JP2005121693A - Streaming delivery system and streaming delivery method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a "streaming delivery system and streaming delivery method" which perform streaming delivery in such a manner that reproduction can be performed without interruption. <P>SOLUTION: A streaming player 43 starts the streaming reproduction of audio data of an A rank file which is streaming delivered from a streaming server 13. When the transmission quality of the streaming delivery thereafter deteriorates to the extent that the interruption occurs in the streaming reproduction, the streaming player 43 transmits a request for rank switching to the streaming server 13. Upon receipt of the request for rank switching, the streaming server 13 switches the streaming delivered data to the audio data of a B rank file lower in speech quality than the A rank file, consequently, smaller in bit rate as well (a). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a streaming distribution technique for distributing content data such as audio data and video data from a server in a form in which reception and reproduction can be performed in parallel on a reproduction terminal.

2. Description of the Related Art Conventionally, a technique of streaming distribution technology that distributes content data such as audio data and video data from a server in a form in which reception and playback can be performed in a playback terminal in parallel is known (for example, Patent Documents). 1).
In addition, when an error occurs in data transmission, the receiving side monitors the error, and when an error occurs, requests the transmitting side to retransmit the data that could not be normally received, and retransmits the transmitting side. A technique for retransmitting requested data is known (for example, Patent Document 2).
JP 2001-306437 A Japanese Patent Laid-Open No. 2002-199041

  In the streaming reproduction, data transfer and data reproduction on the data receiving side are performed in parallel. Therefore, if the transfer rate is lower than the data reproduction rate, the data transfer is not in time and the reproduction is interrupted. An unavoidable situation may occur. For example, when the transmission quality of the transmission path is deteriorated, the frequency of data retransmission according to the technique of Patent Document 2 is increased, and as a result, the effective data transfer rate is reduced, and reproduction on the receiving side is interrupted. End up.

On the other hand, in a mobile terminal that performs data transfer via wireless communication such as a mobile telephone network or a wireless LAN, such as a portable device or a vehicle-mounted device, the transmission quality of a transmission path used for data transfer varies relatively greatly. there is a possibility.
Therefore, when the streaming distribution technology is applied using these mobile devices as receiving devices, there is a possibility that the reproduction of data such as audio and video in the mobile devices is frequently interrupted.
Therefore, an object of the present invention is to realize streaming distribution that can suppress interruption of reproduction of a receiving device.

  In order to achieve the above object, the present invention provides a streaming distribution system including a streaming server that distributes streaming data representing content and a user terminal that includes a streaming player that receives and distributes streaming data that has been distributed. A normal reception rate calculating means for calculating, as a normal reception rate, a rate at which streaming data is normally received by the streaming player at the user terminal, and the normal reception rate and the bit rate of the streaming data currently received by the streaming player If the data does not match, the streaming server is requested to change the bit rate of the streaming data to the bit rate corresponding to the normal reception rate. Streaming rate distribution requesting means, and streaming data to be distributed for streaming to the streaming server in response to a request for changing the bit rate from the user terminal. A streaming quality changing means for changing to data is provided.

  According to such a streaming distribution system, the rate at which streaming data can be received normally due to transmission quality degradation during streaming distribution is not consistent with the bit rate of streaming data to the extent that streaming playback is interrupted. In some cases, the user terminal requests the streaming server to change the bit rate of the streaming data, thereby matching the bit rate of the streaming data distributed thereafter to the rate at which the streaming data can be normally received and played back. be able to. Therefore, it is possible to suppress the occurrence of interruption of streaming playback in the streaming player with respect to fluctuations in the rate at which streaming data can be normally received.

  Here, in the above streaming distribution system, the normal reception rate calculation means of the user terminal may calculate the normal reception rate based on a reception error rate of the streaming data. In the above streaming distribution system, the streaming data may represent content that is audio or video, for example.

  As described above, according to the present invention, it is possible to suppress the interruption of reproduction in the receiving device in streaming distribution.

Hereinafter, embodiments of the present invention will be described taking application to a system in which audio data is subject to streaming distribution as an example.
FIG. 1 shows the configuration of a streaming distribution system according to this embodiment.
As shown in the figure, the streaming distribution system includes a content distribution system 1 connected to the WAN 2 such as the Internet, and one or a plurality of user terminals 4 accommodated in the WAN 2 through wireless communication with the wireless base station 3. Here, the radio base station 3 is, for example, the radio base station 3 constituting the mobile telephone network.

