JP3461278B2 - Distributed multimedia server device, distributed multimedia server information access method, and recording medium storing program for implementing the method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a distributed multimedia system for delivering multimedia information to each terminal or storing multimedia information from a multimedia information input device to a multimedia server in response to requests from a large number of terminals. The present invention relates to a media server device, a distributed multimedia server information access method, and a recording medium recording a program that implements this method.

[0002]

2. Description of the Related Art Conventionally, a service for delivering multimedia information to each terminal has been realized by a single multimedia server device.

A block configuration of a conventional single multimedia server device is shown in FIG. The communication control unit 911 communicates with the terminal, the central control unit 912 controls the entire multimedia server device, the storage unit 913 temporarily stores multimedia information and the like at the time of delivery to the terminal, and the storage unit 91.
5 stores multimedia information, and the system bus 914
Is a communication control unit 911, a central control unit 912, a storage unit 91.
3, data transfer between the storage units 915 is performed.

In the case of the single multimedia server device as shown in FIG. 13, the maximum number of simultaneously connected terminals is limited due to the transfer neck of the system bus 914 and the input / output speed neck of the storage unit 915. Therefore, it has been considered to increase the maximum number of simultaneously connected terminals by a distributed multimedia server device in which a plurality of server modules are connected via a network.

FIG. 14 is a block diagram showing a configuration of a system using a conventional distributed multimedia server device. The terminals 211 to 21L make a multimedia information read request to the distributed multimedia server device 23 via the terminal side network 22 and reproduce the received multimedia information. The terminal side network 22 is the terminal 2
It is a network that connects 11 to 21L and the distributed multimedia server device 23.

The distributed multimedia server device 23 is a server module 2311 to 231M for delivering multimedia information to a terminal, and a control module 232 for accepting a request from the terminal and for delivering a multimedia information to the server module. Composed of.

[0007] One piece of multimedia information is divided into fixed-length multimedia blocks (segments) and distributed and accumulated in a plurality of server modules 2311 to 231M. The configuration of each server module 2311 to 231M is similar to that shown in FIG. 13, and each server module can operate as a single multimedia server device. Delivery of multimedia information using this distributed multimedia server device is performed as follows.

(1) A multimedia information read request including a program identifier to be read is transmitted from the terminal 21i to the control module 232 via the terminal side network 22.

(2) A multimedia information delivery request is transmitted from the control module 232 to all the server modules 2311 to 231M via the terminal side network 22.

(3) Server modules 2311 to 231
M synchronizes with other server modules so that the terminal does not receive multimedia information from a plurality of server modules at the same time, and stores the segments of the multimedia information distributed and accumulated in each server module on the terminal side network 22. It delivers to the terminal 21i via.

(4) Similarly, multimedia information is simultaneously delivered to a plurality of terminals. In other words, a certain server module may have different delivery destination terminals for each segment.

[0012]

However, the conventional distributed multimedia server device has the following problems. (1) It is necessary to synchronize with other server modules so that the terminal does not receive multimedia information from multiple server modules at the same time.

(2) The server module delivers multimedia information to different terminals in order. When the terminal side network 22 is connectionless, the multimedia information is delivered to the terminals as scheduled due to a collision in the network. However, the playback may be interrupted on the terminal. On the other hand, when the terminal-side network 22 is connection-type, one server module must hold connections with all terminals or disconnect and connect repeatedly with terminals at a short interval called multimedia block delivery time. There is. In the former case, it is necessary to keep the connection even when multimedia information is not delivered. In the latter case, the disconnection and connection processing are overheads, and the effective connection time for multimedia information delivery is possible. Is short, and in either case, the usage efficiency of the terminal side network 22 is low.

(3) In addition to the server modules 2311 to 231M for delivering multimedia information, a control module 232 for centrally controlling the entire distributed multimedia server device 23 is required.

(4) Terminal side network 22, or terminals 211 to 21L and distributed multimedia server device 23
When the communication protocol between them is changed, the influence affects all the server modules 2311 to 231M.

An object of the present invention is to provide a distributed multimedia server device which does not require synchronization with other server modules and has a high utilization efficiency of the terminal side network 22. Furthermore, a distributed multimedia server information access method that can flexibly cope with a case where the number of connected terminals increases or a storage server module in the distributed multimedia server device or a storage device is added and has little performance degradation is provided. To provide.

