RU95121152A - BROADBAND WIRELESS SYSTEM AND NETWORK STRUCTURE FOR BROADBAND / NARROW-BAND SERVICE WITH OPTIMAL STATIC AND DYNAMIC FREQUENCY / FREQUENCY - Google Patents

Claims (30)

1. A method for delivering a variety of broadband / narrowband services to an end user of a system in a wireless broadband communication system, characterized in that the end-user equipment is connected to the communication system by a wireless transmission medium using a spread spectrum transmission and time division multiplexing to an access antenna; end-user equipment, including a wireless repeater in the end-user premises, has repeater capabilities to relay spread spectrum over the satellite – earth link and time division multiplexing from the access antenna and transmit spread spectrum over the earth – satellite link and temporal multiplexing to the access antenna ; the available spectrum is divided into special channel / subchannel components intended for specific end-user services, and the distribution of subchannels and subchannels to provide the frequency band required for a particular application system.  2. The method of claim 1, wherein the step of partitioning includes determining asymmetric broadband channels and bidirectional symmetric narrowband channels by allocating channels to specific service categories, and subdividing the channels into subchannels of a particular frequency band, each of which can be combined to assign a specific service .  3. The method of claim 2, wherein the partitioning step includes selecting subchannels within the channels to match the band requirements of the communication types that need to be provided.  4. The method according to p. 3, in which the stage of splitting further includes mapping a single service for several subchannels selected to match the requirements for the frequency band of this one service.  5. The method of claim 4, wherein the subchannels are allocated based on the type of communication requirements for modulation by selecting CDMA modulation for narrowband and WU for broadband communication.  6. The method according to p. 5, in which the channels are distributed according to classes of service to meet the requirements of static and variability.  7. The method according to claim 6, in which the channel is encoded by a modulation scheme by using CDMA to optimize reuse of a narrow frequency band and optimization of uses in the broadband mode is carried out by means of compression and use of the VU scheme.  8. The method according to claim 7, in which maximizing the use of the channel while ensuring a uniformly distributed quality of services is carried out by changing the bit rate on the subchannel to match the requirements of the program, while for all subchannels in the channel, the average bit rate is maintained.  9. A communication network for providing broadband and narrowband communication modes for wireless connection of a network and end users, including a communication network comprising asynchronous transfer means and synchronous transfer means, characterized in that it includes at least one communication node connected to asynchronous means transfer and synchronous transfer medium, and the access node, which in turn is connected to the microport, including an antenna for emitting radio signals to the receiving antenna of the end user, comm a unique circuit for communication and for providing routing control of a communication network, including asynchronous and synchronous means of transfer; a communication node connected to asynchronous and synchronous means of transfer and to an access node, which in turn is connected to a microport for emitting radio signals that must be received by the end user access port, a communication network proportionally distributing communication channels and subchannels for specific types of communication, including , a communication node, measuring the channel occupancy from the number of channels controlled by the communication system, and distributing the network communication channels for their operation as access communication channels; a channel distribution server connected to a communication node for estimating blocking probabilities by service class and for identifying channels that must be transferred from one service class to another in order to comply with service requirements; access node combining and dividing channels for coordination with the mapping of types of communication over the channels; a microport having a radiation device for transmitting and receiving signals over radio equipment and for communicating wired network channels with a radio frequency channel; an access port connecting the received radio signals with the wired and wireless equipment of the end user and transmitting radio signals from the end user to the microport.  10. The network of claim 9, further comprising an access node dividing the channels into a fixed plurality of subchannels, each of the plurality of subchannels having a variable frequency band, the plurality of subchannels having a fixed full frequency band, and the middle band of each subchannel of the plurality of subchannels .  11. The network of claim 9, further comprising a radiation device comprising a partitioned antenna with three sectors and radiating three channel levels for interactive types of broadcast video communications, for interactive video-on-demand and narrowband modes of communication, and a distribution server a channel that controls the transfer of channel assignments from one level to another.  12. The network according to claim 10 or 11, further comprising an access node connected to the communication node through a ring of a synchronous optical communication network.  13. The network of claim 12, further comprising an antenna device for receiving satellite signals to support communication modes of broadcast video, multimedia communications, and information communications.  14. The method of allocating the frequency spectrum to meet the requirements for the frequency band of many types of communication in the communication network to provide broadband and narrowband communication modes for wireless connection of the network and end users, characterized in that it includes periodic setting of the redistribution time, static distribution of channels to satisfy the requirements for service based on a known predetermined distribution maintained by recording time and data during redistribution division, the dynamic allocation of channels to meet the real-time service requirements on the basis of immediate service requests and dynamic allocation, which has priority over the static distribution.  15. The method according to p. 14, in which the static distribution includes the stage of determining the day of the week and time of day, marking the time of redistribution, redistribution of channels at the time of redistribution to meet the expected requirements for servicing a predetermined static distribution of the type of communication for the day of the week and time of day .  16. The method of claim 14, wherein the dynamic allocation includes the steps of determining the free capacity of the channels, determining the number of channels assigned to the classes of service with a higher priority, determining whether the number of free channels exceeds the number of channels assigned to the classes of service with a higher priority by number of blocks, definitions of channels to be assigned to a different class of service.  17. The method according to p. 16, including determining whether there is blocking in the channels that must be assigned to a different class of service, and the redistribution of unused channels to a different class of service.  18. The method according to p. 17, including the creation of a waiting period before the subsequent dynamic distribution.  19. The method according to p. 17, in which the redistribution of channels from one class of service to another class of service is based on the increment of an integer number of channels.  20. The network according to claim 9, including a signal transmission server for providing communication modes for transmitting a signal to end-user devices.  21. The network of claim 9, including a server that performs billing, organizing, supporting, and providing for end-users a common bill for all services provided by broadband and narrowband forms of service communications.  22. The network according to claim 9, including a security server designed to service covert confirmation of access rights and prevent unauthorized access.  23. The network of claim 9, comprising a user service profile server for storing end-user data, including subscriber privileges.  24. The network of claim 9, comprising a user registration server for tracking real-time data regarding a user's location and data related to a service area.  25. The network according to claim 9, including a signal transmission server, an IAVT server, a security server, a server for billing, organizing, supporting and providing a server, a user service profile server, a user location and registration server, and a channel distribution server that are all integrated within the system to provide comprehensive services through end-to-end network transmission to end users throughout the range of services.  26. The network according to claim 10 or 11, further comprising an access node connected to the communication node by directional communication in the microwave range.  27. The network of claim 10 or 11, further comprising an access node connected to the communication node by directional communication in the IR spectrum.  28. The network of claim 10 or 11, further comprising an access node connected to the star communication node.  29. The network of claim 10 or 11, further comprising expanding the available modes of communication by adding interactive modes of communication by creating interactive Earth-satellite links.  30. The network of claim 10 or 11, further comprising adding new types of communication by using compression methods to compress existing types of communication into a subset of channels to free channels for new types of communication.