LT4729B - Internet caching system - Google Patents

Abstract

The present invention relates to a method, a system and a server for caching Internet information content. According to the invention, there is provided a set of geographically distributed cache servers generally serving different geographical regions, wherein Internet information derived in relation to the operation of one of said cache servers is distributed to essentially all of said servers.

Description

The invention relates to a method, system and server for storing Internet information in super-cache memory.

Over the last few years, the Internet has become the most evolving means of communication and is expected to become the main information-sharing system in the future. The Internet is growing in popularity and the number of users is growing at tremendous speed. Anyone can transfer any information - text, pictures, audio-visual information - to a network where it can be retrieved by users anywhere in the world. For this reason, the Internet and its most widely used feature today - the World Wide Web (WWW) - is incredibly popular.

However, the popularity of the Internet, and in particular the World Wide Web application, places a heavy load on the network. The information exchange flow on the Internet doubles every three months. This exponential growth will slow down sometime, but some factors indicate that it will not be fast.

Today only a small percentage of all personal computers (PCs) are connected to the Internet, but it is likely that the vast majority of PCs who purchase will want to use the Internet. The speed of communication between the user and the Internet infrastructure is growing unstoppable. Technologies like ISON, cable TV modems and xDSL are coming. In addition, manufacturers of consumer electronic devices are launching affordable devices that can access television networks via the World Wide Web.

These and other factors make information on the Internet difficult to access because the system is overloaded. Limited bandwidth is a major problem in many parts of the world. The flow of information between the US and Europe is limited by transatlantic bandwidth. Bandwidth is too low to cope with the growing popularity of the Internet.

There are two main solutions to this problem. The first way is to increase the bandwidth and switching power, which is done, but it requires a lot of capital investment and faces major technical problems.

The second way is to use the so-called super caching methods described in, for example, James

S.Gvertzman, Margo Seltzer, The Case for Geographic Push-Caching, 1995; World Wide Web Journal, November 1995, Radhika Malpani et al., "Making the Worid Wide Web Caching Servers Cooperate"; Suguru Yamaguchi, Ken-ichi Chien, Hiroyuki Inoue, WWW Cache Management and Its International Deployment:, 1997, et al. publications. Storing information in super cache means keeping traces of the Internet information exchange traffic and copies of the most commonly accessed World Wide Web files (files) closer to the user than the original files. This allows you to save a local copy of the web page you are interested in. For example, a copy of the CNN web site in the US may be temporarily stored in the super-cache of the European Authorized Representative, allowing European Internet users to quickly access the CNN web site without transatlantic access. The overall information content of the World Wide Web is immeasurable, but only a relatively small amount of this vast amount of information is utilized, compared to a huge amount actually reviewed. Depending on the size and homogeneity of the user community, about 10-20 gigabytes of super-cache memory will reduce information exchange rates by 3050% in this community (spring 1997).

However, even with this kind of super-memory storage, the bandwidth of the communication systems in many parts of the world, such as southern and eastern Europe, southern America, India and eastern Asia, is insufficient to properly adapt the Internet.

The object of the invention is to reduce the power limiters of the Internet by introducing methods of storing information in super-cache memory, which reduces the time of accessing the Internet and allows to significantly increase the number of users and the speed of information exchange, especially in regions where bandwidth is limited.

This object is achieved by the present invention by providing a method, system and server for storing Internet information in super-cache memory as described in the invention.

The invention is based on the idea that a geographic area characterized by linguistic and cultural homogeneity often differs in size and shape from the economically and technically optimal area to be served by a single super-memory server. As a result, such an area is served by multiple geographically dispersed servers. However, the invention is also based on the assumption that users with such linguistic and cultural meanings within a homogeneous geographic area will also have homogeneous priorities with respect to the information pages visited, information stored at the request of the user in the supercache of one such server should be stored The principle is that if one user is interested in a particular type of information, it is likely that other members of a homogeneous area of the same language and culture will be interested in the same information. The larger the end-user community, the more likely it is that someone else will request a specific file from the community.