[0017]

SUMMARY OF THE INVENTION The present invention is a multimedia server device for delivering multimedia information having continuity such as video information and audio information requested from a plurality of terminals to each terminal. And a communication server module that communicates with the terminal, a storage server module that stores multimedia information, and an inter-server module network that enables communication between any communication server module and the storage server module. Characterize.

Further, according to the present invention, each storage server module accesses the segment of its own storage server module independently of the process of accessing the segment in another storage server module, and the communication server module It is characterized by managing the segment delivery timing to the terminal and making a read request specifying the segment to be read to the storage server module.

According to the present invention, the communication server module holds the connection with the target terminal for delivering multimedia information, and the plurality of multimedia blocks transferred from the plurality of storage server modules via the inter-server module network ( (Segments) are delivered in sequence so that playback interruptions do not occur at the terminal, so synchronization with other server modules is not required and the terminal side network is used efficiently.

A program for causing the computer of the communication server module and the storage server module to execute the above processing is a computer-readable portable medium memory,
It can be stored in an appropriate recording medium such as a semiconductor memory or a hard disk.

[0021]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention. First, a device outline of the distributed multimedia server device according to the present embodiment will be described with reference to FIG.

In FIG. 1, reference numeral 3 denotes a distributed multimedia server device according to the present invention, which is a communication server module 311 for communicating with a terminal and terminating a terminal interface.
˜31M, storage server modules 321 to 32N that store multimedia information and read it out in response to a request, and a server module network 33 that communicates between communication server modules and storage server modules. 1
Reference numerals 1 to 1L denote ends, and 2 denotes a terminal side network. Reference numeral 4 denotes a multimedia information input device which makes a write request in order to store multimedia information for delivery in the distributed multimedia server device 3.

FIG. 2 is a block diagram showing the configuration of the communication server module, and FIG. 3 is a block diagram showing the configuration of the storage server module. Figure 1
Each of the communication server modules 311 to 31M shown in 1 includes a communication control unit 51, a central control unit 52, a storage unit 53, a system bus 54, and a server module communication control unit 55. The storage server modules 321 to 32N each include a storage unit 61, a central control unit 62, a storage unit 63, a system bus 64, and a server module communication control unit 65. The central control unit 52 executes the program stored in the storage unit 53 for implementing the present invention. The central control unit 62 also executes a program stored in the storage unit 63 for implementing the present invention.

13 differs from the block configuration of the server module in the single multimedia server device shown in FIG. 13 and the conventional distributed multimedia server device shown in FIG. 14 in the case of the communication server module shown in FIG.
That is, the storage unit 915 shown in FIG. 2 does not exist, and instead there is the inter-server-module communication control unit 55 that controls communication with another server module. In the case of the storage server module shown in FIG. 3, the communication control unit 911 shown in FIG.
That is, there is no server module communication controller 65 instead.

The inter-server module network 33 is
It suffices if high-speed transfer of information can be performed between arbitrary server modules, and various realization methods such as an ATM switch and a high-speed LAN can be considered. For concrete implementation method,
Since a known technique can be used, detailed description thereof will be omitted here.

In this system, when the number of connected terminals or the load on the distributed multimedia server device increases,
It is possible to deal flexibly by adding a communication server module, a storage server module, or both. For example, by displaying the load status of the system, the administrator can be prompted to add communication server modules or storage server modules, or the number of communication server modules and storage server modules can be automatically determined according to the load status. It can be changed.

The multimedia information of one program is divided into fixed-length segments, and a plurality of storage server modules 3
Dispersed and accumulated in 21 to 32N. The operation of the system configured as above will be described.

(1) A connection request is made from the terminal 1i (i = 1 to L) to the arbitrary communication server module 31j (j = 1 to M) via the terminal side network 2. (2) When the communication server module 31j has a sufficient processing capacity and can perform new processing from the terminal 1i, the communication server module 31j returns a connection response to the terminal 1i, thereby communicating with the terminal 1i. A connection is set up with the server module 31j, and this connection is used for subsequent multimedia information delivery and the like. If the processing capacity is not sufficient, a connection refusal response including the communication server module identifier having the processing capacity is returned to the terminal 1i. The terminal 1i, which has received the connection refusal response, makes a connection request to another communication server module 31j 'corresponding to the communication server module identifier included in the connection refusal response and having a sufficient processing capacity.

