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    • 专利摘要:
    A wireless communication system employs directive antenna arrays and knowledge of position of users to form narrow antenna beams to and from desired users and away from undesired users to reduce co-channel interference. By reducing co-channel interference coming from different directions, spatial filtering with antenna arrays improves the call capacity of the system. A space division multiple access (SDMA) system allocates a narrow antenna beam pattern to each user in the system so that each user has its own communication channel free from co-channel interference. The position of the users is determined using geo-location techniques. Geo-location can be derived via triangulation between cellular base stations or via a global positioning system (GPS) receiver. The system can be optimized by applying partially adaptive processing algorithms, which are seeded by geo-location data.
    公开号:US20010003443A1
    申请号:US09/188,835
    申请日:1998-11-09
    公开日:2001-06-14
    发明作者:Scott R. Velazquez;Steven R. Broadstone;Alice M. Chiang
    申请人:Scott R. Velazquez;Steven R. Broadstone;Alice M. Chiang;
    IPC主号:H04W16-28
    专利说明:
    [0001] This application is a continuation of International Application Number PCT/US97/18780 filed on Oct. 10, 1997, which is a continuation-in-part of U.S. application Ser. No. 08/729,289 filed on Oct. 10, 1996, the entire teachings of which are both incorporated herein by reference in their entirety. [0001] BACKGROUND OF THE INVENTION
    [0002] At present, the communications spectrum is at a premium, with projected high capacity requirements of Personal Communication Systems (PCS) adding to the problem. Although all modulation techniques for wireless communications suffer capacity limitations due to co-channel interference, spread spectrum, or Code Division Multiple Access (CDMA), is a modulation technique which is particularly suited to take advantage of spatial processing to increase user capacity. Spread spectrum increases signal bandwidth from R (bits/sec) to W (Hz), where W>>R, so multiple signals can share the same frequency spectrum. Because they share the same spectrum, all users are considered to be co-channel interferers. Capacity is inversely proportional to interference power, so reducing the interference increases the capacity. [0002]
    [0003] Some rudimentary spatial processing can be used to reduce interference, such as using sector antennas. Instead of using a single omnidirectional antenna, three antennas each with a 120 degree sector can be used to effectively reduce the interference by three, because, on average, each antenna will only be looking at ⅓of the users. By repeating the communications hardware for each antenna, the capacity is tripled. [0003]
    [0004] Ideally, adaptive antenna arrays can be used to effectively eliminate interference from other users. Assuming infinitesimal beamwidth and perfect tracking, adaptive array processing (AAP) can provide a unique, interference-free channel for each user. This example of space division multiple access (SDMA) allows every user in the system to communicate at the same time using the same frequency channel. Such an AAP SDMA system is impractical, however, because it requires infinitely many antennas and complex signal processing hardware. However, large numbers of antennas and infinitesimal beamwidths are not necessary to realize the practical benefits of SDMA. [0004]
    [0005] SDMA allows more users to communicate at the same time with the same frequency because they are spatially separated. SDMA is directly applicable to a CDMA system. It is also applicable to a time division multiple access (TDMA) system, but to take full advantage of SDMA, this requires monitoring and reassignment of time-slots to allow spatially separated users to share the same time-slot simultaneously. SDMA is also applicable to a frequency division multiple access (FDMA) system, but similarly, to take full advantage of SDMA, this requires monitoring and reassignment of frequency-slots to allow spatially separated users to share the same frequency band at the same time. [0005]
    [0006] In a cellular application, SDMA directly improves frequency re-use (the ability to use the same frequency spectrum in adjoining cells) in all three modulation schemes by reducing co-channel interference between adjacent cells. SDMA can be directly applied to the TDMA and FDMA modulation schemes even without re-assigning time or frequency slots to null co-channel interferers from nearby cells, but the capacity improvement is not as dramatic as if the time and frequency slots are re-assigned to take full advantage of SDMA. [0006] SUMMARY OF THE INVENTION
