the technical problem, the following technical scheme is adopted in the application: a wireless audio synchronization method is applied to a wireless audio playing device, and comprises the following steps:

sampling a received wireless signal according to a local first clock signal of the wireless audio playing device to obtain a sampling sequence, demodulating the sampling sequence to obtain a wireless data packet, wherein the wireless data packet comprises a synchronization section and a data section, the synchronization section comprises a fixed-mode synchronization sequence, the data section comprises audio codes, and the wireless signal is sent by a wireless audio sending device at regular time according to the local clock signal;

intercepting the sampling sequence according to a time sliding window, performing similarity matching on the intercepted sequence and a local preset synchronization sequence of the wireless audio playing device, and taking a moment corresponding to the maximum value in a plurality of obtained matching values as a peak moment, wherein the length of the sequence intercepted by the time sliding window is equal to the length of the preset synchronization sequence, and the preset synchronization sequence corresponds to a fixed position of the synchronization segment;

counting the time difference between the peak time corresponding to the current wireless data packet and the peak time corresponding to the previous wireless data packet according to the first clock signal, and adjusting the speed of the first clock signal according to the counting result so as to enable the counting result of the time difference between two adjacent peak times to approach to a preset counting value;

and playing the data segment or the preset position data of the data segment according to a local second clock signal of the wireless audio playing device after a preset number of clock cycles of the first clock signal from the peak time, wherein the frequency multiple relation between the first clock signal and the second clock signal is fixed.

In order to solve the technical problem, the following technical scheme is adopted in the application: a wireless audio playback device, comprising:

the wireless audio playing device comprises a sampling demodulation module, a wireless audio sending device and a sampling demodulation module, wherein the sampling demodulation module is used for sampling a received wireless signal according to a local first clock signal of the wireless audio playing device to obtain a sampling sequence and demodulating the sampling sequence to obtain a wireless data packet, the wireless data packet comprises a synchronization section and a data section, the synchronization section comprises a synchronization sequence in a fixed mode, the data section comprises audio codes, and the wireless signal is sent by the wireless audio sending device at regular time according to the local clock signal;

a matching module, configured to intercept the sampling sequence according to a time sliding window, perform similarity matching on the intercepted sequence and a local preset synchronization sequence of the wireless audio playing device, and use a time corresponding to a maximum value of the obtained multiple matching values as a peak time, where a length of the sequence intercepted by the time sliding window is equal to a length of the preset synchronization sequence, and the preset synchronization sequence corresponds to a fixed position of the synchronization segment;

the adjusting module is used for counting the time difference between the peak time corresponding to the current wireless data packet and the peak time corresponding to the previous wireless data packet according to the first clock signal, and adjusting the speed of the first clock signal according to the counting result so as to enable the counting result of the time difference between two adjacent peak times to approach to a preset counting value;

and the playing module is configured to play the data segment or the predetermined position data of the data segment according to a second local clock signal of the wireless audio playing device after a preset number of clock cycles of the first clock signal from the peak time, where a frequency multiple relationship between the first clock signal and the second clock signal is fixed.

In order to solve the technical problem, the following technical scheme is adopted in the application: a wireless audio playback device comprising a memory and a processor, the memory storing instructions that the processor executes to perform the aforementioned wireless audio synchronization method.

In order to solve the technical problem, the following technical scheme is adopted in the application: a wireless audio receiving and transmitting system comprises a wireless audio transmitting device and a plurality of wireless audio playing devices, wherein the wireless audio transmitting device is used for transmitting wireless signals to each wireless audio playing device according to local clock signals of the wireless audio transmitting device in a timing mode, the wireless signals are sampled and demodulated by the wireless audio playing devices to obtain wireless data packets, each wireless data packet comprises a synchronization section and a data section, each synchronization section comprises a synchronization sequence in a fixed mode, each data section comprises audio codes, the counting results of the time difference of two adjacent peak values of each wireless audio playing device are close to the same preset counting value along with the increase of time, and the clock periods of second local clock signals of each wireless audio playing device are close to the same or completely the same.