(3) The terminal 1i issues a multimedia information read request including a program identifier to the communication server module 31j. (4) The communication server module 31j, which has received the multimedia information read request, stores the storage server module 32k having the head segment of the program designated by the terminal 1i.
A segment read request is issued to (k = 1 to N).

(5) The storage server module 32k receiving the segment read request reads the segments stored in the storage unit 61, and the communication server module 31j.
Transfer to. At this time, it is not necessary to synchronize with other storage server modules.

(6) The communication server module 31j having received the segment makes a segment read request to the storage server module having the next segment. Similarly,
Repeat reading of segments from the multiple storage server module.

(7) On the other hand, the communication server module 31j periodically delivers the segment to the terminal 1i with the segment reproduction time as one cycle. At this time, the communication server module 31j does not need to synchronize with other communication server modules.

(8) When the communication server module 31j issues a disconnection request from the terminal 1i, the communication server module 31j returns a disconnection response to the terminal 1i, whereby the communication between the terminal 1i and the communication server module 31j. Is disconnected.

Next, an example of a method of accessing multimedia information in the distributed multimedia server device 3 will be described in more detail. FIG. 4 shows a read processing sequence of the distributed multimedia server information access method according to the present embodiment, and the read processing is performed as follows.

(1) The communication server module 31j receives a program read request from the terminal 1i. (2) The communication server module 31j makes a read request to the storage server module 32k that stores the first segment of the requested program.

(3) In the storage server module 32k,
Without communicating with another storage server module, the segment stored in the self storage server module is read out and transferred to the communication server module 31j. The communication server module 31j transfers the segment transferred from the storage server module 32k. , Deliver to the requesting terminal 1i.

(4) The communication server module 31j, which has received the plurality of consecutive segments accumulated in the accumulation server module 32k, makes a read request to the accumulation server module 32k + 1 in which the following segments are accumulated.

(5) In the storage server module 32k + 1, similarly to the reading process in the storage server module 32k in (3), the storage server module 32k + 1 stores the data in the storage server module itself without communicating with other storage server modules. Reading the existing segment, and communication server module 31
Then, the communication server module 31j delivers the segment transferred from the storage server module 32k + 1 to the terminal 1i.

After (6), similarly, the storage server module that has received the read request from the communication server module 31j reads the segment without communicating with other storage server modules, and the communication server module 31
Repeat delivery to terminal 1i via j.

FIG. 5 is a flow chart showing the processing of the communication server module in this embodiment. The processing of the communication server module will be described according to S1 to S16 shown in FIG.

(S1) Receive a read request from the terminal. (S2) Set the initial delivery time to the terminal. For example, if the initial delivery time is set to the time when the read request from the terminal is received, the segment is delivered to the terminal when the segment is received from the storage server module.

(S3) The "segment delivery process to the terminal" described later is activated. (S4) The segment ID to be read next is calculated, and the storage server module in which the segment is stored is calculated.

(S5) The reception buffer for storing the segment transferred from the storage server module is secured. If the buffer cannot be allocated, wait until it can. The size of one reception buffer is equal to the size of one segment, and a plurality of reception buffers can be used for each terminal.

(S6) A read request is issued to the storage server module calculated in step (S4). (S7) The segment corresponding to the read request is received from the storage server module and stored in the reception buffer.

(S8) If it is not the final segment, (S8)
Returning to step 4), the segment ID to be read next, the storage server module that makes the read request are calculated, and then,
The processes of 4) to (S7) are repeated.

The "segment delivery process to the terminal" is performed as follows. (S11) Wait until the current time set “delivery time to terminal” has passed.

(S12) Wait until a segment is stored in the receive buffer. If there is a segment in which the segment is stored even in one plane among the reception buffers of multiple planes, (S1
Proceed to 3).

(S13) The segment stored in the reception buffer is delivered to the terminal. (S14) The reception buffer is released. (S15) “Delivery time to terminal” currently set
In addition to the one segment playback time on the terminal,
Set as the next delivery time.