    [0007] Instead of using a fully adaptive implementation of SDMA, exploitation of information on a users' position changes the antenna beamforming from an adaptive problem to deterministic one, thereby simplifying processing complexity. Preferably, a beamformer uses a simple beam steering calculation based on position data. Smart antenna beamforming using geo-location significantly increases the capacity of simultaneous users, but without the cost and hardware complexity of an adaptive implementation. In a cellular application of the invention, using an antenna array at the base station (with a beamwidth of 30 degrees for example) yields an order of magnitude improvement in call capacity by reducing interference to and from other mobile units. Using an antenna array at the mobile unit can improve capacity by reducing interference to and from other cells (i.e., improving frequency reuse). For beamforming, the accuracy of the position estimates for each mobile user and update rates necessary to track the mobile users are well within the capabilities of small, inexpensive Global Positioning System (GPS) receivers. [0007]
    [0008] In general, the present invention is a communication system with a plurality of users communicating via a wireless link. A preferred embodiment of the invention is a cellular mobile telephone system. Each user has a transmitter, receiver, an array of antennas separated in space, a device and method to determine its current location, hardware to decode and store other users' positions, and beamformer hardware. The beamformer uses the stored position information to optimally combine the signals to and from the antennas such that the resulting beam pattern is directed toward desired users and away from undesired users. [0008]
    [0009] An aspect of the invention uses a deterministic direction finding system. That system uses geo-location data to compute an angle of arrival for a wireless signal. In addition, the geo-location data is used to compute a range for the wireless signal. By using the determined angle of arrival and range, a system in accordance with the invention can deterministically modify the wireless signal beam between transceivers. [0009] BRIEF DESCRIPTION OF THE DRAWINGS
    [0010] The foregoing and other objects, features and advantages of the invention, including various novel details of construction and combination of parts will be apparent from the following more particular drawings and description of preferred embodiments of the communication system using geographic position data in which like references characters refer to the same parts throughout the different views. It will be understood that the particular apparatus and methods embodying the invention are shown by way of illustration only and not as a limitation of the invention, emphasis instead being placed upon illustrating the principles of the invention. The principles and features of this invention may be employed in various and numerous embodiments without departing from the scope of the invention. [0010]
    [0011] FIG. 1 is a schematic diagram of a cellular communication system. [0011]
    [0012] FIG. 2 is a schematic block diagram of components in a base station and a mobile unit of FIG. 1. [0012]
    [0013] FIG. 3 is a schematic diagram of a general adaptive antenna array. [0013]
    [0014] FIG. 4 is a schematic diagram of a mobile-to-base communications link in cellular communications using AAP SDMA. [0014]
    [0015] FIG. 5 is a schematic diagram of a base-to-mobile communications link in cellular communications using AAP SDMA. [0015]
    [0016] FIG. 6 is a schematic diagram of a general SDMA communications system employing geo-location techniques. [0016]
    [0017] FIG. 7 is a schematic block diagram of two communicating users of FIG. 6. [0017]
    [0018] FIG. 8 is a flow chart of a method of operating a cellular telephone system using geo-location data. [0018]
    [0019] FIG. 9 is a schematic diagram of a cellular telephone system using geo-location data. [0019]
    [0020] FIG. 10 is a schematic block diagram of a steering circuit. [0020]
    [0021] FIG. 11 is a schematic block diagram of a nulling circuit. [0021]
    [0022] FIG. 12 is a schematic block diagram of a receiver module for a mobile unit beamformer. [0022]
    [0023] FIG. 13 is a schematic block diagram of a transmitter module for a mobile unit beamformer. [0023]
    [0024] FIG. 14 is a schematic block diagram of a receiver module for a base station beamformer. [0024]
    [0025] FIG. 15 is a schematic block diagram of a transmitter module for a base station beamformer. [0025]
    [0026] FIG. 16 is a schematic block diagram of a preferred base station employing real-valued FIR filtering at IF. [0026]
    [0027] FIG. 17 is a schematic block diagram of a preferred base station employing complex-valued FIR filtering at base band. [0027]
    [0028] FIG. 18 is a schematic block diagram of a beamshaping circuit based on an adaptive-array processing algorithms. [0028] DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION
    [0029] FIG. 1 is a schematic diagram of a general land-based cellular wireless communications system. The geographic area serviced by this communications system [0029] 1 is divided into a plurality of geographic cells 10, each cell 10 having a respective geographically fixed base station 20. Each cell 10 can have an arbitrary number of mobile cellular units 30, which can travel between and among the cells 10.
