EA003439B1 - Method for accessing the resources of the world wide web - Google Patents

Abstract

1. Method for accessing to the World-Wide Web Resources, wherein at the inter-network connection client/server by Internet paths clients form requests and send them to servers and receive a request object and/or answer flows via proxy server and/or gateways, wherein said units are concentrated and readdressed and/or set as cache the requests and/or the request objects and/or the answer flows wherein the clients send their requests to the servers via the Internet network and through the proxy servers and/or gateways according to a first path and once they have readdressed the requests to the servers and received from said servers the request objects and/or the answer flows, these units modify the transmission path of the request objects and/or the answer flows from the proxy servers and/or gateways to the clients in order to replace the first path with a second one, send the request objects and/or the answer flows in a wide-broadcasting network to the clients using at least one unidirectional emitting network interface and clients receive the request objects and/or the answer flows from the wide-broadcasting network and through the unidirectional emitting network interfaces wherein the second path is shorter than the first one and/or an indirect routing is applied on the first path while a direct one is applied on the second path. 2. Method according to claim 1, characterized in that the client is universal Web-client, requests are URL(Universal Resource Identifier) or/and URL(Universal Resource Locator), and the objects and/or flows are data flow and/or audio- and video streams. 3. Method according to claim 1, characterized in that the clients are private networks, connected with Internet through proxy servers and/or gateways of private networks. 4. Method according to claim 3, characterized in that the request are sent by first path via proxy server and/or gateways of private networks, connected with Internet, wherein the request objects and/or answer flows are received by second path from wide-broadcasting network by means of said units of private networks. 5. Method according to claim 1, or 3, or4, characterized in that gateways can be the gateways of network layer and/or transport layer, and/or representation layer, and/or application layer. 6. Method according to claim 3 or 4, characterized in that the private networks can be local networks and/or intranet, and/or Internet domains, and/or sub-networks of Internet. 7. Method according to claim 1, characterized in that the clients send requests to servers by Internet on proxy servers and/or gateways by the first path by inter-network gateways and/or routers and sub-networks of Internet. 8. Method according to claim 1, characterized in that parameters are to be measured and/or the metrics of first and second paths are set with the following comparing. 9. Method according to claims 7 or 8, characterized in that the measurement parameters of first and second paths are inter-network gateways quantity and/or routers on request paths and/or request objects, and/or answer flows. 10. Method according to claim 1, characterized in that transmitting network interface is DVB modulator (Digital Video Broadcasting). 11. Method according to claim 1, characterized in that the broadcasting network is carried out as air, cable, satellite, cellular broadcasting techniques with use of QAM or QPSK modulation. 12. Method according to 1, characterized in that the receiving network interface is carried out as cable modem or network interface card.

Description

The invention relates to electrical communication technology and can be used to reduce access time to data network or Internet resources, as well as to integrate Internet-based Protocols with existing infrastructures and digital broadcasting technologies: over-the-air, cable, satellite, cellular and others.

Prior art

A known method of addressing and routing is an Address Resolution Protocol with a proxy (Rgohu Lbbge88 KezoKyup Progoso1 (AKP)), in which the network station responds to requests intended for another station on the network, posing as the requested station, then it makes all the necessary decisions on further routing and forwarding packets to the real recipient. As such a proxy (representative, intermediary) is, as a rule, a gateway to the neighboring network. The gateway responds to requests for all stations of the neighboring network, being their representative on the local network, and all traffic to the adjacent network goes through a proxy (S. Klimenko, V. Urazmetov, p. 1. Habitat of the information society. Protvino. Russian Center for Physical and Technical Information , 1995, pp. 287-288).

This method allows you to solve a limited problem of communication (interaction), namely, interaction through an intermediary, nodes of two adjacent adjacent networks and does not allow the client and server to communicate in different subnets or domains separated by other subnets and gateways.