Compared with the prior art, the beneficial effect of this application is: the wireless audio transmitting equipment and the playing equipment directly carry out time synchronization through the transceiving of wireless data packets without additional synchronization information. Wireless data packets are also inherently needed to transmit audio data. Meanwhile, as the number of the wireless data packets received by the wireless audio playing device increases, the product of the clock period of the local first clock signal of the wireless audio playing device and the preset count value approaches or is completely equal to the period of the wireless data packets sent by the wireless audio sending device. Because a plurality of wireless audio playing devices and the wireless audio sending device keep good synchronization, the synchronization among the playing devices can achieve a relatively ideal effect. For example, the clock periods of the first clock signal local to both the wireless audio playback device a and the wireless audio playback device B are approximately equal or completely equal. Generally, the distance between the wireless audio transmitting device and each wireless audio playing device is not large and the difference of the distances is not large, and the propagation speed of the electromagnetic wave is considered to be the light speed, so that the time difference caused by the physical distance can be ignored. The time when the wireless audio playing device a starts playing the audio content of the wireless data packet and the time when the wireless audio playing device B starts playing the audio content of the same wireless data packet are approximately the same or completely the same. Because the clock periods of the local second clock signals of the wireless audio playing devices a and B are approximately equal or completely equal, the speeds of the two playing devices playing the audio contents of the same wireless data packet are also approximately equal or completely equal. The synchronous playing of the wireless audio playing device A and the wireless audio playing device B can be realized without exchanging clock signals between the two devices. The time difference of playing the audio content of the same wireless data packet by the two does not exceed one clock period of the first clock signal at most. Typically, the clock period of the first clock signal is in the order of microseconds or even lower, and the accuracy of the audio synchronization is very high.

Drawings

Fig. 1 is a flow chart of a wireless audio synchronization method according to an embodiment of the application.

Fig. 2 is a block diagram of a wireless audio transceiving system according to an embodiment of the present application.

Fig. 3 is a timing diagram of a wireless audio transmitting device transmitting wireless data packets according to an embodiment of the application.

Fig. 4 is a schematic diagram of a method for finding a correlation peak by a wireless audio playback device according to an embodiment of the present application.

Fig. 5 is a block diagram of a wireless audio playback device according to an embodiment of the present application.

Fig. 6 is a block diagram of a wireless audio playback device according to another embodiment of the present application.

Detailed Description

In this application, it will be understood that terms such as "including" or "having," or the like, are intended to indicate the presence of the disclosed features, integers, steps, acts, components, parts, or combinations thereof, but do not preclude the presence or addition of one or more other features, integers, steps, acts, components, parts, or combinations thereof.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

The application is further described with reference to examples of embodiments shown in the drawings.

Referring to fig. 1, an embodiment of the present application provides a wireless audio synchronization method applied to a wireless audio playing device, and the method includes the following steps.

Step 101, sampling a received wireless signal according to a local first clock signal of the wireless audio playing device to obtain a sampling sequence, and demodulating the sampling sequence to obtain a wireless data packet, where the wireless data packet includes a synchronization segment and a data segment, the synchronization segment includes a synchronization sequence in a fixed mode, the data segment includes an audio code, and the wireless signal is sent by a wireless audio sending device at regular time according to the local clock signal.

Referring to fig. 2, the wireless audio transmitting device S transmits the same wireless data packet (e.g., one wireless data packet every 10 ms) to the wireless audio playback devices A, B and C in accordance with its local clock signal timing. Specifically, the present application does not limit the modulation method of the wireless audio signal. The data segment in the wireless data packet may be divided into multiple segments, and each of the wireless audio playback devices A, B and C may play one of the segments separately. The audio content of the data segments of the wireless data packet may also be non-segmented and the wireless audio playback devices A, B and C play the same content.

Referring to fig. 3, the wireless audio transmitting apparatus transmits wireless data packets at regular time according to its local clock signal and a preset modulation scheme. The former part of the wireless data packet is, for example, a sync segment, and the latter part is, for example, a data segment. In the example shown in fig. 3, the wireless audio transmitting device starts to transmit wireless data packets at time T0, time T0+ T, and time T0+ 2T. Since the clock period of the local clock signal of the wireless audio transmitting apparatus is fixed, the duration of the period T in which it transmits the wireless data packet is also fixed.

Step 102, intercepting the sampling sequence according to a time sliding window, performing similarity matching on the intercepted sequence and a local preset synchronization sequence of the wireless audio playing device, and taking a time corresponding to a maximum value of a plurality of obtained matching values as a peak time, wherein the length of the sequence intercepted by the time sliding window is equal to the length of the preset synchronization sequence, and the preset synchronization sequence corresponds to a fixed position of the synchronization segment.

Fig. 4 shows the sequence content assuming the synchronization sequence is a binary bit: "1101010101110001***1011". For convenience of explanation, it is assumed that the sampling sequence is also "1101010101110001 × 1011".

The length of the time sliding window is for example 7 (this is merely for convenience of illustration and the length of the actual time sliding window may be much larger). The predetermined sampling sequence is, for example: "1110001". The coding sequence that the time sliding window first intercepts from the sampling sequence of the sync segment is: "1101010". Then, the time sliding window slides by one bit, and the coded sequence is cut from the sampling sequence of the synchronous segment: "1010101". The similarity matching algorithm for two binary codes is, for example, to count binary data bits with the same value at corresponding positions (the manner is not limited thereto). Obviously, when the sliding time window is slid to the tenth bit of the sample sequence of the sync segment, a large similarity match value is obtained. This time serves as a reference time. The peak time at this time may be defined as the sampling time of the last sample value corresponding to the maximum matching value when all the sample sequences match.

