Abstract:
A spectrally efficient wireless communication system that includes a plurality of base stations communicating indirectly with a plurality of wireless communications devices through a plurality of repeaters. The method can generally comprise communicating indirectly between a first base station and a wireless communication device using a first repeater and a first RF backhaul link. A control processor associated with the first base station can control a first smart antenna system. The system selectively configures the first smart antenna system to spatially isolate communications on the first RF backhaul from communications on a second RF backhaul of a second repeater.

Description:
RELATED APPLICATION INFORMATION 
     This is a continuation reissue application of U.S. Reissue Application No. 12/191,866, filed Aug. 14, 2008 now U.S. Pat. No. Re 42,605, which is a reissue application of U.S. Pat. No. 7,092,714, issued Aug. 15, 2006. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Technical Field 
     The inventive arrangements relate generally to mobile telecommunications systems and more particularly to a more efficient use of RF spectrum allocation for repeater/base station backhaul links. 
     2. Description of the Related Art 
     In a wireless telecommunication system, a base station communicates with mobile communication devices via communication channels, known in the art as ground links. By itself, a base station can only cover a limited area with ground links. This limited coverage area is referred to in the art as a cell. Other devices, such as repeaters, are sometimes used to expand the range of a base station to cover a larger geographic area. To a limited extent, non-translating repeaters extend the range that a base station can cover within the same cell. A frequency translating repeater can provide coverage within the same cell or for a separate cell from the cell of its serving base station. Repeaters are typically placed beyond the range of a base station&#39;s ground link so as to expand the base station&#39;s service to cover those cells. A group of cells covered by a base station utilizing repeaters is known a cell cluster. The present invention applies generally to the class of repeaters known as frequency translating repeaters. 
     A backhaul communication link allows the base station to communicate with the repeaters for receiving and transmitting information to/from the mobile communications devices. Some base station units and repeaters are configured with a backhaul channel that operate “in band”, i.e. in a portion of the limited frequency spectrum allocated for ground links. Other base stations may support the backhaul in a licensed or unlicensed band other than the band allocated for ground links. However, use of in unlicensed bands is typically undesirable due to interference from uncontrolled sources. Likewise availability of spectrum in a licensed band other than the band used for ground links may be limited as well as costly. In conventional systems, a different backhaul carrier frequency is required for communication between a base station and each associated frequency translating repeater. However, in systems that select the backhaul from a portion of the limited frequency spectrum allocated for ground links, such multiple backhaul frequencies reduce the available ground link bandwidth. 
     A base station may support a number of repeaters that are geographically distributed in any direction from the base station. The repeater would typically utilize a narrow beam antenna to receive downlink signals and transmit uplink signals to its serving base station. This narrow beam antenna focuses transmitted uplink signal to its serving base station and also limits interference to unintended base stations. However, the base station typically would employ an omni-directional or broad beam directional antenna that could support multiple backhauls to different geographically diverse repeaters. Because the downlink (base station-to-repeater) backhaul is transmitted in a broad direction rather than focused to the intended repeater, this broad transmission generates interference for unintended repeaters thus limiting spectral efficiency. Likewise, more power is required to be transmitted than would be necessary than if the base station antenna were using narrow beamwidth antenna. On the uplink the base station may receive a signal from an unintended repeater on the same frequency as an intended repeater. 
     Smart antenna systems are known in the art as a way for multiple communication links to improve spectral efficiency by spatially isolating those communications links from each other thus reducing interference. For example, switched beam systems are available that may consist of a plurality of narrow antenna beams arranged in a pattern to cover an omni-directional area. In switched beam systems, each antenna requires one or more dedicated transceivers and transmit amplifiers together with associated RF cabling. This arrangement permits communications between the base station and a plurality of remote transceivers to occur concurrently on the same frequency, but through different antennas. 
     Another smart antenna system is comprised of an array of antenna elements that are used to perform adaptive spatial processing. The system works by electronically forming RF beams and nulls by adjusting the phase and amplitude of each communication channel through each of the antennas in the array. Adaptive spatial signal processing applied to RF signals of each of the antenna elements permits RF energy to be focused to/from a specific direction to/from the same base station, thus reducing interference between remote communication devices on the same frequency that are spatially separated. 
     Smart antennas have been applied to support spatial division multiple access (SDMA) systems for improving spectral efficiency. These systems make use of the spatial separation of remote communication devices enabling multiple remote devices to communicate with an SDMA base station on the same frequency. SDMA can be implemented using adaptive antenna systems or switched beam systems. 