There is a method of high-speed access, implemented on the basis of the broadcast network THAT (I8 5347304, 13.09.94, H 04H 1/00). In the hybrid (cable, optocable network) access system use the transmission and reception of high-speed streams of digital information in the form of packets of different lengths and use standard TU practices and components. The method consists in that clients send requests to servers via a narrowband channel (a return channel of a cable specification, via dial-up telephone lines via a modem or a digital network with service integration ("8")), and receive response data flows through a wideband specification of the channel. This access system uses a client / server architecture based on asymmetric networks.

This method allows you to effectively solve only a limited task, namely, providing high-speed access to client nodes localized in a limited area, because This method requires a cable network with a reverse channel or direct telephone communication with a point of presence — the head station; this system does not allow economically solving the task of building a large distributed network for client nodes located at a considerable distance from the point of presence (for example, in another city). ), and also does not allow the inclusion in the broadband network of domains already included in the Internet through a narrow-band channel without changing the Internet connection port (Internet service provider) and problems arising in this connection new routing and addressing.

The closest in technical essence to the claimed method is a method of accessing the World Wide Web resources through proxy servers and / or gateways, which consists in the fact that during client / server interconnection via Internet routes, clients, by user commands, form requests and send them to servers and receive request objects and / or response flows from the servers through proxy servers and / or gateways, while the specified nodes concentrate and / or redirect and / or cache requests and / or request objects, and / or response flows, and servers execute requests received from clients and, by selecting the resources requested by clients, return request objects and / or response flows along network routes to proxy servers and / or gateways, the indicated nodes return request objects and / or response flows to clients (Ap liopepe, Keut ASC , Aog1b-A1be, Aeb, Mortuary, Sefeua (8 \ Y1 (h.eg1app), Mau 25-27, 1994, Ige! IyegpaOop sopgegepsa opie AAA, <i1: 1Shr: // \\ l \ l \\ seg.c11 / Rareg8AAA94 / 1io1opp. rz>).

This method allows to increase the effective network bandwidth only partially, due to caching, and only for clients located in the same local network and / or intranet as the proxy servers and / or gateways, and does not allow to significantly increase the bandwidth of the distributed network. network, because traffic requests sent to the proxy servers and / or gateways, and the reverse flow to the clients spreads along the same routes.

Disclosure of the technical entity

The invention is based on the task of reducing the time of access of consumers of services to the World Wide Web resources (Aog1bA1be Aeb) along the routes of the Internet transport network, as well as the task of integrating the networks based on the Internet Protocols with the existing infrastructure and digital broadcasting technologies: air, cable, satellite, cellular . When implementing this method, a reduction in the time of access to the World Wide Web resources for distributed and remote users is achieved by a factor of 1001,000 compared with dial-up access, which is the technical result of the invention.

The technical result is achieved by the fact that in the method of access to the resources of the World

In the case of a client / server internetwork connection, clients create requests and send them to servers and receive request objects and / or response flows from the proxy servers and / or gateways from the servers, and the specified nodes concentrate and / or redirect, and / or cache requests and / or request objects, and / or response streams, while clients send requests to servers over the Internet to proxy servers and / or gateways along the first route, and the specified nodes, by forwarding requests to servers and having received from the server, request objects and / or response streams, change or commute the route for transmitting request objects and / or response streams from proxy servers and / or gateways to clients from the first route to the second route, send request objects and / or response streams to the broadcasting network at least through one unidirectional sending network interface, and clients receive request objects and / or response streams from the broadcast network through unidirectional receiving network interfaces, with the second route shorter than the first- route and / or on the first route using the indirect route, and on the second line.

In addition, as a client can be used \ USB-client. IV1 (Ichuegka1 Vecoigse Shepyeg) and / or IVB (Hypote Vecoigse Boscot) are used as requests, and objects or streams are data streams and / or audio or video streams.

Clients are private networks connected to the Internet through proxy servers and / or private network gateways. Moreover, requests are sent on the first route through proxy servers and / or private network gateways, while the request objects and / or response streams are received on the second route from the broadcast network through the specified private network nodes.

