High quality, controlled latency multi-channel wireless digital audio distribution system and methods

Abstract

A multichannel wireless digital audio distribution system provides for the synchronization of the output of audio data by different receiving units set to output audio data for receiver unit assigned channels. The transmitter includes parallel data respectively representing a plurality of audio data channels in each data packet. The data packets are broadcast wirelessly with predetermined packets including a timing marker. Each receiver unit receives the broadcast data packets and selects the parallel data respectively representing the receiver unit assigned audio data channel. The receiver unit outputs the selected data synchronized to the receipt of the timing marker by said receiving unit.

Description

The present application is related to System and Methods for Aligning Capture and Playback Clocks in a Wireless Digital Audio Distribution System, Ser. No. ______, filed Aug. 4, 2006 and assigned to the Assignee of the present Application.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention is generally related to the wireless distribution of high-quality audio signals and, in particular to a system and methods of distributing high bit rate, multi channel, audio wirelessly while maintaining a constant, low, playback to source latency and channel to channel phase coherency.

2. Description of the Related Art

In the audio space there are many places that latency, high quality, and more than two channels are critical to the quality of the experience. It is also difficult to retrofit standard spaces with cables to the support multiple channels of audio. Today's definition of high end audio in the Home Theater space is 7 channels of audio samples at 48,000 samples per second with 24 bits of data per sample. Further, the marketplace is rapidly maturing from 5.1 (6 channel) to 11.1 (12 channel) sound system requirements.

Conventional wireless solutions rely on simple, low-cost radio technologies, such as frequency modulation (FM) and basic spread spectrum modulation schemes. The consequence of this is a reduction in the number of bits used for each audio sample, with a corresponding reduction in dynamic range and audio quality.

A critical requirement exists in both spaces to minimize and establish a constant or fixed latency in the system and to keep all channels aligned in time. Latency refers to time delays measured from audio source-to-output and from channel-to-channel. Source-to-output delays are a problem for all sound venues including, in particular, Home Theater and other video/audio systems, where the audio program material is synchronized to a video screen (“lip-sync”). Acoustics engineers generally consider source-to-output delays greater than 10 milliseconds to be noticeable. As for latency from channel-to-channel, the human ear is extremely sensitive to these phase delays and experts describe audio delivered with channel-to-channel delays greater than 1 millisecond as sounding “disjointed” or “blurry”.

The same data and sampling rate are in use in recording and sound reinforcement, only the desired number of channels is generally between 8 and 32. In conferencing use, the latency and wireless requirement are compounded by a need for accurate routing of audio paths with intelligent addition of signals and echo cancellation.

Consequently, there is a clear need to solve all of these problems in a wireless audio distribution system.

SUMMARY OF THE INVENTION

Thus, a general purpose of the present invention is to provide an efficient wireless, high bit rate, multi channel, audio system capable of maintaining constant, low, playback to source latency while further maintaining channel to channel phase coherency.

This is achieved in the present invention by providing a multichannel wireless digital audio distribution system that enables the synchronization of the output of audio data by different receiving units set to output audio data for receiver unit assigned channels. The transmitter includes parallel data respectively representing a plurality of audio data channels in each data packet. The data packets are broadcast wirelessly with predetermined packets including a timing marker. Each receiver unit receives the broadcast data packets and selects the parallel data respectively representing the receiver unit assigned audio data channel. The receiver unit outputs the selected data synchronized to the receipt of the timing marker by said receiving unit.

An advantage of the present invention is base configurations are immediately capable of distributing 16 channels of audio with a full 24 bits per sample and 48,000 samples per second.

Another advantage of the present invention is the initial preferred embodiments are capable of achieving a fixed, repeatable inter-channel differential latency of less than 0.001 millisecond and a fixed, repeatable source to speaker latency of less than 2 milliseconds.

A further advantage of the present invention is that it enables multi-channel audio sources to be placed “out-of-view”, while supporting a full complement of audio speakers to be installed throughout a room without wires. Costly physical rewiring is not required.

Still another advantage of the present invention is that the audio playback delays can be precisely adjusted and maintained in fixed relation to “tune” audio phasing for specific listener/speaker positions and room acoustics.