The content distribution system 1 includes a Web server 11, a Web content storage unit 12, a streaming server 13, an encoder 14, an audio input device 15, a stream monitoring unit 16, a streaming file storage unit 17, and a file database 18.
On the other hand, the user terminal 4 includes a wireless communication device 41 that communicates with the wireless base station 3 via wireless communication, a Web browser 42, a streaming player 43, an audio output device 44, a speaker 45, and a reception state monitoring unit 46.
In such a configuration, the Web content storage unit 12 of the content distribution system 1 stores Web page data that the Web server 11 provides to the user terminal 4 via http. The web page stored in the web content storage unit 12 is read by the web server 11 by accessing the URL of the web page from the web browser 42 of the user terminal 4 and transferred to the user terminal 4. Then, the web browser 42 of the user terminal 4 displays the transferred web page. Here, the Web page provided by the Web server 11 in this way also includes a Web page of a menu for accepting selection of streaming content provided by the streaming server 13 from the user.

  Next, the streaming file storage unit 17 of the content distribution system 1 stores an audio file storing music data to be streamed by the streaming server 13. In addition, the encoder 14 generates a data stream of audio data that is stream-distributed in a live format by the streaming server 13 by encoding audio input from the audio input device 15.

  Here, in the present embodiment, the encoder 14 generates four data streams having different voice qualities in response to the voice input from the voice input device 15. A data stream with high audio quality has a high bit rate, and a data stream with low audio quality has a low bit rate. The streaming file storage unit 17 stores four audio files having different sound quality for the same music piece. Here, an audio file with high voice quality has a high bit rate, and an audio file with low voice quality has a low bit rate. Here, the bit rate refers to the amount of audio data representing sound for a unit time, and in streaming distribution, audio data is distributed using this bit rate as a transmission rate.

  Here, as a technology for generating audio data with different audio quality for a certain audio signal, a technology for increasing / decreasing the sampling rate of the audio data and a data per unit time without changing the sampling rate of the audio data itself. There are techniques to increase or decrease the amount. As a technique for increasing / decreasing the amount of data per unit time of audio data in this way, the resolution control for each frequency band in consideration of auditory characteristics, which is adopted in MP3 (MPEG-1 Audio Layer-3), etc. Thus, there is known a technique for performing compression encoding in units of each frame so as to keep a constant data amount per frame obtained by compression encoding data of a predetermined number of samples. In MP3, a technique called variable bit rate (VBR) is also employed, in which the bit rate per frame can be changed in a timely manner in one data stream.

  In the following, the encoder 14 encodes the input audio in a data format that supports this variable bit rate, and the streaming file storage unit 17 stores an audio file that is encoded in a data format that supports the variable bit rate. A case will be described as an example. In this case, the streaming player 43 performs streaming playback that supports such a variable bit rate.

Next, a file management table and a time block management table are recorded in advance in the file database 18 of the content distribution system 1.
As shown in FIG. 2a, the file management table is provided for each music piece in which an audio file is stored in the streaming file storage unit 17. Each file management table includes a representative URL, which is a URL virtually given to the song, and four audio files that are stored in the streaming file storage unit 17 and that represent the song with different audio qualities. URL is described.

Hereinafter, for convenience, the four audio files corresponding to the same music are referred to as an A rank file, a B rank file, a C rank file, and a D rank file, rather than those having better sound quality.
Next, a time block management table is also provided for each piece of music for which an audio file is stored in the streaming file storage unit 17. Each time block management table has a representative URL, which is a URL virtually given to the music, and an entry for each file from the A rank file to the D rank file representing the music. Each entry describes the identification of the first frame of the frames in the audio file that represents the sound in the time zone corresponding to the time block for each time block obtained by dividing the music into predetermined time intervals. The That is, for example, if the time block n corresponds to the time zone from m seconds to k seconds, and the frame j of the A rank file represents the voice in the time zone from m seconds to m + Δ of the music, the A rank file In the entry, the identification of the frame j is described for the time block n.

Next, a virtual URL is also assigned as a representative URL for the live stream to the encoder 14 of the content distribution system 1.
Hereinafter, the streaming distribution operation of such a streaming distribution system will be described.
First, the user causes the Web browser 42 of the user terminal 4 to access the URL of a Web page including a music selection menu, and displays the Web page provided from the Web server 11. Then, the web browser 42 accepts selection of music from the user on the displayed web page, and accesses a predetermined URL according to the description of the hyperlink of the displayed web page.