(S16) If it is not the final segment,
The processes of (S11) to (S15) are repeated. Next, a processing sequence for an example of reading a segment of multimedia information using an unused time slot by the time slot processing will be described with reference to FIG. In the access method according to the present embodiment, each storage server module 3
21 to 32N manage the time slots of only the self-storage server module, and perform the read processing as follows according to the processing sequence shown in FIG.

(1) The communication server module 31j receives a read request for a certain program from the terminal 1i. (2) The communication server module 31j makes a read request to the storage server module 32k that stores the first segment of the requested program.

(3) In the storage server module 32k,
An unused time slot is selected, the segment is read out and transferred to the communication server module 31j without notifying other storage server modules of the selected time slot, and the communication server module 31j is transferred from the storage server module 32k. Connected segment to terminal 1i
To ship to.

(4) The communication server module 31j, which has received a plurality of consecutive segments stored in the storage server module 32k, makes a read request to the storage server module 32k + 1 in which subsequent segments are stored.

(5) In the storage server module 32k + 1, an unused time slot is selected, the segment is read out without notifying the other storage server module of the selected time slot, and the communication server module 31
Then, the communication server module 31j delivers the segment transferred from the storage server module 32k + 1 to the terminal 1i.

Similarly, after (6), the storage server module that receives the read request from the communication server module selects an unused time slot each time and notifies the other storage server module of the selected time slot. Instead, it reads the segment and repeats delivery to the terminal via the communication server module.

FIG. 7 is a timing chart of the time slot processing in the read processing sequence shown in FIG. 6, and FIG. 8 shows the configuration of the storage server module in the example shown in FIG.

As shown in FIG. 8, two storage server modules (# 1, #
2) 321, 322, and each storage server module 3
In the storage units 611 and 612 of 21, 322, respectively, 3
Storage devices 6111 to 6113, 6121 to 6123
There is. The multimedia information of one program is divided into fixed-length segments, and each storage server module 321 or 322 has three storage devices 61.
It is cyclically accumulated in 11 to 6113 and 6121 to 6123.

In the storage server module (# 1) 321, one of TS101, TS102, ..., TS112 is set.
Three time slot sequences each consisting of two time slots at the same intervals are periodically generated for each of the storage devices 6111 to 6113. Also, storage server module (# 2)
322, TS201, TS202, ..., TS2
Three time slot sequences consisting of twelve 12 time slots at the same intervals are periodically generated for each of the storage devices 6121 to 6123. Here, the time slot TS101 of the storage server module (# 1) 321 is ...
.., TS112 and storage server module (# 2) 322
, And TS212, which are independent of the time slots TS201, ...

Storage server module #j (j = 1, 2)
At time Cyclej11, Cyclej12, Cyclej13, Cyclej
21 ... indicates the read cycle (small cycle) of the four time slots that make up the time slot sequence, and the time Cyclej1.
Represents the read cycle (large cycle) of the 12 time slots that make up the time slot series, and one large cycle consists of three small cycles, and each time slot series is out of phase by one small cycle. There is. Here, the short cycle Cycles 111, 112, ... Of the storage server module (# 1) 321.
And the short cycle Cycle2 of the storage server module (# 2) 322
It is independent of 11,212, ....

On the other hand, each segment is cyclically stored in the storage device in the storage server module.
Storage device 611 of storage server module (# 1) 321
2, storage device 6113, storage device 6111, storage device 6122 of storage server module (# 2) 322,
It is assumed that the storage device 6123 and the storage device 6121 are stored in this order.

The processing in the storage server module in this access method is performed as follows, as shown in the flowchart of FIG. If there is a read request for a program from the terminal and the leading segment of the program is stored in the storage device 6112 of the storage server module (# 1) 321, the storage server module (# 1) 321
Searches for unused time slots for which read processing and write processing have not been performed in the order of TS109, TS110, ... For time slots for the storage device 6112 (S21 in FIG. 9).