Yet another advantage of the present invention is that the transmitters and receivers, as implemented in the preferred embodiments, can and will coexist with present wireless networking systems without introducing interference, without loss of audio fidelity, and while meeting all FCC and CSA certification requirements.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 provides a block diagram of a preferred architecture of a multi-channel audio transmitter constructed in accordance with the present invention;

FIG. 2 is a flow diagram illustrating the pipeline processing of data through a wireless transmitter and receiver in accordance with a preferred embodiment of the present invention;

FIG. 3 is a block diagram of a source transmitter-based wireless audio packet distribution timing control configuration constructed in accordance with a preferred embodiment of the present invention;

FIG. 4 is a block diagram of a receiver-based timing control configuration for the timing controlled distribution of wireless audio packets in accordance with a preferred embodiment of the present invention;

FIG. 5 is a block diagram of a preferred architecture of a multi-channel wireless audio packet transmitter constructed in accordance with a preferred embodiment of the present invention;

FIG. 6 is a block diagram of a preferred architecture of a multi-channel discriminating wireless audio packet receiver constructed in accordance with a preferred embodiment of the present invention;

FIG. 7 is a flow diagram illustrating the pipeline processing of data through a wireless transmitter and receiver in accordance with a receiver-based timing control configuration of a preferred embodiment of the present invention;

FIG. 8 is a block diagram of a preferred architecture of a multi-channel discriminating wireless audio packet receiver supporting receiver-based timing control as constructed in accordance with a preferred embodiment of the present invention; and

FIG. 9 is a block diagram of a preferred architecture of a multi-channel wireless audio packet transmitter supporting receiver-based timing control as constructed in accordance with a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides for the packet transmission of audio data from a transmitter, typically coupled to a multiple channel audio data source, to a set of wireless packet data receivers. The receivers are programmable to associate operation with an assigned transmitter. The receivers are further programmable to select and decode a specified channel or channels of the transmitted multiple channel content. In preferred configuration, a separate receiver is provided for each audio reproduction speaker in a sound system and, dependent on the speaker type and placement, selects and decodes a corresponding channel of the audio content. Receivers associated with the center channel, base, various left and right side and rear effects speakers each preferably decode respective audio content channels provided through the transmitter for respective speakers.

The transmitters and receivers of the present invention preferably support both digital or analog format inputs and outputs for audio data. In particular, the receivers of the present invention provide may be integrated into the speaker enclosures and closely integrated with the speaker amplification system. That is, wireless transmission of audio content while maintaining high audio fidelity enables audio component manufacturers to locate and isolate speaker amplifiers internal to the speaker enclosures. This removes the “hot and heavy” power sources and amplifiers from audio source appliances. Migration of these components out to the speakers themselves enables manufactures to fully implement modern digital switching amplifier topologies, including specifically Class D amplifier designs, in the speakers. This will enable fundamental improvements in sound reproduction while achieving reduced size, cost, power consumption, and EMI radiation in all system components. Users also gain the advantages of flexible installation and reconfiguration.

The transmitters and receivers used in the preferred embodiments are preferably based on the high-volume commodity radio components used in conventional wireless networking systems, such as IEEE 802.11g and 802.11n. For purposes of implementation, the present invention provides for the replacement of the conventional Media Access Control (MAC) layer with a data processing engine specifically designed to deliver high bit rate isochronous data, such as audio and video, with low latency in accordance with the present invention. Clock capture and alignment by the data processing engine of the present invention is further described in the co-pending application, System and Methods for Aligning Capture and Playback Clocks in a Wireless Digital Audio Distribution System, Ser. No. ______ filed concurrently herewith, assigned to the assignee of the present invention, which is hereby incorporated by reference.

The system and methods of the present invention has a basic architecture and manner of operation that allow use in multiple ways. All uses are generally based on the same elements. The use sets the operation and data flow of these elements. The preferred general architecture of the present invention is shown in FIG. 1.

The Master Timing System contains a very accurate millisecond level interval generator. The millisecond intervals are derived from the master CODEC sampling clock and this interval is distributed to the slave devices through radio signaling. The slave devices will use this to synchronize their CODEC playback clocks.