     Much study has been performed to apply SDMA to mobile networks; however, thus far in practice, SDMA systems have been limited to fixed wireless networks, such as wireless local loop (WLL) systems, due to the tremendous computation power required to track a large number of mobiles and monitoring spatial separation of those on the same frequency to prevent unacceptable degradation in signal quality. 
     Smart antennas have been applied to improve spectral efficiency by reduction of interference allowing higher frequency reuse across a mobile network. Each cell in a cell cluster may use unique RF frequencies for that cell; however, those RF frequencies may be reused in cells of another cell cluster. By reducing interference through the use of smart antennas, cells of different clusters using the same frequencies may be placed geographically closer, allowing those frequencies to be used more often, thus improving spectral efficiency. 
     Hence, in a network making use of frequency translating repeaters, what is needed is a mobile communication system that can take advantage of existing smart antenna technology for more efficient use of frequency spectrum, in particular the loss of spectral efficiency due to the use of backhaul communication channels. 
     SUMMARY OF THE INVENTION 
     The invention concerns a method and system for implementing a more spectrally efficient wireless communication system that includes a plurality of base stations communicating indirectly with a plurality of wireless communications devices through a plurality of repeaters. The method can generally comprise communicating indirectly between a first base station and a wireless communication device using a first repeater and a first RF backhaul link. A control processor associated with the first base station can control a first smart antenna system. The system selectively configures the first smart antenna system to spatially isolate communications on the first RF backhaul from communications on a second RF backhaul of a second repeater. 
     The first base station can communicate with a second wireless communication device using the second repeater and the second RF backhaul link. Alternatively, the second repeater can communicate with a second base station located in a communication cell separate from the first base station. In the latter case, the method can further include the steps of selectively controlling a second smart antenna system of the second base station for improved spectral efficiency. Specifically, this can be accomplished by selectively configuring the second smart antenna system to spatially isolate communications on the second RF backhaul link from communications on the first RF backhaul link. 
     The controlling step mentioned above can include the step of selecting from an antenna array at least one antenna element for use by the first base station in producing a directional antenna pattern having a major lobe in the direction of the first repeater. According to one embodiment, the controlling step can further comprise selecting a plurality of antenna elements from the antenna array for use by the first base station and adjusting phase and/or amplitude of RF signals received and transmitted by the plurality of antenna elements to produce the directional antenna pattern. Similarly, the controlling step can involve selecting a plurality of antenna elements from the antenna array for use by the base station and adjusting at phase and/or amplitude of RF signals received and transmitted by the plurality of antenna elements to produce a null in the directional antenna pattern. For example, the null can be selectively directed toward the second repeater. 
     According to an alternative embodiment, the invention can comprise a first base station configured for communicating indirectly with a wireless communication device using a first repeater and a first RF backhaul link. The base station can include a first smart antenna system operatively associated with the first base station. The first smart antenna system can be selectively configured by a control processor for spatially isolating communications on the first RF backhaul from communications on a second RF backhaul of a second repeater. The first base station can communicate with a second wireless communication device using the second repeater and the second RF backhaul link. Alternatively, the second repeater can be arranged for communicating with a second base station located in a communication cell separate from the first base station. 
     The second base station can comprises a second control processor for selectively controlling a second smart antenna system of the second base station. The second smart antenna system can be arranged for spatially isolating communications on the second RF backhaul link from communications on the first RF backhaul link. The control processor can select from an antenna array at least one antenna element for use by the first base station. According to one aspect of the invention, the antenna element or elements can be used to produce a directional antenna pattern having a major lobe in the direction of the first repeater. 
     According to another aspect of the invention, the control processor can select a plurality of antenna elements from the antenna array for use by the first base station. In that case, the first smart antenna system can include phase and amplitude controllers for adjusting at least one of a phase and amplitude of RF signals received and transmitted by the plurality of antenna elements to produce the directional antenna pattern. Similarly, the control processor can select a plurality of antenna elements from the antenna array for use by the first base station and the first smart antenna system can include phase and amplitude controllers for adjusting phase and/or amplitude of RF signals received and transmitted by the plurality of antenna elements to produce a null in the directional antenna pattern. The null can be selectively directed toward the second repeater. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       There are presently shown in the drawings embodiments, which are presently preferred, it being understood, however, that the invention is not limited to the precise arrangements and instrumentalities shown. 