Thus, according to the present invention, information stored on geographically distributed super-cache servers serving different geographic areas but having a common connection, such as serving a cultural and / or linguistically defined user group or area, is updated with substantially the same information when only one these super cache servers request information at the request of the end user or the like.

Such a linguistic and cultural homogeneous community can be defined as a group of people united by a common nationality, language, specific religion, a certain level of technology and development, a particular economic region, and combinations thereof, or the like.

Thus, according to the present invention, these geographically distributed super-cache servers are linguistically and culturally distributed within a defined global geographic area or geographically defined community. In addition, each super-cache server is designed to serve the appropriate local region within that geographic area or community.

For example, the German-speaking areas of Germany, Austria, Switzerland and Italy can be defined as a homogeneous culture and language global area. This is why super cache servers are distributed inside this zone. Among these servers, located inside the global area defined above, one (or more) is arranged to serve the first region comprising the northern part of Germany, the second (or more) to serve the second region comprising the eastern part of Germany, the third (or more). to serve a third region comprising central Germany, a fourth (or more) to serve a fourth region comprising Switzerland and the northern part of Italy, and finally a fifth (or more) to serve a fifth region comprising Austria.

It should be noted that a geographically defined zone does not necessarily mean a homogeneous, continuous zone having closed boundaries, but may also mean only a set of geographically separated zones which together form the zone of the invention.

According to the inventor's estimates, in some countries of the world, such as India and South America, the bandwidth capacity of a telecommunications network is so low that it is more efficient to distribute a specific information packet to all super-cache servers within a specific global area defined by a single user , to perform a second network search for the same information packet ordered by another user. However, the rules for using the super-cache storage method and the non-storage method can be set in different ways and depend on the application's specific usage environment, which will be explained below.

Distributing information to multiple super-cache servers according to the present invention can be accomplished in various ways. For example, the internet could be used. However, this could further increase network transmission bandwidth. That is why, in the best embodiment of the present invention, the information is distributed to multiple super-cache servers using a multichannel connection, for example, through dedicated data channels separated from the Internet connection.

According to a preferred embodiment of the invention, this information is distributed to several super-cache servers via satellite. Each server then has the ability to connect to and send information from the ground station to the satellite communications line, and all servers can connect to the satellite data link to the ground station, which transmits information sent from any server. The hardware and software for this distribution can be mapped to the super-cache server itself, or provided by, for example, an Internet Service Provider (ISP) or Satellite Provider (SCLP), Similarly, software to control the flow of information and make system decisions , may be installed on super-cache servers, may be hosted by ISPs, or may be hosted in any common location that is readily apparent to one of ordinary skill in the art. If a satellite system is used, the satellite connection can also be used to transmit the request to other parts of the globe, for example from Europe to the US and vice versa.

According to another embodiment of the invention, all super-memory servers within the system are connected via data channels to a central control unit. Such a central control unit may, for example, decide whether information should be stored in super-cache memory, how it will be distributed, and so on.

Depending on the size of the community, the capacity of the super-memory servers, the network connection capacity, the super-cache provider objects, etc., the distributed super-cache system may be arranged to distribute or not the information obtained under various rules. In the best embodiment of the invention, only the request protocol data blocks associated with a specific communication format or application task corresponding to the type of information service implemented on the local storage devices are stored in super-cache memory. For example, so-called TCP (Data Transfer Protocol) requests - the WWW port. Alternatively, for example, a provider of information stored on a super-cache may decide to store only data taken from specific addresses (such as .com or .org) in the super-cache, only after it has been requested internally for a certain number of times (for example , after three separate requests), or so on.

The processing tools necessary to make such decisions may be provided on each super-cache server, on the central control unit mentioned above, at an Internet service provider, or similar location that interfaces with super-cache servers, or the like.

