JPH10116239A - Data transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve data transmission capability between client and server in a client server type data transmission system. SOLUTION: Between clients 112 to 114 and the originating server 101, repeating servers which relay to more than one client are connected in one state (repeating server 201) or stages (repeating servers 202 and 203). Consequently, the number of transmitting functions is increased and the transmitting functions are decentralized to evade an overload on the originating server 101. At the same time, the number of clients which can use data of the originating server 101 is also increased. The repeating servers do not own data while multiplying the transmitting functions, and relay data of the originating server 101 or other repeating servers Consequently, data to be provided for clients are altered, the alteration is needed only on the originating server 101 and the processes after the data alteration is simplified.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a data transmission system for improving data transmission capability between a client and a server when a server transmits data requested to be provided by a client and the client receives the data. It is.

[0002]

2. Description of the Related Art There are various types of data transmission systems, and among them, there is a client-server type data transmission system. In this type of data transmission system,
The server has a function of transmitting encoded data such as video and audio. When a client wants to use data held by a server, the client requests the server to provide the data. Based on this request, data is transmitted and received between the server and the client. When the client receives the data sent from the server, the client decodes the data and uses it as appropriate.

There is no need for a one-to-one correspondence between a server and a client, and many systems have been realized in which a server can simultaneously provide data to a plurality of clients. FIG. 3 shows that one server 101 that provides data using the transmission mechanism 121 receives the data from the reception mechanisms 131 and 13.
This is an example of a client-server type data transmission system in which four clients 111, 112, 113, and 114 that receive data by using 2, 133, and 134 are connected.

[0004] Further, a transmission system in which the number of servers is not limited to one but the number of servers is increased has been realized. This is a system that replicates the same data provided by a server on another server. In this system, a client can obtain the same data regardless of which server is accessed.

[0005]

However, the above-mentioned conventional client-server type data transmission system has some problems to be solved.

[0006] The first problem is that the data transmission capability of the server is reduced due to the overload of the server, that is, the excessive access of the client. When data is simultaneously provided to a plurality of clients, the load on the server increases as the number of clients accessing the server increases.
If the load on the server exceeds the allowable amount for providing data normally, the server may delay or even stop providing data to the client. That is, a decrease in the processing capacity of the server due to an overload prevents normal provision of data.

A second problem is in a conventional transmission system in which a plurality of servers (mirror servers) having the same data are prepared. This conventional system has the effect of distributing the load. However, since it is necessary to keep the contents of the data owned by the servers the same, in this conventional system, every time the data to be provided is changed, the data must be copied to all the servers. This is the second problem.

[0008] The third problem is that there is a case where the access right of the client to the server is restricted.
If access to the server is restricted for the purpose of security protection, a client whose access is prohibited cannot acquire data.

[0009] It is an object of the present invention to solve the above-mentioned problems and improve the data transmission capability between a client and a server in a client-server type data transmission system.

[0010]

In order to achieve the above object, a first invention according to the present invention provides a transmission path in which a server transmits data requested to be provided by a client and the client receives the data. Transmission server provided with a transmission mechanism for transmitting data, a relay server provided with a reception mechanism for receiving data and a transmission mechanism for transmitting the received data, and receiving the data. And a plurality of clients having a receiving mechanism, wherein the relay server is connected in one or more stages between the transmission server and the plurality of clients or some of the clients.

According to a second aspect of the present invention based on the first aspect, the load monitoring means for monitoring the load status of each of the transmission server and the relay server; and the transmission monitoring means monitored by the load monitoring means. And a reroute configuration unit for changing a connection destination of the relay server or a client based on a load condition of the server or the relay server.

Further, according to a third aspect of the present invention, in the first and second aspects of the present invention, between the originating server and a client having no access right to the originating server,
A relay server having access rights to both of them is provided.

[0013] The first object of the present invention is addressed by connecting a relay server capable of relaying to a plurality of partners to a transmission server in one or more stages between a client and a server. This will increase the number of sending functions and
The transmission function can be distributed, and the number of clients that can use data at the same time can be increased.

Further, a technique is used in which the load of each server is clarified by the load monitoring means, and the connection destination of the client or the relay server is changed from the heavily loaded relay server to the lightly relay server by the reroute configuration means. As a result, the load on the originating server and the relay server is always low and can be suppressed on average, and the quality of the entire service is made uniform.

In order to solve the second problem, while using a relay server to increase the number of existing transmission functions, data is relayed without possessing data on the relay server. As a result, only one transmission server needs to change the data, and the process after the data change can be facilitated.