It is noted here that the sample sequence is used in a binary fashion for ease of illustration only. In practical implementations, it is more likely that the local default synchronization sequence and the sample sequence to be matched are both non-single-bit values, for example, if the sample sequence is sampled by a 12-bit ADC, each value in the sample sequence is a 12-bit value. Accordingly, a plurality of 12-bit values form a predetermined synchronization sequence, rather than a predetermined synchronization sequence formed by a single-bit value sequence.

And in practical systems the sample value for each bit in the synchronization sequence may be a plurality of sample values. For example, if the original bit sequence is 1010, and if it is up-sampled by a factor of 4 in an actual system, then the corresponding sample value may be "21023025021020105152002202402302515312". Assume that the predetermined synchronization sequence is "25052403", meaning that the third oversampling point is the best sampling point at the sampling time.

Step 103, counting the time difference between the peak time corresponding to the current wireless data packet and the peak time corresponding to the previous wireless data packet according to the first clock signal, and adjusting the speed of the first clock signal according to the counting result, so that the counting result of the time difference between two adjacent peak times approaches to a preset counting value.

For example, if referring to the description of fig. 2, this preset count value is a count value corresponding to 10 milliseconds.

Specifically, both the wireless audio transmitting device and the wireless audio playing device have a local clock for measuring local time, and they are nominally set to the same frequency value, e.g., 48Mhz, but are actually erroneous. When the counting result of the time difference between two adjacent peak time is equal to the preset counting value, the local clock period of the wireless audio playing device is completely consistent with the local clock period of the wireless audio sending device.

And step 104, after a preset number of clock cycles of the first clock signal from the peak time, playing the data segment or the predetermined position data of the data segment according to a local second clock signal of the wireless audio playing device, wherein the frequency multiple relation between the first clock signal and the second clock signal is fixed.

With the increase of the number of the wireless data packets received by the wireless audio playing device, the product of the clock period of the first clock signal local to the wireless audio playing device and the preset count value is wirelessly close to or completely equal to the period of the wireless data packets sent by the wireless audio sending device. For example, the clock periods of the first clock signal local to both the wireless audio playback device a and the wireless audio playback device B are approximately equal or completely equal. Generally, the distance between the wireless audio transmitting device and each wireless audio playing device is not large and the difference of the distances is not large, and the propagation speed of the electromagnetic wave is considered to be the light speed, so that the time difference caused by the physical distance can be ignored. The time when the wireless audio playing device a starts playing the audio content of the wireless data packet and the time when the wireless audio playing device B starts playing the audio content of the same wireless data packet are nearly the same or completely the same, and the time difference between the two will not exceed the clock period of the first clock signal at most. Because the clock periods of the local second clock signals of the wireless audio playing devices a and B are approximately equal or completely equal, the speeds of the two playing devices playing the audio contents of the same wireless data packet are also approximately equal or completely equal. The synchronous playing of the wireless audio playing device A and the wireless audio playing device B can be realized without exchanging clock signals between the two devices. The time difference of playing the audio content of the same wireless data packet by the two does not exceed one clock period of the first clock signal at most. Typically, the clock period of the first clock signal is in the order of microseconds or even lower, and the accuracy of the audio synchronization is very high.

In some embodiments, counting a time difference between a peak time corresponding to a current wireless data packet and a peak time corresponding to a previous wireless data packet according to the first clock signal, and adjusting a speed of the first clock signal according to the counting result, so that the counting result of the time difference between two adjacent peak times approaches a preset counting value, includes:

when the counting result is smaller than the preset counting value, reducing the clock period of the first clock signal;

and when the counting result is greater than the preset counting value, increasing the clock period of the first clock signal.

Specifically, the first clock signal and the second clock signal are obtained by frequency reduction according to a fixed multiple based on a reference clock signal, the reference clock signal is generated by a phase-locked loop according to a clock signal of a local crystal oscillator, and the speed of the first clock signal is adjusted by adjusting the clock period of the local crystal oscillator.

Specifically, the local oscillator is connected to the matching circuit, and the clock period of the local oscillator can be changed by adjusting the capacitance value of a capacitor in the matching circuit, for example. Of course, the clock period of the local crystal oscillator may be changed according to other known techniques by those skilled in the art, and the present application is not limited thereto. The circuit form of the matching circuit may also be determined by known techniques. This application is not repeated herein.