         FIG. 1  shows a simple diagram of a mobile communications network incorporating a base station and repeaters. 
         FIG. 2  shows a base station using a switched-beam antenna array to communicate with multiple repeaters simultaneously. 
         FIG. 3  shows a base station using and adaptive antenna array to communicate with multiple repeaters simultaneously. 
         FIG. 4  shows a simplified block diagram of a base station incorporating smart antennas. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       FIG. 1  is diagram of a mobile communications network  100  incorporating base stations  102 , repeaters  104 , and mobile communication devices  106 . Generally, base stations  102  can facilitate communication among mobile communication devices  106  and between mobile communication devices  106  and other data networks, for example a public switched telephone network (PSTN)  124  or a public switched packet network (PSPN)  125 . Signals communicated to and from a PSTN or PSPN pass through a mobile telephone switching office (MTSO)  120 . Base stations  102  can receive communication signals from MTSO  120  and modulate the signals to format them for transmission through base station antennas  110 . Base stations  102  can also receive signals transmitted to base station antennas  110  from repeaters  104 , or mobile communication units  106 . These signals are communicated to the MTSO  120 . Base station controller  122  can incorporate a management application to manage the operations of a plurality of base stations  102 . 
     Base stations  102  conventionally communicate with mobile communication devices  106  via groundlinks. By itself, a base station  102  can only cover a limited area with groundlinks. This limited coverage area is referred to in the art as a cell. Hence, repeaters  104  are typically placed in cells outside the reach of a base station&#39;s groundlink to expand the base station&#39;s service to cover those cells. A group of cells covered by a base station  102  and its associated repeaters  104  is referred to in the art as a cell cluster. 
     Repeaters  104  can receive communications transmitted from a corresponding base station  102  over a backhaul link and can forward the communications to mobile communication devices  106  through antennas  114 . Likewise, repeaters  104  can receive communications transmitted from mobile communication devices  106  and forward these communications to the corresponding base station  102  over the backhaul link through antennas  115 . 
     According to a preferred embodiment of the invention, base station  102  can incorporate suitable hardware and software for implementing smart antenna processing. Such processing can permit a single frequency to be used for implementing multiple backhaul links between a base station  102  and multiple repeaters  104 , or for improved frequency re-use in a system of base stations making use of such smart antennas for implementing repeater backhaul links. Implementing multiple repeater backhaul links on the same RF frequencies, either within a cell or among a group of cells, can be highly advantageous as it increases the available bandwidth for ground link communications with mobile communication devices  106 . 
     Smart antenna processing systems as described herein can include switched-beam antenna systems, adaptive antenna processing, or any other system incorporating special processing techniques to focus antenna propagation patterns for reducing co-channel or adjacent channel interference.  FIG. 2  shows a base station  102  that incorporates a conventional switched-beam antenna array  211  for communication with mobile units  106  and repeaters  104 . The switched-beam antenna array  211  comprises 16 antenna elements, each having a 22.5 degree beamwidth, so as to cover a 360 degree propagation angle. However, those skilled in the art will appreciate that the invention is not limited in this regard. Rather, the switched-beam antenna array  211  can comprise any other desired arrangement of multiple narrow beam antennas, each with an individual antenna pattern  202  covering a narrow azimuth region. As is conventional in such systems, each switched beam antenna associated with antenna array  211  requires a dedicated transceiver and a transmit amplifier together with associated RF cabling. This arrangement permits a base station to communicate with one or more remote repeaters on the same backhaul frequency without substantial interference. It can also permit base stations in a cell cluster to have improved levels of frequency reuse by allowing a common set of backhaul frequencies to be used more often by different base stations within the cell cluster. 
     In addition to providing concurrent communications with multiple repeaters on a single backhaul frequency, the arrangement in  FIG. 2  can also be used to concurrently permit groundlink communications on the same frequency between a base station  102  and a mobile communication unit  106 . Groundlink communications with a mobile transceiver unit  106  can be switched from one antenna element to another as the mobile communication unit  106  moves from a region covered by one antenna element to a region covered by another antenna element. 