The third problem is addressed by connecting a transmitting server and a client whose access to the transmitting server is prohibited via a relay server permitted to access both. Thereby, data provision to the client is realized.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment] FIG. 1 is a block diagram showing a first embodiment of the present invention.

In the conventional example shown in FIG. 3, up to three servers 101 can transmit data at the same time, and when data transmission to four or more partners is overloaded for the server 101, four clients can simultaneously transmit data. When accessing the server 101, the load on the server exceeds the allowable amount of three servers of the originating server. In this case, the server 101
In this case, data cannot be transmitted normally, that is, data is not sent to the client or data transmission is delayed.

On the other hand, in the present embodiment, as shown in FIG.
1, the relay server 203 is connected to the relay server 202, the client 113 is connected to the relay server 203, and the client 114 is connected to the relay server 201.

The transmission server 101 uses the transmission mechanism 121 to transmit the encoded data to the relay servers 201 and 202.
-Send to the client 111.

The relay servers 201 and 202 receive the data transmitted from the transmission server 101 by the receiving mechanisms 221 and 222 provided respectively. Then, the received data is transmitted to the other relay server 203 and the client 114 using the transmission mechanisms 211 and 212, respectively. That is, the relay server performs a function of relaying data to be transmitted. Here, the relay server 202 and the relay server 2
03, relay servers may be connected in multiple stages.

Clients 111, 112, 113, 1
14 is the originating server 101 or the relay server 201,
The data transmitted from 202 and 203 is received by the receiving mechanism 13
1, 132, 133, and 134.

At this time, since the load on the transmission server 101 is three for the client 111 and the relay servers 201 and 202 in total, the load does not exceed the allowable amount for providing data normally. If the permissible capacity of the relay servers is two or more, data is normally transmitted to all the relay servers and clients.

As described above, by connecting the originating server and the client via the relay server connected in one or more stages, the number of transmission functions can be increased and the transmission functions can be distributed. As a result, the number of clients that can use data at the same time can be increased.

[Embodiment 2] FIG. 2 is a block diagram showing a second embodiment of the present invention.
01 and the relay servers 201, 202, and 203 are provided with load monitoring mechanisms 301, 311, 312, and 313, and the relay servers 201, 202, and 203 and the clients 111, 112, 113, and 114 are provided with the reroute configuration mechanisms 321 and 321. 322, 323, 331, 332, 333
FIG. 14 is a configuration diagram illustrating an example of an embodiment including 334.

Load monitoring mechanisms 301, 311, on the server
312 and 313 measure and store the load status of each server regularly or irregularly. The collected server load is sent to the server to which the server is connected. Further, the connection destination server further sends the load sent together with the load of the own server to the connection destination server. this,
Repeat until the call reaches the transmission server 101. Outgoing server 10
1. Taking the relay servers 202 and 203 as an example, the load on the relay server 203 is sent to the relay server 202, and then the load on the relay servers 202 and 203 is sent to the transmission server 101. Next, the load status collected in this way is transmitted from the originating server 101 to each of the re-route configuration mechanisms 321 to 323 and 331 to 334 in the same route as the data transmission.

The reroute configuration mechanisms 321 to 323 and 331 to 334 on the relay server and the client examine the server with the lightest load among the collected server loads. If there is a server lighter than the load of the server that is the connection destination of the client or the relay server, the reroute configuration mechanism disconnects the connection with the server that is the connection destination and changes the connection destination to the server that has the lighter load I do.

Alternatively, instead of changing the connection destination of the client having the re-route configuration mechanism or the relay server itself, the re-route configuration mechanism does not change the connection destination of another client or the relay server which does not have the re-route configuration mechanism. May be changed. That is, the load monitoring mechanism sends the measured load of the server to the server to which the server is connected, and the connected server further calculates the load sent together with the load measured by the server itself, and To the server. This is repeated up to the transmission server. At this time, each reroute configuration mechanism can know the load status of the relay destination and the relay server located downstream thereof. Each reroute configuration mechanism looks at the load status collected in this way and searches for an overloaded server. If there is a server in an overloaded state, the re-routing configuration mechanism selects, from among the relay servers or clients connected to the server, a number of relay servers or clients capable of eliminating the overloaded state, and Change the connection destination to a lighter server.

It is to be noted that, unlike the above example, a load monitoring mechanism that monitors the load status of a plurality of servers is realized instead of constructing a load monitoring mechanism one-to-one with each transmission / relay server. Is also possible.