    [0030] FIG. 2 is a schematic block diagram of components in a base station [0030] 20 and a mobile unit 30 of FIG. 1. As shown, each base station 20 includes a transceiver 210 having a transmitter 212 and a receiver 214, control hardware 220, and a set of antennas 25 to communicate with a plurality of mobile units 30. The mobile units are free to roam around the entire geographic service area. Each mobile unit 30 includes a transceiver 310 having a transmitter 312 and a receiver 314, control hardware 320, a handset 8, and an antenna or antennas 35 to allow for simultaneous sending and receiving of voice messages to the base station 20. The base station 20 communicates with a mobile telecommunications switching office (MTSO) 5 to route the calls to their proper destinations 2.
    [0031] The capacity of a spread spectrum cellular communication system can be expressed as:[0031]
    [0032] where W is the bandwidth (typically 1.25 MHz); [0032]
    [0033] R is the data rate (typically 9600 bps); [0033]
    [0034] E[0034] b/No is the energy-to-noise ratio (typically 6 dB);
    [0035] D is the voice duty-cycle (assumed to be 0.5); [0035]
    [0036] F is the frequency reuse (assumed to be 0.6); [0036]
    [0037] G is the number of sectors per cell (assumed to be 1, or omnidirectional); and [0037]
    [0038] N is the number of simultaneous users. [0038]
    [0039] As such, a typical cell can support only about 25-30 simultaneous calls. Space division multiple access (SDMA) techniques can be used to increase capacity. [0039]
    [0040] The capacity improvement by using an adaptive array at the base station [0040] 20 in the mobile-base link is summarized below in Table I. The results are valid for various antenna beamwidths at a fixed outage probability of 10−3. TABLE I Base Station Antenna Beamwidth vs. Call Capability in Mobile-to-Base LinkBeamwidth (degrees) Capacity (calls/cell) 360 (omni)  31 120  75 60 160 30 320
    [0041] FIG. 3 is a schematic diagram of an M-element adaptive antenna array and beamformer. Each element has N adaptive linear filters (ALFs) [0041] 55, where N is the number of users per cell. Each of the ALFs 55 are adapted in real time to form a beam to and from each mobile unit 30. The ALFs 55 use a variety of techniques to form an optimal beam, such as using training sequences, dynamic feedback, and property restoral algorithms. Preferably, the ALFs 55 are single chip adaptive filters as described in U.S. Pat. No. 5,535,150 to Chiang, the teachings of which are incorporated herein by reference.
    [0042] The M-element array is capable of nulling out M-[0042] 1 co-channel interference sources. However, all the users in a CDMA cell share the same frequency band and therefore, are all co-channel interferers in the mobile-to-base link. Because the number of users, N, far exceeds the number of antennas, M, subspace methods of direction-of-arrival estimation are not applicable. Instead, a Constant Modulus Algorithm (CMA) adaptive beamforming approach is more applicable.
    [0043] For the base-to-mobile link, the co-channel interferers are the neighboring base stations. Conceivably, the number of antennas in the adaptive array at the mobile could be approximately the same as the number of neighboring base stations, so subspace methods of direction-of-arrival estimation may be applicable to null out the interfering base stations. The computational complexity of both types of AAP algorithms is approximately equal. [0043]
    [0044] The majority of the computational complexity incurred by using AAP in a cellular system is due to covariance formulation and copy processing. The covariance is a sum of a sequence of matrices, each of which is an outer product of complex array samples. Each term of this outer product is a complex product. The computation requires on the order of K[0044] 2 computations, where K is the number of antennas. Using the covariance, the AAP algorithm computes the antenna weight vector, which is applied to the received signal vectors. This is a matrix inversion, which copies the desired signal. The covariance is updated periodically, and each desired signal is copied in real time.