For example, if TS109 is an unused time slot, in the short cycle Cycle111, the segment stored in the storage device 6112 at the timing of the time slot TS109 is read (S22) and transferred to the communication server module (S23). ). Next cycle Cycl
At e112, the segment stored in the storage device 6113 at the timing of the same time slot TS109 is read, and in the next short cycle Cycle113, the segment stored in the storage device 6111 is read at the timing of the same time slot TS109, and the communication server Transfer to module. Since the next segment is not stored in the storage server module (# 1) 321, the reading process in the storage server module (# 1) 321 ends (S24).

Similarly, the storage server module (# 2) 322 which has received the read request from the communication server module
Searches for a new unused time slot. For example,
If the time slot TS210 is an unused time slot, the storage device 612 is used in the short cycle Cycle221.
The segment stored in 2 is read and transferred to the communication server module. Next, the segments stored in the storage device 6123 in Cycle 222 and the storage device 6121 in Cycle 223 are read and transferred to the communication server.

Thereafter, the storage server module (# 1) 32
Return to 1 and search for a new unused time slot,
The same reading process is repeated. FIG. 10 shows a write sequence for accumulating multimedia information in the embodiment of the present invention. In this embodiment, the write processing is performed as follows.

(1) The multimedia information input device 4 is
When storing the multimedia information of the program in the distributed multimedia server device 3, a write request is issued via the terminal side network 2. Communication server module 31
j receives the multimedia information write request from the multimedia information input device 4.

(2) The communication server module 31j determines the storage server module 32k to write the beginning segment of the requested program and makes a write request to the storage server module 32k.

(3) The communication server module 31j divides the multimedia information transferred from the multimedia information input device 4 into fixed-length segments and transfers them to the storage server module 32k.

(4) The storage server module 32k writes the segment without communicating with other storage server modules. Similarly after (5), the communication server module 31j
The storage server module for writing the segment is cyclically determined like the storage server modules 32k + 1 and 32k + 2, and the multimedia information transferred from the multimedia information input device 4 is divided into fixed-length segments and determined. The transfer to the stored server module is repeated.

Next, a processing sequence for an example of writing a segment of multimedia information by using an unused time slot by the time slot processing will be described with reference to FIG. In this embodiment, each storage server module 321 to 32N manages the time slot of only its own storage server module, and performs the write processing as follows according to the processing sequence shown in FIG.

(1) The communication server module 31j receives a program write request from the multimedia information input device 4. (2) The communication server module 31j determines the storage server module 32k in which the beginning segment of the requested program is written, and issues a write request.

(3) In the storage server module 32k,
Select an unused timeslot to use for writing the segment. (4) The communication server module 31j divides the multimedia information transferred from the multimedia information input device 4 into fixed-length segments and transfers them to the storage server module 32k.

(5) The storage server module 32k writes the segment according to the selected time slot. (6) After that, the communication server module 31j similarly
The storage server module for writing the segment is cyclically determined like the storage server modules 32k + 1 and 32k + 2, and the multimedia information transferred from the multimedia information input device 4 is divided into fixed-length segments and determined. The transfer to the stored server module is repeated.

The timing chart of the time slot process used in this embodiment is the same as that of FIG. 7, and each segment is cyclically stored in the storage device in the storage server module. For example, the storage server module (# 1) 32
1 storage device 6112, storage device 6113, storage device 6
111, and then the storage device 6122, storage device 6123, and storage device 612 of the storage server module (# 2) 322.
Accumulate in the order of 1.

The processing in the storage server module in this access method is performed as follows, as shown in the flowchart of FIG. When there is a request to write a certain program from the terminal and the first segment of the program is stored in the storage device 6112 of the storage server module (# 1) 321, the storage server module (# 1) 321
Time slot for storage device 6112 TS
In the order of 109, TS110, ..., Unused time slots for which read processing and write processing have not been performed are searched (S31 in FIG. 12).

For example, if TS109 is an unused time slot, a segment is written in the storage device 6112 at the timing of the time slot TS109 in the small cycle Cycle111, and the storage device is written at the timing of the same time slot TS109 in the next cycle Cycle112. 6
The segment is written in 113 and the segment is written in the storage device 6111 at the same timing of the time slot TS109 in the next short cycle Cycle 113 (S32). Since there is no segment to be written next, the writing process in the storage server module (# 1) 321 ends (S3).
3).

