Telecommunications – Radiotelephone system – Zoned or cellular telephone system
Reexamination Certificate
2000-09-29
2003-02-18
Appiah, Charles N. (Department: 2682)
Telecommunications
Radiotelephone system
Zoned or cellular telephone system
C455S446000
Reexamination Certificate
active
06522885
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Technical Field
The present invention relates, in general, to an improved method and system to be utilized with wireless communication systems having cellular architectures. In particular, the present invention relates to an improved method and system, to be utilized with wireless communication systems having cellular architectures, and which assign groups of channels to individual cells within the system in such a fashion that system-wide channel interference is minimized over some defined geographical area.
2. Description of the Related Art
The present invention is related to wireless communication systems, and, in particular, to wireless communication systems having a cellular architecture (e.g., cellular telephony, Personal Communication Systems, or Global System for Mobil Communication). Wireless communication refers to the fact that transmission between sending and receiving stations occurs via electromagnetic radiation not guided by any hard physical path (e.g., by microwave link.) Cellular architecture refers to the fact that the wireless system effects service over an area by utilizing a system that can be pictographically represented as a cellular grid.
Wireless cellular communication is the latest incarnation of a technology that was originally known as mobile telephone systems. Early mobile telephone system architecture was structured similar to television broadcasting. That is, one very powerful transmitter located at the highest spot in an area would broadcast in a very large radius. If a user were in the useable radius, then that user could broadcast to the base station and communicate by radiotelephone to the base station. However, such systems proved to be very expensive for the users and not very profitable to the communication companies supplying such services. The primary limiting factor of the original mobile telephone systems was that the number of channels available for use was limited due to severe channel-to-channel interference within the area served by the powerful transmitter. Thus, a problem arose as to how to provide more channels within the service area.
Counterintuitively, engineers discovered that channel-to-channel interference effects within the service area were not due solely to the distance between stations communicating with the base transmitter (which intuitively would seem to give rise to the interference), but were also inversely related to the transmitter power (radius) of the area being served by the transmitter. Engineers found that by reducing the radius of an area by fifty percent, service providers could increase the number of potential customers in an area fourfold. It was found that systems based on areas one-kilometer in radius would have one hundred times more channels than systems based on areas ten-kilometers in radius. Speculation led to the conclusion that by reducing the radius of areas to a few hundred meters, the number of calls that could be served by each cell could be greatly increased.
Thus, reducing the power of the central transmitter allowed a significant increase in the number of available channels by reducing channel-to-channel interference within an area. However, as the power of the central transmitter was reduced, the serviceable area was also reduced. Thus, although reducing transmission power increased the number of available channels, the small service area provided by such reduced power did not make such radio telephone systems attractive communication options for many users. Thus, a problem arose relating to how to utilize the discovery that smaller cell sizes increased available channels in a fashion that would provide service attractive to users.
This problem was solved by the invention of the wireless cellular architecture concept. The wireless cellular architecture concept utilizes geographical subunits called “cells” and is buttressed by what is known as a frequency reuse concept. A cell is the basic geographic unit of a cellular system. Cells are base stations (a base station consists of hardware located at the defining location of a cell and includes power sources, interface equipment, radio frequency transmitters and receivers, and antenna systems) transmitting over small geographic areas that are represented as hexagons. Each cell size varies depending on the landscape. The term “cellular” comes from the honeycomb shape of the areas into which a coverage region is divided. Because of constraints imposed by natural terrain and man-made structures, the true shape of cells is not a perfect hexagon, but such shape serves as an effective tool for design engineering.
Within each cell a base station controller talks to many mobile subscriber units at once, utilizing one defined transmit/receive communications channel per mobile subscriber unit. A mobile subscriber unit (a control unit and a transceiver that transmits and receives wireless transmissions to and from a cell site) uses a separate, temporary wireless channel to talk to a cell site. Transmit/receive communication channels utilize a pair of frequencies for communication—one for transmitting from the cell site base station controller, named the forward link, and one frequency for the cell site to receive calls from the users, named the reverse link. Both the forward and reverse link must have sufficient bandwidth to allow transmission of user data.
The frequency reuse concept is what made wireless cellular communications a viable reality. Wireless communication is regulated by government bodies (e.g., the Federal Communications Commission.) Government bodies dictate what frequencies in the wireless spectrum can be utilized for particular applications. Consequently, there is a finite set of frequencies available for use with cellular communications. The frequency reuse concept is based on assigning to each cell a group of radio channels used within a small geographic area (cell). Adjacent cells are assigned a group of channels that is completely different from any neighboring cell. Thus, in the frequency reuse concept there are always buffer cells between two cells utilizing the same set of frequencies. The cells are sized such that it is not likely that two cells utilizing the same set of frequencies will interfere with each other. Thus, such a scheme allows “frequency reuse” by non-adjacent cells.
Since each contiguous cell utilizes different frequencies, the ability for such a system to supply continuous service across a cell grid requires that a call-in-progress be switched to a new transmit/receive channel as a user transits from one cell into another. That is, since adjacent areas do not use the same wireless channels, a call must either be dropped or transferred from one wireless channel to another when a user crosses the line between adjacent cells. Because dropping the call is unacceptable, the process of “handoff” was created. Handoff occurs when the mobile telephone network automatically transfers a call from wireless channel to wireless channel as a mobile subscriber unit crosses adjacent cells.
Handoff works as follows. During a call, a moving mobile subscriber unit is utilizing one voice channel. When the mobile unit moves out of the coverage area of a given cell site, the reception becomes weak. At this point, the base station controller in use requests a handoff. The system switches the call to another different frequency channel in a new cell without interrupting the call or alerting the user. The call continues as long as the user is talking, and generally the user barely notices the handoff.
The foregoing ideas of cells, frequency reuse, and handoff constituted the invention of the cellular concept. The invention of the cellular concept made the idea of wireless cellular communications a viable commercial reality.
As noted previously, the frequency reuse concept requires assigning groups of cells different groups of frequencies. In practice, in order to do the assignment engineers first assume an ideal hexagon layout of the network and apply an ideal frequency assignment pattern “as if” the d
Djurkovic Roderick
Tang Yuqiang
Appiah Charles N.
Crane John D.
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