The radio and MAC (Media Access Controller) sections are used to control the radio and transfer the data. The data clock is independent of the Master Timing System and is part of the overall radio design. The input to the MAC from the Master Timing System is used to synchronize the sending of data blocks marked as Marker Sample Blocks. The Sample Block Markers on the receiver will be generated based on the timing of these packets.

The Data Buffering and Sequencing block manages taking the many data streams and either encoding them for sending as data blocks or decoding the received blocks and returning the data to the many data streams.

The programmable delay block is used in the receivers to allow for time alignment of the speakers in the system. It is not used to adjust for transmission delays but rather for listener to speaker distance adjustment for acoustics.

The CODEC and Digital Audio Interfaces provide the different ways the audio can be brought or sent to outside systems for use. The diagram shown in FIG. 2 illustrates the method of transmission used by the master transmitter with receipt and playback on a slave receiver. The following describes operation at the corresponding stages illustrated in FIG. 2.

• • 1) The samples are collected from the CODECS or Digital Audio Interfaces into a Sample Block Buffer. The data in the Sample Block Buffer preferably implements data redundancy injection for Forward Error Correction (FEC) and is organized into a Send Buffer.
  • 2) The Sample Block Buffer (Send 1) is transmitted over the radio link as a packet. The Block may be sent more than once (Send 2) to provide data redundancy. The first Data Block sent in this mode of operation will have its Sample Block Marker bits set.
  • 3) When the receiver radio and MAC decode a valid Sample Block with the Marker bits set the MAC will trigger a Sample Block Marker at a delay determined during the initialization of the radio link. The delay will provide a Sample Block Marker at Sample Block boundaries.
  • 4) The Sample Block is played starting at the Sample Block Marker generated in step 3. The received Data Buffer is processed through a convolutional decoder and the resulting data is checked and repaired by use of the FEC methods employed and is returned to being a Sample Block that can the be sequence for playing.
  • 5) The entire sample Block is sequenced out. The three phases of collection, transport, and playback are pipelined such that every step is running simultaneously.

The method achieves a fixed latency using asynchronous packets by using the first packet or Block to generate a calibrated Sample Block Marker to show the boundary of the playback Block.

When the receiver detects the first send of the data block a timing chain is activated to generate the Interval Alignment Marker. The multiple sends and the error detection and correction codes embedded in the sent data are used to insure that the data is received correctly. If there is an error in the received data the Interval Alignment Marker is not generated and through either data repetition or interpolation a block of 48 samples are supplied to the buffering and playback.

Data security and quality is achieved by sending the collected data multiple times in the transport period or through the embedding error correction and detection codes with the data streams in the Block.

In use, the present invention can be implemented in multiple different configurations. Two exemplary embodiments, illustrating different configuration options, are presented as examples.

• • 1) FIG. 3 illustrates the timing control flow for a configuration as a single transmitter acting as a timing master to a single slave or multiple slave receivers.
  • 2) FIG. 4 illustrates the timing control flow for a configuration as a single receiver acting as a timing master to a single or multiple slaved transmitters.

A preferred implementation of the single master transmitter configuration controller embodiment is shown in FIG. 5. As shown, the timing data buffering and sequencing are driven by the Master Timing System. The MAC will send the first data packet at a preset delay relative to the Sample Block Marker. The MAC will not set the Sample Block Marker bit on subsequent redundant sends of the data packet.

A preferred implementation of the slave receiver is shown in FIG. 6. The slave receiver detects the Sample Block Marker bit in the received data packet and a timing chain is activated to generate the Sample Block Marker for use in the Data Buffering and Sequencing of the received data. Redundant data is discarded after a valid packet is received.

For the preferred implementation of a single receiver as a timing master to one or more slaved transmitters, the preferred timing control flow is changed relative to that shown in FIG. 2. As shown in FIG. 7, the preferred timing control flow for the receiver timing master embodiment allows for the aligning of the timing in all-the transmitters to match the receiver that acts as the timing master. The following describes operation at the corresponding stages illustrated in FIG. 7.