Since the next segment is stored in the storage device 6122 of the storage server module (# 2) 322, the storage server module (# 2) 322 which has received the write request from the communication server module creates a new unused time slot. To explore. For example, time slot TS21
If 0 is an unused time slot, the short cycle Cycl
At e221, the segment is written to the storage device 6122, then at Cycle222, the storage device 6123, Cycle2
At 23, the segment is written to the storage device 6121.

Thereafter, the storage server module (# 1) 32
Return to 1 and search for a new unused time slot,
The same writing process is repeated.

[0077]

As is clear from the above description, the distributed multimedia server device of the present invention has the following advantages.

(1) The storage server module has only to transfer the segment of the multimedia information according to the read request from the communication server module, and does not need to synchronize with other storage server modules. Also, the communication server module may transfer segments to the terminal at regular intervals without synchronizing with other communication server modules.

(2) In response to a connection request from a terminal, the communication server module always holds the connection with all terminals because the segment is delivered using the connection set with that terminal. No need, and
There is no need to repeat disconnection and connection with multiple terminals at short intervals.

(3) Since there is no control module for controlling the whole in the distributed multimedia server device,
The processing performance of the distributed multimedia server device is not limited by the processing neck of the control module.

(4) When the communication protocol between the terminal side network or the terminal and the distributed multimedia server apparatus is changed, the effect is limited to the communication server module and it is necessary to change the entire distributed multimedia server apparatus. Absent.

(5) A communication server module having a low processing capacity can distribute a load among a plurality of communication server modules by guiding a connection request to another communication server module when a connection request is made from a terminal. Therefore, the processing capacity of the entire distributed multimedia server device is not limited by the processing neck of a specific communication server module.

(6) Since the multimedia information of one program is divided into a plurality of fixed-length segments and each segment is distributed and stored in a plurality of storage server modules, the read requests to the storage server modules are almost equal. Yes, due to the processing neck of a particular storage server module,
The processing capacity of the entire distributed multimedia server device is not limited.

(7) Since it is composed of a plurality of server modules, multimedia information can be simultaneously delivered from a single multimedia server device to a large number of terminals. (8) When the number of connected terminals or the load on the distributed multimedia server device increases, it is possible to deal flexibly by adding a communication server module, a storage server module, or both.

In particular, the access method of the present invention has the following advantages. (1) It is not necessary to notify all storage server modules of the synchronization information.

According to the second aspect, if the terminal issues a special reproduction request such as a read request for another program or a jump request to another reproduction position in the same program before the end of reading of a certain program, all There is no need to notify the storage server module of an access suspension request or new synchronization information based on the previously notified synchronization information. In addition, the communication server module that has received the trick play request from the terminal stops the delivery of the previous program to the terminal, and subsequently delivers the new program segment transferred from the storage server module. Appears to have a short response time to trick play.

According to the third and fifth aspects, each storage server module manages the time slot of only its own server module. Therefore, when an unused time slot is selected, the selected time slot is notified to all the storage server modules. You don't have to. Further, in claim 3, when a special playback request such as a read request for another program or a jump request to another playback position in the same program is issued from the terminal before the end of the certain program is read, at that time point. It is only necessary to release the time slot and select another unused time slot in the storage server module that is performing the read processing in the above, and it is not necessary to notify other storage server modules of the time slot release or the newly selected time slot. is there.

(2) Since the same synchronization information is not managed by different storage server modules, there is no difference between the synchronization information. In Claims 3 and 5, since different storage server modules perform different time slot management, the same time slot is not selected.

(3) When a storage server module or a storage device which is a component of the storage server module is added, it is not necessary to change the synchronization information managed by all the storage server modules.

In the third and fifth aspects, when a storage server module or a storage device which is a component of the storage server module is added, only the time slot management information managed by the storage server module concerned needs to be changed. .

(4) Since there is no inconsistency in the synchronization information managed by each storage server module, it is not necessary to regularly perform a synchronization information consistency check between storage server modules.

In the third and fifth aspects, different storage server modules perform different time slot management, so that no mismatch of time slot management information occurs. (5) Time synchronization is not required in all storage server modules.

In claims 3 and 5, the phase difference of the time slots between adjacent storage devices in the same storage server module needs to be one small cycle, but between adjacent storage devices in different storage server modules. Since it is not necessary to keep the phase difference of the time slots of 1 constant, time synchronization between different storage server modules is not required.