In addition, a request relating to an information provider located in a region served by one of several super-cache servers may be handled in different ways and will depend on different embodiments of the invention, which will be explained below.

In the first embodiment of the invention, it is assumed that the end-user local information request to the ISP, when both are in the same region, is of purely local interest. That’s why information; a) will not be stored in super cache at all because the local user will always be able to easily access the ISP: or b) will only be stored on the local super cache server and will not be distributed over the whole network of geographically distributed super cache servers. the object of interest. Thus, in this context, the term local is attributed to features occurring in one of these regions.

According to a second embodiment of the invention, it is assumed that a request for end-user information to an ISP located in one of these regions will not be stored on a super-cache server serving that region, but instead will only be distributed to all other cache servers within that system. the local user will always be able to contact the local internet information provider (so there is no point in storing the information on the local super cache server), and the user outside the region will not have the same easy access to the local internet information provider.

In yet another embodiment of the invention, it is assumed that the super-memory server is sufficiently powerful to handle all requests, so that information related to local ISPs is no longer processed differently, and thus by storing information on one super-memory server within the system, the same information will be stored on all servers within the system.

In yet another embodiment of the invention, depending on the choice made within the decision-making system, it is provided that the address list of the Internet information providers cannot be stored in super-cache memory. In this way, each super-cache is organized in such a way that it can compare incoming information requests with this list to see if or not a request is to be stored in super-cache.

Super cache servers can be customized to store information for a certain amount of time. For example, super-memory can operate on a first come, first served basis. According to another example, a certain type of information may be required to be updated, specifying the maximum period for which the copied information may be used, provided that the information is still accurate. Of course, in relation to these and other aspects, the invention may include different types of conventional super-cache storage devices, as will be understood by one of ordinary skill in the art.

In addition, each of these super-memory servers may be comprised of several subordinate servers connected by high-speed switches to the super-memory management program that controls its operation. The number of super-cache servers is unlimited and each server can be used by more than one ISP.

If any of these super cache servers fail, the system can quickly bypass them by continuing to service subscribers while the faulty server is repaired or replaced. The super-cache functionality is executed by another server in another region within the system, the advantage of the invention being that the super-cache server delivers the same stored information as the bypass server, thereby ensuring that super-cache information is still available to end users in the bypass server region.

While the description of the invention relates to internet communication systems, it will be apparent to those skilled in the art that the invention may also be applicable to other similar types of future global information communication systems that may have similar communication problems. For this reason, the invention is not limited to web application applications.

In addition, although the description of the invention relates to the World Wide Web application, it should be understood that the invention may be applicable to many other network applications.

Other aspects, features and advantages of the invention will become apparent from the following description of exemplary embodiments of the invention with reference to the accompanying drawings, in which:

Fig. 1 is a schematic view of a super-cache system for storing Internet information of the present invention;

Fig. 2 is a schematic view of a super-cache server that is part of the system shown in Fig. 1:

Figure 3 is an alternative schematic view of a super-cache memory server;

Figure 4 is another schematic view of a super-cache memory server;

Fig. 5 is a block diagram of the operation of a super-cache memory server;

Figure 6 is a block diagram of the interceptor activity of Figure 3;

Fig. 7 is another schematic view of a super memory cache system of the present invention; and

Fig. 8 is a further schematic view of a system for storing internet information in super-cache memory of the present invention.

A first embodiment of a system for storing Internet information in super-cache memory will now be described with reference to FIG. As can be seen in Figure 1, geographical area 1 defined by language and / or culture is made up of four geographical regions A, B, C and D. For example, zone 1 could be British Isles and regions B, C and D could be Ireland, Wales, Scotland and northern England, southern England, respectively.