• • 1) All channels collect their data stream for an interval's duration. While FIG. 7 illustrates collection for two channels, the present invention contemplates collection and operation on data for 1 to N channels, with N being from 8 to 16 in the preferred embodiments of the present invention.
  • 2) A Sample Block Marker (SBM) packet is signaled over the radio link from the Master Receiver to the Slave Transmitter(s).
  • 3) The transmitting device containing channel 1 waits a specified interval after the SBM signal has been removed and then transmits its Sample Block (SB1) to the Master Receiver.
  • 4) The transmitting device containing channel 2 waits a specified interval after the previous Sample Block has been sent and then transmits its Sample Block (SB2) to the Master Receiver. The channel Block signaling continues as in step 3 & 4 until all the transmitting channels have sent their Blocks. The data is saved in the Slave Transmitter's MAC and repeated when the time for redundant signaling has come.
  • 5) A Sample Block Marker is generated in the Slave Transmitter to align the Sample Block Collection start timing to the Master Receiver playback timing during each cycle.

A preferred implementation of the master receiver, as used in the receiving timing master embodiment, is shown in FIG. 8. As shown, the master receiver sends the sample block markers to the slave transmitters but receives data sent round robin from the slave transmitters. All slave transmitters receive the sample block marker packet sent from the master receiver and slave their sampling clocks to that timing. This is one case where a receiver transmits information, though only the signaling information necessary to align all the sampling timing in the slave transmitters.

A preferred implementation of the slave transmitter, as used in the receiving timing master embodiment, is shown in FIG. 9. The slave transmitter, as shown, receives a sample block marker packet from the master receiver and uses that to align its master timing system to that of the one or more master receivers. During system initialization the channel number and therefore the transmission order are determined and set for each of the slave transmitters.

Thus, a system and methods for providing for the distribution of high bit rate, multi channel, audio wirelessly while maintaining a constant, low, playback to source latency and channel to channel phase coherency operable in multiple configurations has been described.

In view of the above description of the preferred embodiments of the present invention, many modifications and variations of the disclosed embodiments will be readily appreciated by those of skill in the art. It is therefore to be understood that, within the scope of the appended claims, the invention may be practiced otherwise than as specifically described above.

Claims

1. A method of operating a wireless digital audio distribution system to synchronize the output of audio data by receiving units, wherein a transmitting unit provides for the wireless packet transmission of audio data for receipt by a plurality of receiving units, said method comprising the steps of: a) generating a sequence of audio data packets wherein each said data packet includes parallel data respectively representing a plurality of audio data channels; b) broadcasting wirelessly, by said transmitter unit, said sequence of audio data packets, wherein said transmitter unit includes a timing marker in first predetermined ones of said audio data packets; c) receiving wirelessly, by a predetermined one of said plurality of receiving units, said sequence of audio data packets; d) selecting, from a second predetermined one of said audio data packets, parallel data respectively representing a predetermined one of said plurality of audio data channels; and e) outputting, said parallel data respectively representing a predetermined one of said plurality of audio data channels synchronized to the receipt of said timing marker by said receiving unit.

2. The method of claim 1 wherein said second predetermined one of said audio data packets is one of said first predetermined ones of said audio data packets.

3. The method of claim 1 wherein said step of broadcasting further includes redundantly broadcasting said sequence of audio data packets.

4. The method of claim 3 wherein said second predetermined one of said audio data packets is exclusive of said first predetermined ones of said audio data packets.

5. The method of claim 1 wherein said method further includes the steps of: a) detecting, by said predetermined one of said plurality of receiving units, a transmission data error in a predetermined one of said first predetermined ones of said audio data packets;. and b) correcting said transmission data error including selection of a predetermined one of said redundantly broadcast audio data packets in replacement of said predetermined one of said first predetermined ones of said audio data packets.

6. The method of claim 5 wherein said step of correcting includes successively performing correction by: a) first correcting said transmission data error using forward error correction to correct errors in the audio data transferred by said predetermined one of said first predetermined ones of said audio data packets; b) second correcting said transmission data error, where said step of first correcting fails, by replacement of said predetermined one of said audio data packets; and c) third correcting said transmission data error, where said step of second correcting fails, by interpolation using the audio data transferred by a select one of said sequence of audio data packets to construct substitute audio data in replacement for the audio data transferred by said predetermined one of said first predetermined ones of said audio data packets, wherein said select one of said sequence of audio data packets is received by said predetermined one of said plurality of receiving units prior to said predetermined one of said first predetermined ones of said audio data packets.