    [0045] Overall about ½to ⅔of the computational complexity incurred by using AAP SDMA in a cellular system is due to the covariance formulation alone, and the remaining complexity resides in the matrix inversion for copy weight generation. The complexity, size, power consumption, and cost of implementing AAP SDMA has thus far prevented it from gaining acceptance. In preferred embodiments, the present invention achieves substantially the same results as a fully adaptive implementation of SDMA but with significantly less hardware complexity, smaller size, lower power consumption, and lower cost. [0045]
    [0046] FIG. 4 is a schematic diagram of a mobile-to-base communication link in a cellular communications system using AAP SDMA. Illustrated are the antenna array SDMA transmission beam patterns [0046] 150 from the mobile units 30 to the base station 20 along a central direction 155. Also illustrated is interference 170 which would exist without SDMA.
    [0047] Assuming the base station [0047] 20 employs a multi-antenna adaptive array while the mobile unit 30 uses a single omnidirectional antenna, in the reverse channel (uplink, or mobile-to-base), the base station array reduces interference from other users both in-cell and out-of-cell, as illustrated in FIG. 4, by pointing its reception beam only towards the desired mobile unit 30.
    [0048] For a 120 degree beamwidth, about ⅓of the mobile units 30 in a cell [0048] 10 are visible to the array, so the capacity is approximately tripled. Similarly, for a 30 degree beamwidth, about {fraction (1/12)}of the mobile units 30 in a cell 10 are visible to the array, so the capacity is increased by a factor of approximately 12.
    [0049] Assuming that both the base station [0049] 20 and the mobile unit 30 employ multi-element antenna arrays, for the reverse channel, this system significantly reduces interference from out-of-cell mobile transmitters, because they are forming beams toward their own base station 20. Ideally, this would improve the frequency reuse, F, from 0.6 to nearly 1.0, thereby increasing the capacity by nearly ⅔. Simulations on such a system show that a frequency re-use factor of F=0.8826 with a 60 degree beamwidth from the mobile unit improves capacity by 47% over the omnidirectional case (F=0.6).
    [0050] Improvement due to adaptive arrays on the mobile units [0050] 30 are not as dramatic as those achieved with adaptive arrays at the base station 20. In addition, complexity, size, power, and cost can make the application of antenna arrays in mobile units 30 impractical for most situations. The reduction in inter-cell interference afforded by adaptive arrays in mobile units 30 may, however, be critical in high-traffic environments and for mobile units 30 near the cell boundaries where interference is the greatest.
    [0051] FIG. 5 is a schematic diagram of a base-to-mobile communication link in a cellular communications system using AAP SDMA. Assuming the base station [0051] 20 employs a multi-antenna array while the mobile unit 30 uses a single omnidirectional antenna, in the base-to-mobile link, the base station 20 antenna array reduces interference to other users both in-cell 180 and out-of-cell 175, as illustrated in FIG. 4. Results for this channel for various beamwidths are summarized below in Table II. TABLE II Base Station Antenna Beamwidth vs. Call Capacity in Base-to-Mobile ChannelBeamwidth (degrees) Capacity (callscell) 360 (omni)  30 75 (5 antennas) 120 55 (7 antennas) 165
    [0052] Assuming that both the base station [0052] 20 and the mobile units 30 employ multi-element adaptive antenna arrays, for the forward channel, this system significantly reduces interference from out-of-cell base stations, because the mobile units 30 are forming beams toward their own base station 20. As in the reverse channel, ideally, this would improve the frequency re-use, F, from 0.6 to nearly 1.0, thereby increasing the capacity by nearly ⅔.
    [0053] FIG. 6 is a schematic diagram of a general SDMA communications system employing geo-location techniques. As illustrated, a first user [0053] 301 and a second user 302 are in communication. The first user 301 computes the direction of the desired user 302 and abeam pattern 314 is formed along the desired direction 316. In addition to desired users 302, the first user 301 wants to avoid projecting a beam in the direction 317 of an undesired user 303. Furthermore, the first user 301 wants to avoid receiving a beam from any direction other than the desired direction 316. These goals are accomplished by utilizing a narrow directional radio beam.