Each region A, B, C, and D has at least one ISP 2a, 2b, 2c, and 2d providing a router Internet 3. Each ISP 2a, 2b, 2c, and 2d provides an Internet connection to multiple end users 4a, 4b, 4c. and 4d and multiple Internet information providers 5a, 5b, 5c and 5d. It goes without saying that although end users 4 and information providers 5 are shown as separate objects in Figure 1, the end user can also be an information provider.

Each service provider is connected to at least one Internet caching server 6a, 6b, 6c and 6d. Each super-cache server 6 provides end users 4 with a functional capability to store information in super-cache memory within the appropriate region. In addition, each super-memory server 6a, 6b, 6c and 6d communicates with the satellite antenna 7a, 7b, 7c and 7d and can transmit information to all other super-memory servers inside the area 1 via satellite 8.

The operation of the system of FIG. 1 will now be described. When, for example, service provider 2a in region A receives a request from end user 4 for information provided by information provider 5e located in region E, which in this case is outside zone 1 (e.g. region E is North America), Provider 2a verifies that an updated copy of the requested information is stored on the super cache server 6a associated with it. If so, the requested information is retrieved from the super-cache server 6a and then provided to the end user. However, if there is no copy of the requested information on the super-cache server 6a, the service provider 2a forwards the request to the true information provider 5e over the internet 3. When the requested information returns from the service provider 5e over the internet 3, the service provider 2a information. As part of the update operation, updated information is transmitted via satellite dish 7a and satellite 8 to super-cache servers 6b, 6c and 6d, thereby updating all servers with the same information. Once the information is updated, no user within Zone 4 1 needs to contact the primary information provider 5e over the Internet, instead they can access the copy stored on the appropriate super-cache server. If any super cache server is full then the longest stored information (the oldest used by the end user) will be deleted from that server when the data is updated. In addition, each server will take several steps to ensure that the information stored on each super-cache server is accurate and up-to-date, providing reliable copies of the original web pages.

In order to simplify the description, all drawings which perform similar functions to those shown in FIG. 1 will be denoted by the same numerals.

The super cache server system forming part of the system shown in FIG. 1 will now be described with reference to FIG. As shown in Figure 2, three end user terminals or stations 4 are connected to a multiplexer 9, which may be a modem storage device or a local area network (LAN) router, depending on the type of user system. The multiplexer 9 is coupled to an Internet Service Provider Takeover Station 2 providing a connection to the Internet 3.

Multiplexer 9 multiplexes communications to and from terminals 4.

In such an embodiment, user 2, wishing to obtain information not provided in the drawing by an ISP 3 on the publication site as a WWW site or web page, typically sends a multiplexer 9 information request to ISP 2, namely an HTTP request j \ N \ NVJ port, where the request is routed to the Internet 3 for the final information provider. The information provider responds to the request by sending the requested information online 3 back to the user 4 via the service provider 2.

However, as shown in the diagram in FIG. 2, user request 2 is checked by service provider intercepting station 2. The intercepting station verifies that a copy of the requested information is on local super cache server 6 directly connected to intercepting station 2. If a copy of the requested information is on a local server 6, the user's request is directed to server 6, which will then return the requested information to the user. In this case, the information will already be present on all super-cache servers within zone 1 of FIG. 1 and will not need to be forwarded to other servers.

However, if the intercepting station 2 determines that there is no copy of the information of interest to the user on the local server 6, then the request for information 4 of the user 4 is sent to the Internet 3 via a conventional internet connection. The intercept station will follow the response of the Internet 3 to the user 4 and update the super-cache server 6 with the requested information as soon as it is received.

In accordance with the present invention, the storage of new or updated information on the super-cache server 6 occurs in conjunction with the distribution of the new or updated information to other super-cache servers within the area 1 shown in FIG. This allocation is made either by the service provider's super-cache servers 6 or by the intercepting station 2 via a data link with satellite 8 to access other super-cache servers within a defined area. In a similar way, i.e. via the satellite communication line, the super cache server 6 will also receive new or updated information from other super cache servers within the area.