This access is accepted by the Web server 11, and the Web server 11 stores a metafile including a description of the representative URL of the selected music stored in the Web content storage unit 12 corresponding to the accessed URL. Return to browser 42.
The web browser 42 that has received the metafile activates the streaming player 43 and delivers the metafile.
The activated streaming player 43 performs the following streaming playback processing.
FIG. 3 shows the procedure of the streaming playback process.
As shown in the figure, in the streaming playback process, the streaming player 43 first sets rank A as the current rank (step 302). Then, the representative URL of the music described in the meta file delivered from the Web browser 42 is accessed (step 304), and the audio data streamed from the streaming server 13 is received as a response, and stored in the buffer. Go (step 306). In addition, the reception state monitoring unit 46 is caused to measure the error level of streaming delivery from the accessed representative URL (step 308). Here, it is assumed that streaming delivery from the streaming server 13 is always performed without congestion at a constant transmission rate, and the error level is an effective transmission band for the streaming player 43 of the audio data to be streamed, that is, The audio data reception rate that can be normally received is also expressed. The error level is measured based on, for example, the error occurrence rate of streaming data received by the streaming player 43, the frequency of issuance of streaming data retransmission requests, and the normal reception rate of streaming data. On the other hand, if the streaming delivery from the streaming server 13 is performed at a variable transmission rate, the error level is the effective transmission band necessary for streaming and reproducing the highest-quality audio data without interruption. The actual effective transmission band ratio is used.

  If the amount of audio data stored in the buffer exceeds the predetermined threshold value ThV (step 310), the process proceeds to step 312 and before the amount of audio data stored in the buffer exceeds the predetermined threshold value ThV. If the error level measured by the reception state monitoring unit 46 does not match the current rank (step 318), a request to switch the rank to the rank that matches the measured error level is issued to the streaming server 13. At the same time, the current rank is changed to a rank that matches the measured error level (step 320). Here, as the error level, an A level, a B level, a C level, and a D level are provided from the corresponding level having a large effective transmission band. Further, it is assumed that the A level matches the A rank, the B level matches the B rank, the C level matches the C rank, and the D level matches the D rank.

  In step 312, the audio data stored in the buffer starts to be reproduced according to the bit rate of the audio data. When all the music has been reproduced (step 316), the streaming reproduction process is terminated. Also, if the error level measured by the reception state monitoring unit 46 does not match the current rank before all the music has been played back (step 314), the rank is matched to the measured error level. Is issued to the streaming server 13 and the current rank is changed to a rank that matches the measured error level (step 322), and the bit rate of the audio data stored in the buffer is set to the bit rate of the audio data. Continue playing according to the request.

Next, an operation of the streaming server 13 that performs streaming delivery to the streaming player 43 will be described.
FIG. 4 shows the procedure of the streaming distribution process performed by the streaming server 13 when the representative URL accessed by the streaming player 43 is the representative URL of the music of the audio file stored in the streaming storage unit.
In this case, as shown in the figure, in the streaming distribution process, the streaming server 13 first reads the file management table corresponding to the accessed representative URL from the file database 18 and obtains the A rank file URL of the music corresponding to the representative URL. Obtain (step 402). Then, the acquired A rank file URL is set as the distribution target URL, the audio file (A rank file in this case) of the distribution target URL is read from the streaming file storage unit 17, and streaming distribution of the audio data of the audio file is started ( Step 404).

  Then, after receiving the rank switching request from the streaming player 43 (step 406), monitoring the occurrence of the end of the streaming distribution of the audio data of the audio file of the distribution target URL (step 408), and the streaming distribution is completed (Step 408), the streaming distribution process is terminated.

  On the other hand, when a rank switching request is received from the streaming player 43 (step 406), first, the time block management table is referred to, and the time block next to the time block corresponding to the current streaming delivery frame is switched. Calculated as a block (step 410). Then, referring to the file management table in which the audio file currently being streamed is registered, the URL of the audio file of the rank of the switching destination requested by the rank switching request is acquired as the next distribution target file URL (step 412) The frame position corresponding to the head of the switching time block of the audio file stored in the next distribution target file URL of the streaming file storage unit 17 is obtained with reference to the time block management table (step 414).