(6) In claim 3, the maximum response time for a new read request is constant regardless of the number of storage server modules. For example, in FIG. 7, when a new read request is made, even if the number of storage server modules is doubled, one of 12 time slots in three small cycles is selected and the maximum response time is 3 small. It is a cycle.

(7) In the read processing, the communication server module makes a read request to the storage server module after securing the buffer for receiving the segment, so that there is no failure in segment transfer due to the buffer shortage of the communication server module. ， There is no interruption of playing multimedia information on the terminal.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a communication server module.

FIG. 3 is a block diagram showing a configuration of a storage server module.

FIG. 4 is a diagram showing a read processing sequence according to the embodiment of the present invention.

FIG. 5 is a flowchart showing processing of the communication server module according to the embodiment of the present invention.

FIG. 6 is a diagram showing a read processing sequence according to another embodiment of the present invention.

FIG. 7 is a timing chart of time slot processing in the embodiment shown in FIG.

FIG. 8 is a block diagram showing a configuration of a storage server module.

FIG. 9 is a flowchart of a read process of the storage server module according to the embodiment of the present invention.

FIG. 10 is a diagram showing a write processing sequence according to the embodiment of the present invention.

FIG. 11 is a diagram showing a write processing sequence according to another embodiment of the present invention.

FIG. 12 is a flowchart of a writing process of the storage server module according to the embodiment of the present invention.

FIG. 13 is a block diagram showing a configuration of a conventional single multimedia server device.

FIG. 14 is a block diagram showing a configuration of a system using a conventional distributed multimedia server device.

[Explanation of symbols]

11-1L terminal 2 Terminal side network 3 Distributed multimedia server device 311 to 31M communication server module 321 to 32N storage server module 33 Network between server modules 4 Multimedia information input device 51 communication control unit 52 Central control unit 53 storage 54 system bus 55 Communication control unit between server modules 61 Accumulator 62 Central control unit 63 storage 64 system bus 65 Server module communication controller

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kazutoshi Nishimura 3-19-2 Nishishinjuku, Shinjuku-ku, Tokyo Nihon Telegraph and Telephone Corporation (56) Reference JP-A-6-209460 (JP, A) JP-A-8-190533 (JP, A) JP-A-8-280002 (JP, A) JP-A-7-107425 (JP, A) IEICE Technical Report SSE 96-132 IEICE Transactions D-II, Vol. J-78-D-II, No. 1, pp. 76-85 IPSJ 55th National Conference, 3R-07 (58) Fields investigated (Int.Cl. ⁷ , DB name) H04L 12/56 G06F 13/00 H04N 7/08 H04N 7/081 H04N 7/173 G06F 15/16

Claims (9)