It should be noted that in this example, the interception station only intercepts certain specific types of communication packets. For example, it intercepts only 4 requests for WWW information from users on the World Wide Web. Other communication services, such as e-mail services, etc., are not touched by Station 2.

An alternative super-cache server system similar to that shown in FIG. 2 will now be described with reference to FIG. The system of FIG. 3 differs from the system of FIG. 2 in that the service provider takeover station 2 is connected not only to the super-cache memory 6, but also to the fast access super-cache 10. Compared to the super-memory 6 of the invention. , for example, several hundred gigabytes, the size of the high-speed super accessory cache will, in this case, be much smaller, such as one gigabyte. Thus, the super-fast cache 10 is designed to store substantially all of the information passing through intercept station 2, but each information packet will only be stored for a very short period of time.

The high-speed super access cache depicted in FIG. 3, having memory areas 10 and review tables 11 showing which information is currently stored in these memory areas, is used as the working memory of the takeover station 2. Thus, when accepting a request for information from user 4, the intercepting station will first check for such information in its high-speed cache memory 11, 10. The super-cache server 6 will only be accessed if the requested information is not found in super-cache 10. However, all information related to each information request by users 4 will be temporarily stored in high-speed super cache 10, which will either be information received from the Internet 3 or information received from the super-memory server 6, and the super-memory server will only be updated with new information, retrieved from the Internet 3. In addition, super-cache may be used to store information of a different type than that stored in super-cache 6. For example, in addition to WWW information stored in super cache server 6, information related to other types of requests may be stored in super cache. In addition, the information stored in the super cache 10 will not be automatically allocated to the other super caches in the area 1 shown in FIG. 1, inside.

Yet another alternative super-cache server system similar to that shown in Figure 2 will be described with reference to Figure 4. As shown in FIG. 4, all WWW requests from the service provider 2 will be forwarded to the super-cache server 6. The super-cache server will respond to the request if the requested information is stored there, or it will try to retrieve the information itself from the internet 3 using either satellite connection 12 to the internet. Upon retrieval of the requested information, the super cache server 6 will update the information stored in itself, as well as the information stored in other super cache memory via satellite 8, and provide the information to the end user 4 through the service provider 2.

The service provider may also provide other types of services, such as e-mail services, etc., without sending packets of such information through a super-cache server.

The operation of the super-cache server 6 of FIG. 4 will now be described with reference to the block diagram of FIG. 5. Upon triggering system operation in step S1, the super-memory server receives in step S2 an information request from an end user belonging to a particular information provider. In step S3, the super-cache server determines if there is a copy of the information it requests. If so, the requested information is transmitted to the end user in step S4 and the operation is terminated in step S10. (Of course, the final step S10 can return the operation to step S1).

However, if in step S3 it is determined that the super-memory server does not have a copy of the requested information, the process continues in step S5 where the super-memory server sends an information request over the Internet to the specified information provider. Thereafter, in step S6, the super-cache server receives the requested information and forwards it to the end user in step S7. The information received in step S8 is stored on the super-cache server, and then in step S8 the information is distributed to all other super-cache servers inside area 1 of FIG. Thus, new, previously unprotected super-cache memory information will be retained on virtually all super-cache servers inside the zone, and thus easily accessible to all users in that zone.

