SE524486C2 - Data transfer method over peer-to-peer network involves information composed of type identity and name identity that is repeatedly and independently transmitted from server on two channels - Google Patents

Abstract

Method of sending information from server (8) to group of devices e.g. computers (1), connected over peer-to-peer network (3), where information composed of objects with type identity and name identity is sent repeatedly and independent on the information request of the devices by server on a channel and that an index of where to find which information is sent by server on second channel, and that second channel is listened to by devices.

Description

524 486 independent claims 1, 5, 10 and 11.

Details of the preferred embodiment of the invention are set forth in the accompanying drawings and the description below. Other features and advantages of the invention will become apparent from the description, drawings, and claims.

In the drawings: Fig. 1 is a block diagram of a communication system.

Fig. 2a shows a channel used to transmit information.

Fig. 2b shows a packet in an object transmitted on an information channel.

What in this context is called a server is a software component that delivers some added value, such as an email server, and has nothing to do with server hardware, which may be the same for your servers.

Client / server describes the relationship between two computer programs in which one program, the client, makes a request for a service from another program, the server, which completes the request. In a network, the client / server model provides a convenient way to connect programs that are efficiently distributed across different locations.

In fi g 1, a computerized electronic equipment connected to the network is represented by l, an operator side of 2 and an operator network of 3, which is also connected to the Internet.

The operator side 2 comprises a router 7, at least one information server 8 and a management system 9. The information server 8 is the server component used to transmit information specified by the operator over the network 3.

The management system 9 is responsible for the information contained in the information server 8.

The operator network 3 comprises fl your routers 7. A router is a device that determines the next network point a packet is to be sent to its destination. A router creates or maintains a table of available routes and their conditions and uses this information together with distance and cost algorithms to determine the best route for a given package. A packet can typically travel through a number of network points with routers before reaching its destination. 10 15 20 25 30 35 524 486 3 In the present invention, the routers are 7 multicast routers. Each multicast router 7 is connected to your electronic equipment 1, either directly or via a switch (not shown). Multicast technology is based on the interest of sending information to a selected group, instead of to all (broadcast) or to only one recipient (unicast). To enable that functionality in a network, group addressing is used.

Group addressing is based on services in multicast routers, which allow servers and clients to join a specific group with a specific address. Together, the routers keep track of the members of the group, and when a member of the group sends a message to the group address, all members receive that message.

In the present invention, a protocol based on multicast, hereinafter referred to as the information protocol, is used to repeatedly transmit information from the information server 8, whether or not that information has been requested.

The information, specified by the operator, is transmitted over and over again until it is stopped. It is up to the client to listen to the correct channel and to decode the information obtained. If the information is secret, it is possible to encrypt an entire information object or just some data inside the object.

In this context, an object is defined as a general information object sent to electronic equipment 1, such as TV charts, stock exchange information or boot information. The information protocol accepts streams of objects of almost any length and system capacity.

Fig. 2a shows the information channel comprising at least two objects, X and Y.

Objects are divided into pak your packets when they are broadcast on the channel. It is shown that the last packet in an item may be smaller than the other sent packets.

In a single package, the first part is the header, A and B, shown in fi g 2b. A is a static part that is always in the package. B is a dynamic part. C and D are payload. If there is no dynamic part B in the package, the payload C, D starts immediately after the static head A.

The packages contain object type and name, package number, checksums, pre-coded denominations, data, etc.

The payload C, D contains a part of the data object to be reassembled into an object. If the field "precoding" shows that the data contains a signature, the last part of the packet, D, must be treated as a signature. All information in the header, except the packet number, must be identical in all heads corresponding to the same object.

When encryption or signing of the payload is used, the signature is added as binary data at the end of the item composed of packet payloader.

The dynamic head type describes what is stored in the dynamic head and how it is used. The dynamic head B can store nothing, a digital signature, extra head felt or a digital signature and extra head blanket. If it is a combination, the dynamic head starts with the signature up to a break point, after that point extra head tents are stored. The dynamic main type tent consists of 2 bytes that are used as bitmaps described below.

AAABBBCCCDDDEEEE AAA is the dynamic head size in A * 16 bytes. If A = 000, B, C, D and E are ignored BBB is the breaking point between the digital signature and the extra main fields.

The breakpoint is located at (B / 8) * A * 16.

CCC describes the signature algorithm used.

DDD Describes the key to be used.

EEEE describes the additional main fields.

A use of the dynamic head B is for safety reasons.

The information protocol uses standardized multicast and it is easy for any node on a network to send multicast information (false multicast server) and thus confuse the clients on the subnet and potentially the whole network if the routers allow this. In the dynamic head B, it is possible for the operator to make an encrypted checksum. The clients that receive the information channel thus discover if a fake server is sending information and rejects all packets that do not have a correct checksum.

To send an object via the information protocol, it must first be coded at the object level with the encryption and checksums needed. 10 15 20 25 30 35 524 486 5 When the information server 8 reads a list of objects to send specified by the operator, it receives information about the object, including the object type, fil name or object source process name, and the packet size to be used. Server 8 calculates the number of packets needed to send the item and then creates the first packet to send. In the packet, it writes the correct data in the header and fills the payload section with some of the object data before sending the packet. This is then repeated for each required package.

