Multiplex communications – Channel assignment techniques – Messages addressed to multiple destinations
Reexamination Certificate
1999-05-13
2001-07-24
Olms, Douglas W. (Department: 2732)
Multiplex communications
Channel assignment techniques
Messages addressed to multiple destinations
C370S352000, C370S401000, C370S465000, C370S486000, C379S090010, C379S201060, C348S014160, C348S014160
Reexamination Certificate
active
06266339
ABSTRACT:
S
TATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT Not Applicable
BACKGROUND OF THE INVENTION
During the 1970's and 1980's, the defense industry encouraged and developed an interconnecting network of computers as a back up for transmitting data and messages in the event that established traditional methods of communication fails. University mainframe computers were networked in the original configurations, with many other sources being added as computers became cheaper and more prevalent. With a loose interconnection of computers hardwired or telephonically connected across the country, the defense experts reasoned that many alternative paths for message transmission would exist at any given time. In the event that one message path was lost, an alternative message path could be established and utilized in its place. Hence, it was the organized and non-centralized qualities of this communications system which made it appealing to the military as a backup communication medium. If any one computer or set of computers was attacked or disconnected, many other alternative paths could eventually be found and established.
This interconnection of computers has since been developed by universities and businesses into a worldwide network that is presently known as the Internet. The Internet, as configured today, is a publicly accessible digital data transmission network which is primarily composed of terrestrial communications facilities. Access to this worldwide network is relatively low cost and hence, it has become increasingly popular for such tasks as electronic mailing and weather page browsing. Both such functions are badge or file transfer oriented. Electronic mail, for instance, allows a user to compose a letter and transmit it over the Internet to an electronic destination. For Internet transfers, it is relatively unimportant how long each file transfer takes as long as it is reasonable. Though messages are routed, through no fixed path, through various interconnected computers until they reached their destination. During heavy message low periods, messages will be held at various internal network computers until the pathways cleared for new traditions. According to cut Internet transmissions are effective, but cannot be relied upon for time high incentive applications.
Web pages are collections of data including text, audio, video, and interlaced computer programs. Each web page has a specific electronic site destination which is accessed through a device known as a web server, and can be accessed by anyone through via Internet. Web page browsing allows a person to inspect the contents of a web page on a remote server to glean various information contained therein, including for instance product data, company backgrounds, and other such information which can be digitized. The remote server data is access by a local browser and the information is displayed as text, graphics, audio, and video.
The web browsing process, therefore, is a two-way data communication between the browsing user who has a specific electronic address or destination, and the web page, which also has a specific electronic destination. In this mode of operation, as opposed to electronic mail functions, responsiveness of the network is paramount since the user expects a quick response to each digital request. As such, each browsing user establishes a two-way data communication, which ties up an entire segment of bandwidth on the Internet system.
Recent developments on the Internet include telephone, video phone, conferencing and broadcasting applications. Each of these technologies places a similar real-time demand on the Internet. Real-time Internet communication involves a constant two-way throughput of data between the users, and the data must be received by each user nearly immediately after its transmission by the other user. However, the original design of the Internet to did not anticipate such real-time data transmission requirements. As such, these new applications have serious technical hurdles to overcome in order to become viable.
Products which place real-time demands on the Internet will be aided by the introduction of and updated hardware interconnection configuration, or “backbone,” which provides wider bandwidth transmission capabilities. For instance, the MCI backbone was recently upgraded to 622 megabytes per second. Regardless of such increased bandwidth, the interconnection configuration is comprised of various routers which may still not be fast enough, and can therefore significantly degrade the overall end-to-end performance of the traffic on the Internet. Moreover, even with a bandwidth capability of 622 megabytes per second, the Internet backbone can maximally carry only the following amounts of data: 414 - - - 1.5 mbs data streams; 4,859 - - - 128 kbs data streams; 21597 - - - 28.8 kbs data streams; or combinations thereof. While this is anticipated has being sufficient by various Internet providers, it will quickly prove to be inadequate for near-future applications.
Internal networks. or Intranet sites, might also be used for data transfer and utilize the same technology as the Internet. Intranets, however, are privately owned and operated and are not accessible by the general public. Message and data traffic in such private networks is generally much lower than more crowded public networks. Intranets are typically much more expensive for connect time, and therefore any related increase in throughput comes at a significantly higher price to the user.
To maximize accessibility of certain data, broadcasts of radio shows, sporting events, and the like are currently provided via Internet connections whereby the broadcast is accessible through a specific web page connection. However, as detailed above, each web page connection requires a high throughput two-way connection through the standard Internet architecture. A given Internet backbone will be quickly overburdened with users if the entire set of potential broadcasters across world began to provide broadcast services via such web page connections. Such broadcast methods through the Internet thereby prove to be ineffective given the two-way data throughput needed to access web pages and real-time data.
Furthermore, broadcasts are typically funded and driven by advertising concerns, a broadcast provided through a centralized location, such as a web page for real-time Internet connection, will be limited by a practicality to offer only nationally advertised products, such as Coke or Pepsi. Since people might be connected to this web page from around the world, local merchants would have little incentive to pay to advertise to distant customers outside of their marketing area. Local merchants, instead, would want to inject their local advertising into the data transmission or broadcasts in such a way not currently available the Internet.
There is an enormous demand for the delivery of large amounts of content to a large number of listeners. The broadcast channels of today, such as radio and TV, can only deliver a small number of channels to a large number of listeners. Their delivery mechanism is well known to customers. The broadcaster transmits programs and the listener must “tune in” at the proper time and channel to receive the desired show.
“On Demand” systems have been attempted by the cable industry. Such systems attempt to transport the program or show from a central repository (server) to the user (client) in response to his/her request. To initiate the request, the user selects from a list of candidate programs and requests that the system deliver the selected program.
The foregoing “on demand” model of content delivery places two significant requirements on the delivery system. First, there should be a direct connection between each content storage device (server) and each listener (client). The phone system is an example of such a point-to-point interconnection system. Another example of such an interconnection system is the Internet, which is also largely based on the terrestrial telecommunications
Ballister Thomas C.
Dankworth Jeffrey A.
Donahue Paul W.
Fish Laurence A.
Hinderks Larry W.
Hom Shick
Nixon & Vanderhye P.C.
Olms Douglas W.
Ryan, Esq. Robert C.
StarGuide Digital Networks, Inc.
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