The operation of the takeover station or service provider 2 shown in Fig. 3 will be described with reference to the flowchart of Fig. 6. When triggered in step S11, the intercepting station in step 2 S12 reads an information request from an end user addressed to a particular information provider. In step S13, the intercepting station 2 checks the table of contents 11 of the high-speed super-cache memory 10 and makes sure that it contains a copy of the requested information. If so, the operation proceeds to step S15 described below. If not, the operation proceeds to step S14, where the intercepting station sends a request to the super cache server 6 to verify that it contains a copy of the requested information. If the answer is positive, the process goes to step S15 where the end user request is intercepted and step S16 where the requested information is passed to the end user using either super cache 10 or super cache server 6. However, if the super cache response is negative, the process proceeds to step S17, where the intercepting station decides not to intercept the user's request, but to forward it over the Internet to a particular information provider. The process then proceeds to step S18, where the intercepting station examines the response sent by the information provider to the end user. As such information passes through the end user on the way to the end user, the latter writes, at step S19, previously unavailable information to the super-cache server 6 and distributes it to all other super-cache servers inside area 1 of FIG. Thus, the new information that has not been previously recorded will be stored on virtually all super-cache servers inside the zone and thus easily accessible to all users in that zone. Each time the information is retrieved from the super-cache on the network, a copy of it is temporarily stored on the super-cache 10.

Another embodiment of an Internet caching system similar to the one shown in FIG. 1 will now be described with reference to FIG. As shown in FIG. 7, the system differs from that shown in FIG. 1 in response to an information provider 5e located in a region outside the system area 1. The response to the information request sent from the end user 4a will not be forwarded back to the user via Internet 3. Instead, the response is transmitted directly by satellite 8 to servers 6a, 6b, 6c and 6e, thus automatically updating all super-cache servers. The super-cache server 6a and the service provider 2a then transmit the information to the end user 4a.

Another embodiment of a system for storing Internet information in super-cache memory, similar to that shown in FIG. 1, will now be described with reference to FIG. As shown in FIG. 8, each super-memory server in area 1 serving respective regions A, B, C and D is connected by data channels to a central control unit 13. The central control unit 13 decides whether information is to be stored on the respective super-memory server and how it is to be distributed to other super-cache memories inside zone 1. In this case, the information may be distributed between different super-fast memories using either satellite communication or data channel communication with a central control unit 13.

Further, with respect to the systems illustrated in Figures 1, 7 and 8, it is obvious that other operating schemes than those discussed above may be applied to each of the super-cache servers 6, to each service provider 2, or to the central control unit 13 for "local" solutions. "Retrieval of request information, such as end-user information request 4a to information provider 5a in the same region A, in super-cache memory.

It will be understood that the design and function of the elements described with reference to the drawings will be apparent to those skilled in the art.

While the invention has been described with reference to specific embodiments thereof, many modifications, modifications, and the like will be apparent to those skilled in the art. The described embodiments of the invention are not to be construed as limiting the invention.

Claims (34)