Gateways can be network level and / or transport and / or representative and / or application level gateways. Private networks can be local area networks and / or an intranet, and / or a domain or domains of the Internet, and / or subnets of the Internet.

Clients send requests to servers on the Internet to proxy servers and / or gateways on the first route through gateways and / or routers and Internet subnets.

Measure the parameters and / or set the metric of the first and second routes and carry out their comparison.

The parameters for measuring the first and second routes are the number of gateways and / or routers in the path of following requests and / or request objects and / or response flows.

The transmitting network interface is an IUB modulator (Όίβίΐηΐ U1éyo Vtoaysakksd).

In addition, the broadcast network is made in the form of cable or terrestrial, or satellite, or cellular broadcasting using CAM or OPK modulation.

In addition, the receiving network interface can be configured as a cable modem or network interface card.

A short list of figures explaining the claimed method

FIG. 1 is a functional diagram illustrating the interrelationships of the main functional units of the system in the preferred embodiment of the method, where client 1, first route 2, Internet 3 together with gateways (routers) and subnets (domains), proxy servers and / or gateways 4, server 5 or a plurality of servers, a unidirectional transmitting network interface 6, a second route 7, a broadcast network 8, a unidirectional receiving network interfaces 9.

FIG. 2 shows an embodiment of the method using a private network and / or an intranet, where the proxy server and / or the gateway 10 of the private network and / or the intranet, the remaining positions correspond to the positions of the same nodes in FIG. one.

Preferred embodiments of this method

Clients in the claimed method may be \ MUTOKI Iyegpek Ehp1ogue \ Fue-client or Ixxare Sottishakot, as well as private networks and / or intranet networks connected to the Internet through a proxy server and / or a multi-service multi-protocol gateway and / or tunnel 10. Client 1, having access to the Internet, it forms and sends requests to servers 5. As requests, requests are generated in the format of the Internet Protocols, i.e. requests I1 or IVI (I1 - request1 Vekoigse ShePiPeG, IVI - υηίίοηη Vcoigse Boscot). Requests are received through gateways and subnets of the Internet 3 via the first route 2 to proxy servers and / or gateways and / or tunnels 4. These nodes are intermediary nodes intended for concentration (multiplexing) and / or forwarding and / or caching requests, and / or data objects, and / or response data streams, and / or inter-network traffic. The server, accepting client requests from proxy servers and / or gateways 4, processes them and generates a response in the form of objects and / or streams, which it transmits to the specified intermediary nodes. In turn, nodes 4, by accepting server responses, change (re-connect) the transfer route of objects and / or response data streams to clients 1 from the first route 2 to the second 7, send objects and / or response data streams to the broadcast network, for example, high-speed digital broadcasting network 8 to clients 1 according to the scheme - many points, at least through one unidirectional transmitting network interface 6. Clients 1 receive request objects and / or response streams from high-speed digital broadcasting network 8 through unidirectional e receiving network interfaces 9, wherein the second route is shorter than the first route and / or on the first route using an indirect route, and in a second line.

There is a special case when clients 1 use proxy servers and / or multiservice gateways 10 of a private network and / or intranet connected to the Internet 3 to send requests to the servers 5. Requests are transmitted through the gateways and Internet subnets of the Internet 3 via the first route 2 to proxy servers and / or gateways. These intermediary nodes 4, by redirecting requests to servers 5 and receiving request objects and / or response flows from servers 5, change (re-commute) the route for transferring request objects and / or response flows from intermediary nodes 4 to clients from the first route 2 to the second 7 by sending request objects and / or response streams to a high-speed digital broadcasting network 8 to clients 1 in a point-to-multipoint scheme, at least through one unidirectional sending network interface 6. Clients 1 receive request objects and / or response streams n through proxy servers and / or gateways 10 of a private network and / or intranet from a high-speed digital broadcasting network 8 via unidirectional receiving network interfaces 9, the second route is shorter than the first route and / or the first route uses indirect routing and the second direct route.