  Then, it waits for all the streaming distribution of the audio file frame of the current distribution target file URL included in the time block corresponding to the frame that is currently being distributed (step 416). The stream distribution of the audio file of the target file URL is terminated (step 418), the next distribution target file URL is set as the distribution target file URL, and the frame position of the audio data of the audio file of the distribution target file URL is extracted in step 414. Streaming distribution from the frame is started (step 420). Then, the process proceeds to step 408, and the process returns to receiving the rank switching request from the streaming player 43 and monitoring the end of the streaming distribution of the audio data of the audio file of the distribution target URL.

The streaming distribution process performed by the streaming server 13 when the representative URL accessed by the streaming player 43 is the representative URL of the music of the audio file stored in the streaming storage unit has been described above.
Next, a streaming distribution process performed by the streaming server 13 when the representative URL accessed by the streaming player 43 is the representative URL of the encoder 14 will be described.
In this case, the streaming server 13 starts streaming delivery of the stream having the best audio quality among the four streams output from the encoder 14. After that, when a rank switching request is received, the stream to be streamed is switched between the four streams output by the encoder 14 in accordance with the rank of the switching destination requested by the rank switching request. That is, if the switching destination rank is B rank, the stream having the second highest audio quality among the four streams output by the encoder 14 is the target of streaming delivery, and if the switching destination rank is C rank, the encoder 14 If the stream with the third highest audio quality among the four streams to be output is the target of streaming distribution and the rank of the switching destination is D rank, the stream with the fourth highest audio quality among the four streams output by the encoder 14 If the rank of the switching destination is A rank, the stream with the best audio quality among the four streams output by the encoder 14 is the target of streaming distribution.

The streaming delivery operation in the streaming delivery system according to this embodiment has been described above.
Here, FIG. 5a shows an operation example by such a streaming distribution operation.
As shown in the figure, in this operation example, first, the user of the user terminal 4 accesses the music from the Web page via the Web browser 42. Then, a metafile is sent from the web server as a response, and the Web browser 42 that receives the metafile activates the streaming player 43.

  The activated streaming player 43 accesses the representative URL described in the metafile. Then, the audio data of the A rank file, which is the audio data of the highest voice quality of the music selected by the user, is streamed from the streaming server 13. On the other hand, the streaming player 43 starts streaming reproduction of the audio data distributed in a streaming manner.

  After that, when the transmission quality of the streaming delivery between the streaming player 43 and the streaming server 13 deteriorates to such an extent that the streaming reproduction is interrupted, the streaming player 43 that detects this deteriorates the streaming server 13 to rank B. A rank switching request for switching is transmitted.

  Upon receiving the rank switching request, the streaming server 13 uses the next time block break of the audio data that is being streamed, the data to be streamed as the B rank file having a lower voice quality and therefore a lower bit rate. Switch to audio data.

  Thereafter, the streaming player 43 issues a rank switching request to a rank of an audio file with the highest voice quality that can be streamed and played back without interruption at the transmission quality at that time in accordance with the transmission quality of the streaming distribution. The voice quality and bit rate of the audio data streamed from the server 13 are switched according to the rank switching request.

  As a result, for example, as shown in FIG. 5b1, if a B-rank file has a reproduction time three times as long as the same data amount (a bit rate is 1/3) with respect to an A-rank file, As shown in FIG. 5b2, when the audio data of only the rank file is distributed by streaming, if the effective audio data streaming distribution is interrupted due to the influence of the transmission quality, as shown in FIG. Streaming playback is interrupted.

  On the other hand, according to the present embodiment, as shown in FIG. 5 b 3, at a time point 50 immediately after the transmission quality is deteriorated, the rank change request is issued from the streaming player 43 to the streaming server 13 and the streaming server 13 performs the streaming distribution. When the data is switched to the audio data of the B rank file, the streaming reproduction is not interrupted even when the streaming distribution of the audio data is interrupted as in FIG. 5b2.

The embodiment of the present invention has been described above.
As described above, according to the present embodiment, it is possible to suppress the interruption of streaming playback when the transmission quality deteriorates during streaming delivery.
In the present embodiment, a plurality of audio files having different audio qualities for the same music are prepared in the streaming file storage unit 17 in advance, but this stores only a single audio file, and from this audio file, streaming distribution and In parallel, audio data of voice quality corresponding to the rank requested by the rank switching request may be generated in real time. Note that audio data and time block management tables with different audio qualities for the same music piece may be prepared as one file.

  Further, in the present embodiment, a case has been described in which one audio data stream is delivered from the streaming server 13 to the streaming player 43 on a one-to-one basis. However, in the present embodiment, audio data is not specified from the streaming server 13. The present invention can also be applied to a case where a plurality of streaming players 43 are distributed in a broadcast format.