DEFINITION OF INVENTION 1. A method of storing Internet information in super-cache, comprising storing traces of the Internet information exchange traffic and the most commonly accessed copies of the World Wide Web, in a manner such that: retrieves the information sent by the ISP to the end user upon request of that user information and distributes this information to a plurality of geographically distributed super-cache servers. 2. The method of claim 1, further comprising coordinating the retrieval of information with a super-cache server serving that user in a geographic region served by this super-cache. 3. The method of claim 2, wherein storing said information on a super-cache memory server. 4. The method of claim 3, wherein the information is stored on a super-cache only if the ISP is outside this region. 5. The method of claim 3, wherein the information is stored on the super-cache only if the ISP is within the region. 6. The method of claim 2, wherein the information is distributed only if the Internet information provider is outside the region. 7. The method of claim 2, wherein the information is distributed only if the Internet information provider is within the region. 8. A method as claimed in any one of the preceding claims, comprising distributing said information to a plurality of geographically distributed super-memory servers using a multichannel connection. 9. The method of claim 8, further comprising distributing said information to a plurality of geographically distributed super-cache servers using satellite communication. 10. A method as claimed in any preceding claim, further comprising distributing the information obtained by the rule by deciding whether each piece of information is to be distributed to a plurality of geographically distributed super-cache servers. 11. A method as claimed in any one of the preceding claims, wherein said plurality of geographically distributed super-cache servers serve different geographic regions. 12. The method of any of the preceding claims, further comprising geo-plotting a plurality of super-cache servers within the defined language or culture. 13. The method of claim 11, further comprising geo-plotting a plurality of super-memory servers within a language or culture-defined area comprising these regions. 14. A super-cache system for storing information on the Internet, having a plurality of geographically distributed super-cache servers, characterized in that it comprises: means for retrieving Internet information from any of the super-cache servers; and means for distributing the retrieved information to substantially all of the super-cache servers. 15. The super-cache Internet information storage system of claim 14, having information retrieval means for sending retrieved information based on an end-user-specific request from an Internet information provider to an end-user located in a geographic region served by one of these super-cache servers. 16. The super-cache system for storing Internet information according to claim 15, wherein the one super-cache server is dedicated to storing that information. 17. The super-cache system for storing Internet information according to claim 16, wherein the one super-cache server is dedicated to storing this information only when the information provider is outside the region. 18. The super-cache system for storing Internet information according to claim 16, wherein the one super-cache server is dedicated to storing this information only if the information provider is within the region. 19. The super-cache Internet information storage system of claim 15, wherein it has distribution means for distributing information to the plurality of super-cache servers only when the information provider is outside the region. 20. The super-cache Internet information storage system of claim 15, further comprising distribution means for distributing information to the plurality of super-cache servers only if the information provider is within the region. 21. The super-cache Internet information storage system of any one of claims 14 to 20, further comprising distribution means for distributing information to a plurality of super-cache servers using a multichannel connection. 22. The super-cache Internet information storage system of claim 21, further comprising distribution means for distributing information to a plurality of super-cache servers via satellite. 23. A super-cache system for storing Internet information according to any one of claims 14 to 22, further comprising a data processing means for determining whether the retrieved information is to be distributed to a plurality of super-cache servers. 24. The super-cache Internet information storage system according to any one of claims 14 to 23, characterized by having geo-distributed super-cache servers for serving different geographic regions. 25. A super-cache system for storing Internet information according to any one of claims 14 to 24, characterized by having super-cache servers spread over a language or culture within a defined geographical area. 26. A super-cache system for storing Internet information according to any one of claims 14 to 24, characterized by having super-cache servers distributed in a language or culture within a defined geographical area comprising these regions. 27. An Internet Information Storage Super Cache Server, configured primarily to serve users in a geographic region, having data reception, storage, and processing means, comprising: means for retrieving information sent to an end-user within the region by an Internet information provider; and distributing that information to a plurality of geographically distributed super-cache servers serving different geographic regions. 28. The super-cache server for storing Internet information according to claim 27, wherein the super-cache servers are distributed in a language or culture within a defined geographical area. 29. The Internet Information Storage Super Cache Server of claim 27 or 28, further comprising a data processing means for determining whether a specific portion of the retrieved information is to be stored on the Super Cache Server. 30. The Internet Information Storage Super Cache Server according to claim 27, 28 or 29, characterized by having a data processing means for determining whether a specific portion of the retrieved information is to be distributed to a plurality of geographically distributed super-memory servers. 31. An Internet caching super cache server according to claim 29 or 30, characterized in that it has a data processing means whose decision making depends on whether the information provider is located inside or outside the region. 32. An Internet Information Storage Super Cache Server according to claim 29, 30 or 31 having a data processing means designed to advise the server not to store this information in super cache memory and to distribute it to a plurality of geographically distributed super-memory servers, if end-users, the vendor and the server are in the same region. 33. An Internet Information Storage Super Cache Server according to claim 29, 30 or 31 having a data processing means designed to advise the server to store this information in super cache memory but not to distribute it to a plurality of geographically distributed super memory servers if the Internet information provider and the server are in the same region. 34. An Internet Information Storage Super Cache Server according to claim 29, 30 or 31 having a data processing means designed to advise the server not to store this information in Super Cache but only to distribute it to a plurality of geographically dispersed Super Cache Servers if the ISP is and the server is in the same region.