(57) [Claims] 1. A multimedia server device for delivering multimedia information requested by a terminal to a requesting terminal, the multimedia information of one program to be delivered to the terminal.
Divided segment, each module in segment unit
A module that cyclically distributes and stores the data to and from a segment read request, and that reads and transfers the requested segments, and that connects between multiple storage server modules that operate independently and terminals. Is set, a multimedia information read request from a terminal is received using this connection, a segment read request is issued to the storage server module, and a segment received from the storage server module is requested for multimedia information. Repeat the process of delivering to the terminal
And a plurality of communication server modules that operate independently of each other, and an inter-server-module network that enables communication between the arbitrary communication server module and the arbitrary storage server module. Distributed multimedia server device. 2. A module for storing multimedia information having continuity such as video information and audio information,
A plurality of storage server modules that operate independently, a module that delivers multimedia information requested by a terminal to each terminal, and a plurality of communication server modules that operate independently of each other A method of accessing multimedia information in a distributed multimedia server device configured by a network between server modules that enables communication between a communication server module and a storage server module, which is one program to be delivered to a terminal Segments of the multimedia information are cyclically stored in a plurality of storage server modules, and when the multimedia information is delivered to the terminal, the program is sequentially reproduced from the communication server module at the timing at which the program reproduction at the terminal is not interrupted. Read segment to storage server module Makes a request, storage server between modules read a segment without synchronized, repeat from the communication module to the end of the segment the process of delivering to the terminal
Distributed multimedia server information access method, characterized in that to. 3. The distributed multimedia server information access method according to claim 2, wherein a plurality of storage devices included in each storage server module have:
The segments of the multimedia information are stored in segment units, and each storage server module has a time slot sequence that is independent of other storage server modules and has a required number of time slots of the same interval for each storage device. A distributed multimedia server information access method, wherein the distributed multimedia server information is generated by displacing, and in response to a segment read request from the communication server module, an unused time slot is selected from a time slot sequence and the segment is read. 4. A module for accumulating multimedia information having continuity such as video information and audio information,
A plurality of storage server modules that operate independently, a module that delivers multimedia information requested by a terminal to each terminal, and a plurality of communication server modules that operate independently of each other A method for accessing multimedia information in a distributed multimedia server device configured by a network between server modules that enables communication between a communication server module and a storage server module, wherein the communication server module is multimedia information. Receives multimedia information write request from input device and stores it for delivery.
Dividing the set of multimedia information into a plurality of segments, cyclically performs segment write requests for a plurality of the storage server module, the process of performing a segment writing without taking synchronization between the storage server module
A distributed multimedia server information access method characterized by repeating until the end of a segment . 5. The distributed multimedia server information access method according to claim 4, wherein each storage server module has a plurality of storage devices, and each storage server module is independent of other storage server modules and has the same interval. , A time slot sequence having the required number of time slots is generated with a phase shift for each storage device, and an unused time slot is selected from the time slot sequence in response to a segment write request from the communication server module, A distributed multimedia server information access method characterized by writing. 6. A module for storing multimedia information having continuity such as video information and audio information,
A plurality of storage server modules that operate independently, a module that delivers multimedia information requested by a terminal to each terminal, and a plurality of communication server modules that operate independently of each other A recording medium in which a program used in a distributed multimedia server device configured by a network between server modules that enables communication between a communication server module and a storage server module, wherein the communication server module is a terminal when distributing multimedia information, the segments obtained by dividing a <br/> multimedia information 1 program to be shipping to the terminal with respect to the storage server module for cyclically storing, uninterrupted program playback in the terminal Storage server sequentially makes segment read requests at timings Reads the segment without taking synchronization between joules, Se to be delivered to the terminal
A recording medium storing a program for realizing a distributed multimedia server information access method, characterized by recording a program for causing a computer to execute a process of repeating until the end of a segment . 7. A recording medium having a program for realizing the distributed multimedia server information access method according to claim 6, wherein each storage server module is independent of other storage server modules in the recorded program. , A time slot sequence having a required number of time slots of the same interval is generated by shifting the phase for each of a plurality of storage devices for storing the segments of the multimedia information that the self storage server module has, and the segments from the communication server module are generated. A distributed multimedia server information access method including a program for causing a computer to execute processing of selecting an unused time slot from a time slot sequence and reading a segment in response to a read request is realized. A recording medium recording a program. 8. A module for storing multimedia information having continuity such as video information and audio information,
A plurality of storage server modules that operate independently, a module that delivers multimedia information requested by a terminal to each terminal, and a plurality of communication server modules that operate independently of each other A recording medium for recording a program used in a distributed multimedia server device configured by a network between server modules that enables communication between a communication server module and a storage server module, wherein the communication server module is a multimedia Receiving a multimedia information writing request from the information input device, dividing the multimedia information of one program to be delivered to the terminal into a plurality of segments, and cyclically writing the segments to the plurality of storage server modules. Between each storage server module making a request To write the segment without synchronizing with the end of the segment
A recording medium recording a program for realizing a distributed multimedia server information access method, characterized by recording a program for causing a computer to execute repetitive processing. 9. A recording medium having a program for realizing the distributed multimedia server information access method according to claim 8, wherein each storage server module is independent from other storage server modules in the recorded program. , A time slot sequence having a required number of time slots of the same interval is generated by shifting the phase for each of a plurality of storage devices for storing the segments of the multimedia information that the self storage server module has, and the segments from the communication server module are generated. To realize a distributed multimedia server information access method characterized by including a program for causing a computer to select an unused time slot from a time slot sequence in response to a write request and perform a segment write process. A recording medium recording a program.