  In this case, the streaming server 13 performs streaming distribution of the audio data to a predetermined broadcast address, and each streaming player 43 receives the audio data distributed to the broadcast address and performs streaming reproduction. Each streaming player 43 independently measures the error level of the streaming distribution received by itself and issues a rank switching request to the streaming server 13 together with the identifier of the stream being received as described above.

  The streaming server 13 receives a rank switching request from each streaming player 43, and switches the voice quality / bit rate of the audio data to be streamed in the broadcast format according to a predetermined switching algorithm. Here, as this switching algorithm, an algorithm for switching audio data to be streamed to audio data of voice quality corresponding to the lowest rank among the ranks requested by the received rank switching request, or a predetermined period Each time, the audio data to be stream-distributed is switched to the audio data of the voice quality corresponding to the rank that has issued the rank switching request to that rank among the ranks requested by the received rank switching request. Among the ranks requested by the algorithm and the rank switching request received for each predetermined period, the audio quality of the voice corresponding to the rank in which the number of streaming players that issued a rank switching request that requests a rank lower than that is less than the predetermined number Audio data Etc. can be used an algorithm for switching the audio data to stream.

  As described above, according to the present embodiment, since the transmission quality is measured on the streaming player 43 side, the streaming server 13 is requested to switch the distribution audio data to the audio quality corresponding to the measured transmission quality. Even in a broadcast format performed without connection, streaming distribution can be performed so that interruption of streaming reproduction in the streaming player 43 can be suppressed.

  By the way, the above embodiment has been described by taking the case of streaming delivery of audio data as an example. However, this embodiment can be similarly applied to the case of streaming delivery of other media data such as video data. it can.

It is a block diagram which shows the structure of the streaming delivery system which concerns on embodiment of this invention. It is a figure which shows the table stored in a file database in embodiment of this invention. It is a flowchart which shows the streaming reproduction | regeneration processing which concerns on embodiment of this invention. It is a flowchart which shows the streaming delivery process which concerns on embodiment of this invention. It is a figure which shows the operation example of the streaming delivery operation | movement which concerns on embodiment of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Content delivery system, 2 ... WAN, 3 ... Wireless base station, 4 ... User terminal, 11 ... Web server, 12 ... Web content storage part, 13 ... Streaming server, 14 ... Encoder, 15 ... Voice input device, 16 ... Stream monitoring unit, 17 ... streaming file storage unit, 18 ... file database, 41 ... wireless communication device, 42 ... web browser, 43 ... streaming player, 44 ... audio output device, 45 ... speaker, 46 ... reception state monitoring unit.

Claims (4)

A streaming distribution system including a streaming server that distributes streaming data representing content and a user terminal that includes a streaming player that receives and distributes streaming data that has been distributed.
The user terminal has a normal reception rate calculation means for calculating, as a normal reception rate, a rate at which streaming data is normally received by the streaming player, and a normal reception rate and a bit rate of streaming data currently received by the streaming player. A bit rate change requesting unit for requesting the streaming server to change the bit rate of the streaming data to the bit rate according to the normal reception rate when they do not match,
In response to a request for changing the bit rate from the user terminal, the streaming server includes streaming quality changing means for changing the streaming data to be distributed to streaming data having a content quality and a bit rate different from those represented by the streaming data. A streaming distribution method comprising: The streaming distribution system according to claim 1,
The normal distribution rate calculating means calculates the normal reception rate based on a reception error rate of the streaming data. The streaming distribution system according to claim 1 or 2,
The streaming distribution system, wherein the streaming data represents content that is audio or video. In a streaming distribution system including a streaming server for streaming distribution of streaming data representing content, and a user terminal including a streaming player for receiving and streaming streaming data that has been streamed, the streaming server to the streaming player A streaming delivery method for delivering streaming data,
Delivering the streaming data from the streaming server to the streaming player;
In the user terminal, calculating a rate at which streaming data is normally received by the streaming player as a normal reception rate;
In the user terminal, when the normal reception rate and the bit rate of the streaming data currently received by the streaming player do not match, the streaming data to the streaming server to the bit rate according to the normal reception rate Requesting a change in the bit rate of
In the streaming server, in response to a request for changing the bit rate from the user terminal, the streaming data to be streamed is changed to streaming data having different quality and bit rate of the content represented by the streaming data. A streaming delivery method characterized by the above.

Images