       FIG. 3  illustrates an adaptive antenna type system according to an alternative preferred embodiment in which adaptive spatial processing is used to define and steer antenna patterns  302 . The geometry of the adaptive array determines spatial resolution of the signals transmitted or received, i.e. the amount of coverage in a given spatial region. Commonly used adaptive array types are the uniform linear and circular arrays. For any given geometry, the phases and amplitudes of the currents exciting the array elements as well as the number of array elements determine the transmission power of the array in a certain direction. The phases and amplitudes of the currents on the antenna array elements can be electronically adjusted using amplitude and phase controllers such that transmitted signals in a certain direction add in phase, and maximum power is directed in that direction. Due to the reciprocal nature of adaptive antennas, this approach is also generally applicable to enhance the receive gain of an antenna array in a particular direction as well. 
     The embodiment of  FIG. 3  is similar to that of  FIG. 2  except that use of the adaptive antenna techniques as opposed to switched-beam antennas makes the angular positioning of the repeaters  104  around the base station  102  less critical. More particularly, since adaptive array processing permits provides greater flexibility in directing the antenna pattern  302  in a particular direction as compared to switched-beam antennas, there is greater flexibility in the positioning of the repeaters. Adjacent repeaters  104  need only be separated enough so that each major lobe pattern  202  does not significantly overlap any two or more repeaters using the same frequency. Adaptive spatial processing has the further advantage in this context of permitting the antenna array to create RF nulls in the direction of interfering co-channel signals operating on the same frequency. This reduces the strength of undesired signals interfering with RF received from a desired repeater. In any case the adaptive antenna array  311  can permit base station  102  to communicate with multiple repeaters  104  on a same backhaul frequency at the same time without significant interference between the signals. It can also allow multiple base stations, which are nearby to one another to communicate with multiple repeaters on a same backhaul frequency. 
     Referring to  FIG. 4 , base station  102  can have a selected number of antenna elements  110  in a switched-beam or adaptive array antenna system. Each antenna element has a dedicated receive apparatus chain comprising duplexer  520 , broadband digital transceiver  540 , and a channelizer/combiner  550  (including analog to digital converter). A suitable interface such as time division multiplex bus  560  can be provided for facilitation communications between the dedicated receive apparatus chain and digital signal processor board (DSP)  570 . The DSP  570  can provide signal processing, for example beam forming (in the case of adaptive array processing), antenna selection (in the case of switched-beam antenna processing), signal modulation, signal calibration, etc. DSP  570  can include a plurality of individual digital signal processors for performing these tasks for each channel. 
     For transmission, each antenna element  110  has a dedicated transmit apparatus chain comprising duplexer  520 , multi-carrier power amplifier (MCPA)  530 , broadband digital transceiver  540 , combiner  551  (including digital to analog coverter), time division multiplex bus  560 , DSP  570 , and associated connectors inclusive. Similar to its function on the receive path, DSP  570  can perform antenna switching or adaptive array beam forming. DSP  570  can also apply any other desired signal processing to the transmit signals, for example switching transmit signals between antenna elements when transmitting through a switched-beam antenna array. 
     A control processor  580  can be provided for controlling the operation of the major system components including the bus  560 , and each channelizer  550 , combiner  551 , broadband digital transceiver  540 , MCPA  530 . The control processor can communicate with these system components using a control bus  581 . Where a switched-beam antenna system is used, the control processor  580  can select one or more antennas  110  to operate exclusively with each of the plurality of repeaters  104 , where each antenna or combination of antennas can having an antenna pattern  202  comprising a major lobe exhibiting gain in a direction of one of the repeaters  104 . RF signals communicated to and from the base station  102  for each of the plurality of repeaters  104  can be processed separately in one of the plurality of the transceivers  540  associated with each of the antennas. 
     Alternatively, where an adaptive array approach is used, the control processor  580  can adjusts a phase, amplitude or both for RF signals associated with all of the plurality of antennas of the antenna array. These operations can be performed in the channelizer and combiner blocks or within DSP  570 . In this way the system can combine the RF signals to create an antenna pattern  302  comprising a major lobe exhibiting gain in a direction of one of the plurality of repeaters  104 . The control processor  580  can also adjust a phase and/or amplitude of RF signals associated with each of the plurality of antennas  110  of the antenna array for combining the RF signals to create an antenna pattern comprising nulls in the direction of at least one other of the plurality of repeaters concurrently operating on the common RF carrier frequency. 
     It should be understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application. The invention can take many other specific forms without departing from the spirit or essential attributes thereof for an indication of the scope of the invention.