The claimed method of access to the resources of the World Wide Web is a transaction with a holistic state transition operation in the World Wide Web technical system. To implement access, a user who has a PC (personal computer) using the software —Yue-client, which is available on the PC — uses client 1 to query the source of information —You-server in the form required for transmission over the Internet, i.e. . in accordance with the “Internet Protocols” (TCP / 1P). Then, using a telephone modem and public networks, the request is transmitted via the HTTP protocol (Nureyeh! TgaikGeg Prog! Oso1) to the corresponding Internet node, which transmits it via the Internet via the first route 2 to the proxy server 4, located at the point of presence of the high-speed broadcasting network 8 Proxy server 4 sends a request to server 5 at the uye node on the network.

The Internet and, having received from it the requested object and / or response data stream, changes (re-commits) the transmission route of objects and / or response data streams and / or inter-network traffic from the proxy server 4 to clients 1 from the first route 2 to the second 7, directing the specified objects and / or traffic to the high-speed broadcast network 8 according to the point-to-point scheme 1. Clients 1 receive the requested objects, for example, the NTM code (Nureyeh! Magkir Lediade) from the high-speed broadcast network 8 via the receiving network interface s 9, convert objects into the required format and display them on PC output devices and / or PC screen.

When implementing this asymmetric asynchronous access to the resources of a distributed network, data objects, indexed resources of the World Wide Web, are read, written or modified. Resources are network data objects and / or types of services identified by means of ϋΚ! or a KFM. In the particular case, query objects are objects identified as a KFM and immersed in the base NTM object that are retrieved during the HTTP sessions and generate video streams on the Internet. Reverse streams are data streams and / or audio or video streams.

To implement these relationships, a type of client / server computing network interaction model is used: client-agent-server. Proxy servers 4 are agents, acting as both a client and a server, and all outgoing traffic to the Internet and intranet traffic concentrates on it, since all clients send requests to the servers and receive the requested request objects and / or reverse flows from them through the indicated nodes intermediaries 4. Caching reduces both the response time for the client and the peak loads on the communication channels, since reduces and smoothes inter-network traffic, which is extremely uneven, due to replication and multiple use of data objects.

A new system operation on whole data objects, changing (re-switching) the route of their transmission, allows complex and flexible management of data flows in a distributed network. The introduction of an additional second route 7 for reverse traffic with large bandwidth through the use of high-speed broadcasting network 8 reduces the time to access resources for network distributed and remote users.

The second route 7 is shorter than the first route 2 and / or on the first route 2 they use indirect routing, and on the second 7 they use direct. By direct routing is understood as direct communication between nodes, i.e.

Ί The number of gateway gateways on the route is zero. Indirect routing is understood as communication through a sequence of gateways or at least one gateway, i.e. The number of gateways on the route is greater than or equal to one.

At the same time, access time to resources is significantly reduced by reducing the number or exclusion of gateway gateways and / or routers on the second route when transporting objects and / or data streams over a high-speed broadcast channel. Also, access time is reduced by caching and reusing entire data objects retrieved by proxy servers and / or gateways from inter-network traffic in the global Internet.

Industrial Applicability

To implement this method, a software tool is used as a client - the universal \ USB client 1p1sgps1 Expl of the corporation M1 stokoy or №1xar Sottipka1ot company No1xar sotypkaOopk. These funds operate on the PC platform (Regkopa1 Sotriet) in the environment of the Mktokoy \ Utbo \ 95 ΝΤ or ΝΤ operating system. As clients, there may also be private networks and / or intranets connected to the Internet through proxy servers.

As a proxy server, software is used by Mktokoy Rgohu 8et or No. 1xarre Rgohu 8etuet the above-named companies that can support HUSHKOS and / or 8SKK and / or 8OSK1 gateways.

