Base station hand-off mechanism for cellular communication...

Telecommunications – Radiotelephone system – Zoned or cellular telephone system

Reexamination Certificate

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Details

C455S442000, C455S440000, C455S439000

Reexamination Certificate

active

06240290

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates in general to cellular communication systems, and is particularly directed to a new and improved communication control mechanism for controlling the hand-off of frequency channels through which communications are conducted between base stations of adjacent cells and a mobile transceiver as the mobile transceiver moves between those cells.
BACKGROUND OF THE INVENTION
Wireless (cellular) communication service providers customarily supply wireless communication capability to (mobile) subscribers located within a geographic area, through the use of a relatively limited number of communication channels. In order to optimize coverage within the geographical area of interest, the service provider typically subdivides the area into a cluster or multiple clusters of base stations. In addition, in order to minimize interference from adjacent or nearby cells, the service provider may employ some form of frequency reallocation (or reuse) scheme, such as that described in the U.S. Pat. No. 4,144,496, as a non-limiting example.
In such a spatially distributed or ‘cluster’ network architecture, a fixed number of sectors (i) are served by a cluster of (k) base stations. This has the effect of subdividing the number of available channels N by the product of i and k, namely by (i*k). Unfortunately, with today's expanding traffic, particularly in densely populated urban areas, service providers face the eventuality of running out of channels to meet demand.
One solution is to construct more base stations and reduce power levels—which is both hardware intensive and expensive. Another scheme is to reuse channels in time (TDMA) or in frequency (CDMA). Other approaches, such as described in the above-referenced patent, include dynamic allocation of frequencies or channels to accommodate channel demand. Initially, the relatively poor efficiency of frequency allocation schemes was not a significant problem as the demand was small and the number of available channels was more than adequate. However, as demand increased, new channel assignment and frequency reuse strategies were developed.
Such schemes have included sectorization of cells to minimize interference, and dynamic allocation or ‘borrowing’ of channels from other cells with a cluster, to meet unbalanced demand within the cluster. A new and promising approach is to spatially separate channels using switched or steered antenna beams. The overall objective of any strategy is to maximize the number of channels available, subject to an acceptable carrier (C) to interference (I) ratio, with the current industry standard being a figure of merit (or C/I ratio) of 18 dB.
Sectorization is a technique that uses fixed beams formed by directional antenna (phased) arrays installed at the base stations to divide the cell into an integral number of smaller cells. This technique serves to reduce interference to the base station, by attenuating channel interference to those mobile subscribers who are not located in that sector's beam. It also reduces interference to the mobile subscriber, by attenuating channel interference from base stations transmitting in a direction that is predominately away from the location of the mobile subscriber. However, as the number of sectors increases, the number of channels per sector necessarily decreases, thereby reducing the figure of merit. Ideally, at the time of system installation, there would be no sectorization, which would greatly increase system capacity.
Regardless of the channel allocation mechanism employed, whenever a mobile subscriber moves from one cell to another, it is necessary to change the frequency channel used to conduct communications with the base station in the ‘old’ cell from which the mobile transceiver is departing to a new frequency channel used to conduct communications with the base station in the ‘new’ cell which the mobile transceiver is entering.
Techniques using steered beam antennas have unique problems accomplishing this handoff between cells. In particular, the ‘new’ cell has the problem of where to point its narrowbeam antenna. The mobile subscriber is waiting on transmission from the new base station to transmit on the new frequency. If the new base station points the beam in the wrong direction, then the mobile subscriber sees no signal, does not synchronize and does not transmit. After the elapse of a prescribed period of time with no communication, the call will be dropped. The problem then is for the new base station to determine the correct beam to the mobile subscriber.
One mechanism for performing such frequency channel reuse/reallocation (or hand-off from the previous base station to the new base station) is described in the U.S. Patent to Forssen et al, U.S. Pat. No. 5,615,409. This scheme involves the base station using an ‘intermediate’ channel to determine the direction of the mobile transceiver relative to it. It then assigns the mobile transceiver to an available narrowbeam channel. Because this technique requires what could otherwise be used for a regular communication channel be employed as an intermediate construct channel to determine the direction of the mobile transceiver, it necessarily reduces the number of available precious resources (channels).
SUMMARY OF THE INVENTION
In accordance with the present invention, this drawback is effectively obviated by a channel hand-off communication control mechanism that uses the very channels that are employed for communications between base stations of adjacent cells and a mobile transceiver as the mobile transceiver moves between those cells, to locate the mobile transceiver relative to the base stations, so that the acquiring base station may readily place a narrowbeam channel on the mobile transceiver at hand-off. Each base station employs a phased array antenna, which allows the base station to controllably define its antenna coverage pattern with respect to any mobile transceiver, so as to minimize interference from one or more other transceivers, and thereby reduce frequency reuse distance.
Pursuant to a first embodiment of the invention, when the quality of a narrowbeam link between the mobile subscriber and an already acquired cell base station indicates that the mobile transceiver is approaching a cell boundary with a new cell, the already acquired base station will initiate a hand-off sequence with the acquiring base station in the new cell to which the mobile subscriber is moving. For this purpose, the current base station will forward a message to the new base station that a channel hand-off is to commence. This hand-off initiating message will contain the identification of the communication channel currently employed by the mobile transceiver.
In response to this message, the acquiring base station employs one of the antenna elements of its phased array antenna to transmit an omnidirectional burst on a new communication channel to which mobile transceiver is to tune itself for conducting communications with the acquiring base station at hand-off, when the mobile transceiver enters cell. In response, this burst signal on the new channel, the mobile transceiver transmits a reply signal on the new channel, which is processed by the acquiring base station to derive a steering vector representative of the direction of the mobile transceiver relative to the new base station.
The new base station employs this derived steering vector to adjust the directivity pattern of its phased array antenna, so as to place a narrowbeam pattern of the new communication channel in the direction of mobile transceiver, completing the hand-off. The new base station proceeds to conduct narrow beam communications with the mobile transceiver on the new communication channel. Using its ability to control the directivity of the narrowbeam lobe by way of its phased array antenna, the new base station continues to communicate with and track the mobile transceiver as long as the mobile transceiver is located in the new cell.
In a second embodiment of the invention, the acquiring base

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