The client receives one package at a time and must read the type and name fields for each package in order to reassemble the object. If the type and name are identical, the client must first ensure that the packet arrived correctly by checking the Internet Protocol (IP) and the Unicast Datagram Protocol (U DP) / Multicast header checksums. If any checksum is incorrect, the package is discarded and the client must act as if the package never arrived. If the dynamic header is used for a checksum or signature, it can also be used to determine if the package is valid.

After receiving all the packets, the client should have connected all the packets to one object. If the package headers specify that encryption or object-wide checksums are used, the client must now decode data or calculate the checksums.

If it is discovered that the object is not complete, the object must be discarded.

On a control channel there is an index of where you can find different objects available to the clients.

In the preferred embodiment of the present invention, Extensible Markup Language (XML) is used in the information protocol, but any other data format well known to those skilled in the art may be used, such as binary formats. Because many different general information objects are sent, all XML documents have a header that all clients connected to the operator network understand. An object template can look something like this: My0bjectName 10 15 20 25 30 35 524 486 6 XXXX Data to be sent is placed in the part of the document. Object name is a descriptive and unique name of the object according to a naming standard maintained by the network operator. Object identifiers are a universally unique identifier (UU ID), which is generated for each object to be transmitted. This identifier is used when the objects on the electronic equipment are to be updated.

To ensure a high availability of the information channels, several information servers can be used. For example, two servers are started up but only one transmits the information channel and the other listens to that information channel. If the first server stops transmitting, the second server notices it and starts transmitting the same information channel.

In the preferred embodiment of the present invention, the computerized electronic equipment is an advanced gateway between the operator network, which is an IP-based network, and household appliances. For example, to deliver broadband multimedia services to TVzn, such as music, video and e-commerce. In any case, there are no restrictions on the inventive gateway to be connected to household equipment. It is very suitable to be placed in hotels or companies, for example.

In another embodiment of the present invention, the computerized electronic equipment 1 is a mobile telephone used in a telecommunication network.

Claims (1)

A method of transmitting information from at least one server (8) to a selected group of computerized electronic equipment (1), connected to the first server (8) over an IP-based network (3). ), characterized in that group-addressed information, consisting of general objects having a type identity and a name identity, addressed to the electronic equipment (1) is transmitted repeatedly and independently of information request from the electronic equipment (1) of the first server (8) on at least a first channel, that an index of where to find what information is transmitted by the first server (8) on at least a second channel, the second channel being listened to by the equipment (1). Method according to claim 1, characterized in that the objects are divided into smaller packages (21) by the first server (8), and that each package is provided with a checksum. Method according to claim 2, characterized in that the objects are verified with the checksum in each package (21), wherein the packages (21) can be downloaded in any order of the equipment (1), and that which object to be downloaded is selected by the equipment (1). ). Method according to claim 2 or 3, characterized in that the checksum is placed in a dynamic head (B) in the packages (21). Device for sending information from at least one first server (8) to a selected group of computerized electronic equipment (1), connected to the first server (8) over an IP-based network (3) according to the method of claim 1, characterized by , that the first server is arranged to repeatedly and independently of the request for information from the electronic equipment (1) send group-addressed information directed to the electronic equipment (1) on at least a first channel, that the first server (8) is further arranged to send a index of where to find what information on at least one second channel, that the equipment (1) is arranged to listen to the second channel and that the information consists of general objects with a type identity and a nan identity. Device according to claim 5, characterized in that the objects are divided into smaller packages (21) by the first server (8), and that each package (21) is signed and provided with a checksum. Device according to claim 6, characterized in that the checksum verifies the objects in each package (21), and that the equipment (1) is therefore arranged to download the packages (21) in any order, and that the equipment (1) is arranged to select which item to download. Device according to claim 6 or 7, characterized in that the packages (21) comprise a dynamic head (B), in which the checksum is placed. Device according to one of Claims 5 to 8, characterized in that at least two first servers (8) are arranged to transmit the information over the network (3) and in that these servers (8) are arranged to transmit the information one at a time. Method of receiving information from at least the first server in an electronic equipment (1) which is part of a selected group of computerized electronic equipment (1), which are connected to a first server (8) over an IP-based network (3) (8), characterized in that group-addressed information consisting of general objects having a type identity and a name identity, directed to the electronic equipment, is repeatedly and independently of the request for information from the electronic equipment (1), transmitted by the first server (8). (1), is received by the electronic equipment (1) on at least a first channel, that an index of where to find what information is received by the electronic equipment (1) on at least a second channel, the second channel being listened to by the equipment ( 1), and wherein the electronic equipment connects to the first channel based on said indexes. Device for receiving information from at least the first server in an electronic equipment (1) which is part of a selected group of computerized electronic equipment (1), which are connected to a first server (8) over an IP-based network (3). (8), according to the method of claim 10, characterized in that the electronic equipment (1) is arranged to repeatedly and independently of the information request from the electronic equipment (1) receive group-addressed information directed to the electronic equipment (1) on at least a first channel, that the electronic equipment (1) is further arranged to receive an index of where to find which information on at least one second channel, that the equipment (1) is arranged to listen to the second channel and that the information consists of general objects with a type identity and a name identity, the electronic equipment joining the first channel based on said index.