The servers can be used with the software \ WoA-server and / or HTTP of the server Mktoko 1n1gpe11nGogta1yup 8etuet or # 1xar 8shk 8ro1 server.

As gateways can be used gateways 1R - MAC (1P (egpe1 Rgo1oso1 - Mephala Assekk Sop1to1) and / or 1 R - ΌνΒ - T / C / 8 (ΌφίΙη1 Teggek1pa1 Ttapktkkyup 8uk1etk ET8 300,744 / EschTsa1 SaYe Oeyuegu 8uk1et ET8 300,429 / EschTsa1 The 8th Tactic Review 8TC ET8 300 421) and / or the Digital Video Broadcasting Standards (“Όν”) on the Network and / or channels and / or the media on the Internet.

As a transmitting network interface, a hardware and software tool can be used.

Cables, terrestrial, satellite, or cellular networks can be used as a broadcasting network, in which TsAM or TsR8K modulation can be used.

As a receiving network interface can be used cable modems of the company № х1еуе1 (former Seieta1 1pc), сht 21, 3Сот, Mono1a or SuIet8a1 satellite ΌνΒ modem - network interface cards of the company № \ ν MeFa SotypkaPop.

Claims (12)

CLAIM 1. The method of accessing the World Wide Web resources, which consists in the fact that when the client / server is interconnected via Internet routes, clients generate requests and send them to the servers and receive request objects and / or response flows from the servers through proxy servers and / or gateways wherein said nodes concentrate and / or redirect and / or cache requests and / or request objects and / or response flows, characterized in that the clients send requests to servers via the Internet to proxy servers and / or gateways along the first route , and the decree nodal nodes, redirecting requests to servers and receiving request objects and / or response flows from servers, change or switch the transmission route of request objects and / or response flows from proxy servers and / or gateways to clients from the first route to the second, direct request objects and / or response streams to the broadcast network to clients through at least one unidirectional transmitting network interface, and clients receive request objects and / or response streams from the broadcast network through unidirectional receiving network interfaces, the second route being shorter than the first route and / or on the first route using indirect routing, and on the second direct. 2. The method according to claim 1, characterized in that as a client use a universal \ Ue-client. as queries use IR1 (seeker 1 Kekoigse IepIyeg) and / or IKE (Hypot Kekoigse IosIog), and the objects and / or streams are data streams and / or audio or video streams. 3. The method according to claim 1, characterized in that the clients are private networks connected to the Internet through proxy servers and / or gateways of private networks. 4. The method according to claim 3, characterized in that the requests are sent on the first route through proxy servers and / or gateways of private networks connected to the Internet, while the objects of the requests and / or response flows are received on the second route from the broadcast network through the indicated nodes of private networks. 5. The method according to claim 1, or 3, or 4, characterized in that the gateways can be gateways of the network layer and / or transport layer, and / or representative layer, and / or application layer. 6. The method according to claim 3 or 4, characterized in that the private networks can be local networks and / or intranets, and / or domain, and / or domains of the Internet and / or subnet of the Internet. 7. The method according to claim 1, characterized in that the clients send requests to the servers via the Internet to proxy servers and / or gateways along the first route through the Internet gateways and / or routers and subnets. 8. The method according to claim 1 or 3, characterized in that the parameters are measured and / or set the metric of the first and second routes and compare them. 9. The method according to claim 7 or 8, characterized in that the measurement parameters of the first and second FIG. 1 route is the number of gateways and / or routers along the path of requests and / or request objects and / or response flows. 10. The method according to claim 1, characterized in that the transmitting network interface is an IPM modulator (Όφίΐαΐ U1beo Vgoabeishd). 11. The method according to claim 1, characterized in that the broadcast network is made in the form of cable or terrestrial, or satellite, or cellular broadcasting using CAM or OP8K modulation. 12. The method according to claim 1, characterized in that the receiving network interface is made in the form of a cable modem or network interface card.