And the clock frequency of the local crystal oscillator is increased or decreased, the clock frequencies of the first clock signal and the second clock signal are increased or decreased in an equal proportion. For example, if the clock frequency of the local oscillator is increased by 1%, the clock frequency of the first clock signal is increased by 1%, and the clock frequency of the second clock signal is increased by 1%. For example, if the clock frequency of the local oscillator is reduced by 1%, the clock frequency of the first clock signal is reduced by 1%, and the clock frequency of the second clock signal is reduced by 1%.

Of course, the adjustment of the clock periods of the first clock signal and the second clock signal may also be implemented by changing the number of periods of the reference clock signal included in one clock period of the first clock signal and the second clock signal locally in the wireless audio playing device.

Based on the same inventive concept, referring to fig. 5, an embodiment of the present application further provides a wireless audio playing device, including:

the wireless audio playing device comprises a sampling demodulation module 1, a wireless audio transmitting device and a processing module, wherein the sampling demodulation module 1 is used for sampling a received wireless signal according to a local first clock signal of the wireless audio playing device to obtain a sampling sequence and demodulating the sampling sequence to obtain a wireless data packet, the wireless data packet comprises a synchronization section and a data section, the synchronization section comprises a synchronization sequence in a fixed mode, the data section comprises audio codes, and the wireless signal is transmitted by the wireless audio transmitting device at regular time according to the local clock signal;

the matching module 2 is configured to intercept the sampling sequence according to a time sliding window, perform similarity matching on the intercepted sequence and a local preset synchronization sequence of the wireless audio playing device, and use a time corresponding to a maximum value of the obtained multiple matching values as a peak time, where a length of the sequence intercepted by the time sliding window is equal to a length of the preset synchronization sequence, and the preset synchronization sequence corresponds to a fixed position of the synchronization segment;

the adjusting module 3 is configured to count a time difference between a peak time corresponding to a current wireless data packet and a peak time corresponding to a previous wireless data packet according to the first clock signal, and adjust the speed of the first clock signal according to the counting result, so that the counting result of the time difference between two adjacent peak times approaches a preset counting value;

and the playing module 4 is configured to play the data segment or the predetermined position data of the data segment according to a second local clock signal of the wireless audio playing device after a preset number of clock cycles of the first clock signal from the peak time, where a frequency multiple relationship between the first clock signal and the second clock signal is fixed.

In some embodiments, the adjusting module 3 is specifically configured to:

when the counting result is smaller than the preset counting value, reducing the clock period of the first clock signal;

and when the counting result is greater than the preset counting value, increasing the clock period of the first clock signal.

Specifically, the first clock signal and the second clock signal are obtained by frequency reduction according to a fixed multiple based on a reference clock signal, the reference clock signal is generated by a phase-locked loop according to a clock signal of a local crystal oscillator, and the speed of the first clock signal is adjusted by adjusting the clock period of the local crystal oscillator.

Referring to fig. 6, an embodiment of the present application provides a wireless audio playing device, which includes a memory and a processor, wherein the memory stores instructions, and the processor executes the instructions to execute the aforementioned wireless audio synchronization method.

It should be noted that the wireless audio playing device further includes a wireless radio frequency transceiver module, an audio playing module, a clock module, and the like. The wireless radio frequency receiving and transmitting module is used for receiving and transmitting wireless signals. The audio playing module is used for playing the audio codes. The clock module is connected with the crystal oscillator and used for generating various clock signals required by the wireless audio playing equipment. These can be designed according to the prior art.

The embodiment of the present application further provides a wireless audio transceiving system, including wireless audio transmitting device and a plurality of the aforesaid wireless audio playback devices, wireless audio transmitting device is used for regularly sending wireless signal to each according to its local clock signal wireless audio playback device, wireless signal warp obtain wireless data package after wireless audio playback device samples and demodulates, wireless data package includes synchronization segment and data segment, the synchronization segment includes the synchronization sequence of fixed mode, the data segment includes audio encoding, and along with time increase, each wireless audio playback device is to the same count value of predetermineeing to the count result of the time difference of two adjacent peak moments, and the clock cycle of the local second clock signal of each wireless audio playback device is close to being equal or equal completely.

Following the previous example, the wireless audio playback devices A, B and C are both sampling exactly the first clock signal at 48MHz, and the audio playback speeds of the three devices are exactly the same.

The embodiments in the present application are described in a progressive manner, and the same and similar parts among the embodiments can be referred to each other, and each embodiment focuses on the differences from the other embodiments.

The protective scope of the present application is not limited to the above-described embodiments, and it is apparent that various modifications and variations can be made to the present application by those skilled in the art without departing from the scope and spirit of the present application. It is intended that the present application also include such modifications and variations as come within the scope of the appended claims and their equivalents.