Similarly, it is also possible to prepare one reroute configuration mechanism in the data transmission system and realize all the route changes by the reroute configuration mechanism. When the data transmission system is realized by a single reroute configuration mechanism, the reroute configuration mechanism collects the loads of all the originating servers and the relay servers from the load monitoring mechanism, and searches for an overloaded server. When there is a server in an overloaded state, the re-route configuration mechanism selects, from among the relay servers or clients connected to the server, a number of relay servers or clients capable of eliminating the overloaded state, and Change the connection to a lighter server.

As described above, by using the load monitoring mechanism and the reroute configuration mechanism to find a server with a high load, and by changing the connection to a server with a light load, the load on the originating server and the relay server is always maintained. It will be low and averaged down, and the quality of the whole service will be uniform.

[Embodiment 3] This embodiment is an example in which data used on the data transmission system is changed in the first and second embodiments.

The relay servers 201, 202, and 203 only relay the data transmitted from the originating server 101, and do not provide the data owned by the own server. When data used on the data transmission system is changed, only one of the originating servers 101 having a function of providing data needs to change the data, and the relay servers 201 to 203 are not affected. Not receive.

As described above, it is necessary to change the data by providing the data only by the originating server and using a plurality of relay servers having a function of relaying the data to the client. Only one originating server is required, and processing after data change can be facilitated.

[Embodiment 4] This embodiment is an example of a case where data is supplied to a client who does not have access right to the originating server.

In the conventional example shown in FIG.
In some cases, external access is restricted in order to maintain network security, and the client 112 may not have access to the originating server 101. In this case, since the client 112 cannot access the transmission server 101, it cannot receive data directly from the transmission server 101.

In this embodiment, for example, the relay server 20
As the second, an access right to the transmission server 101 and an access right to the client 112 at the same time are used.
, A connection between the relay server 201 and the client 112 is simultaneously established. At this time, the relay server 20
1 can realize a relay function of receiving data transmitted from the transmission server 101 and transmitting the data to the client 112. This means that the relay function realizes data transmission between the originating server and the client, which cannot be directly realized due to the restriction of the access right.

As described above, by using the relay server permitted to access a certain server, data can be provided to another server or client that cannot directly access the server. become.

[0040]

As described above, according to the data transmission system of the present invention, the relay server capable of relaying to a plurality of partners is connected to the transmission server in one or more stages, so that the transmission function is increased. It is distributed, and the degree of reduction in the data transmission capability of the originating server and the data relay capability of the relay server can be suppressed to a low level.

In the case where the load monitoring means clarifies the load on each server, and the reroute configuration means uses a technique for changing the connection destination of the client or the relay server from a heavily loaded relay server to a lightly relayed server, The load on the originating server / relay server can be kept low and averaged, and the quality of the entire service can be made uniform.

In addition, while using the relay server to make the existing transmission functions plural, the relay server relays without possessing the data. Therefore, when changing the data to be provided to the client, the data must be changed. Only one outgoing server is required, and processing after data change can be facilitated.

Further, when the originating server and the client who is prohibited from accessing the originating server are connected via a relay server permitted to access both, the access to the originating server is prohibited. Data is provided to the client that is in use.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a first exemplary embodiment of the present invention.

FIG. 2 is a diagram showing a configuration of a second exemplary embodiment of the present invention.

FIG. 3 is a diagram showing a configuration of a conventional client-server data transmission system.

[Explanation of symbols]

 101 transmission server 111-114 client 121, 211-213 transmission mechanism 131-134, 221-223 reception mechanism 201-203 relay server 301, 311-313 load management mechanism 321-323, 331-334 Reroute configuration mechanism

Claims (3)

[Claims] 1. A data transmission system connected by a transmission path, wherein a server transmits data requested to be provided from a client and the data is received by the client. A relay server having a receiving mechanism for receiving data and a transmitting mechanism for transmitting the received data, and a plurality of clients having a receiving mechanism for receiving data, the transmitting server and the plurality of A data transmission system, wherein the relay server is connected in one or more stages between clients or some of the clients. 2. A load monitoring means for monitoring the load status of each of the transmission server and the relay server; and a connection destination of the relay server or a connection destination of the relay server based on the load status of the transmission server or the relay server monitored by the load monitoring means. The data transmission system according to claim 1, further comprising: a re-route configuration unit that changes a connection destination of the client. 3. The transmission server according to claim 1, further comprising a relay server having access rights to both of the transmission server and the client having no access right to the transmission server. Data transmission system as described.