    [0054] The radio-beam extends from the transmitting unit at a beamwidth angle B[0054] o. The distance from the transmitting unit to the receiving unit is designated as rm. The beamwidth at the receiving unit is Bm. In a cellular system, a base unit is located at the center of a geographical cell of radius R and the receiving unit is generally mobile and moves with a velocity V.
    [0055] FIG. 7 is a schematic block diagram of communicating users of FIG. 6. As illustrated, the first user [0055] 301 and the second user 302 receive geo-location data from a satellite system 90. The users 301, 302 communicate using a respective antenna array 52 controlled by a respective beamformer circuit 34. In addition to the standard transceiver 310 and control hardware 320, a Global Positioning System (GPS) circuit 350 communicates with a global positioning satellite system 90 to command the beamformer 34. Although a satellite system 90 is illustrated, the geo-location data can be provided by or derived from a ground-based positioning system. Furthermore, a differential global positioning system using both ground and satellite based transmitters can be employed to provide a higher resolution location.
    [0056] FIG. 8 is a flow chart of a method of operating a cellular telephone system using geo-location data. As a part of the initial establishment of the wireless link (step [0056] 500) between the mobile unit 30 and the base station 20, the mobile unit 30 must determine its current position. The GPS receiver may not already be tracking satellites and could take several minutes to get an accurate position estimate (cold start). If the GPS receiver 350 is cold starting (step 510), the base station 20 provides a rough location estimate to orient the GPS receiver and significantly expedite the position acquisition (step 512). It can send an estimate of the mobile unit's location via triangularization from adjacent base stations. This information can be sent along with a Channel Assignment Message (which informs the mobile unit of a Traffic Channel on which to send voice and data) via a Paging Channel. Users share the Paging Channel to communicate information necessary for the establishment of calls.
    [0057] Then the base station [0057] 20 transmits its position to the mobile unit 30 via the Paging Channel (Step 520). If the mobile unit 30 is employing a directive antenna array 35′, it uses the base station position and its current position and heading information to form a beam pattern toward the base station 20 as described above (step 530). The mobile tunes to the Traffic Channel and starts sending a Traffic Channel preamble and the current mobile location information to the base station via a Reverse Traffic Channel (step 540). Every two seconds, the GPS location is updated and sent to the base station via the Reverse Traffic Channel.
    [0058] If the mobile unit [0058] 30 is employing a directive antenna array 35′, every two seconds it uses the current heading information and compares its updated position information to the stored location of the current base station to update the beam pattern toward the base station. Also, the base station 20 receives the updated mobile unit location information and updates it beam pattern toward the mobile unit (step 550). During hand-off between base stations (step 560), the directivity of the mobile antenna array, if employed, is disabled (step 570) to allow the user to communicate with other base stations.
    [0059] FIG. 9 is a schematic diagram of a cellular telephone system using geo-location data. A preferred embodiment is an implementation of SDMA using knowledge of user position in a cellular spread spectrum communication system. Fixed base stations [0059] 20 communicate with roving mobile units 30 within a prescribed geographic cell 10. Each base station 20 consists of a transceiver 210, a directional antenna array 25′ and associated beamformer hardware 24, control hardware 220, and a transmission link with a mobile telecommunications switching office (NTSO) 5 to route calls. The mobile unit 30 consists of handset 8 with a microphone and a speaker, a transceiver 310, a GPS receiver 350 (or other hardware to determine position of the mobile), and an omnidirectional antenna 35 or optionally a directional antenna array 35′ and associated beamformer hardware 34.
    [0060] A preferred embodiment of the invention employs a conventional CDMA base station [0060] 20 but with the addition of a 10-element directional antenna array 25′ capable of forming antenna patterns with a beamwidth of 36 degrees, beamformer hardware 24, and additional modems to accommodate the order of magnitude increase in call capacity. The beamformer hardware 24 takes as input the current latitude and longitude of each mobile unit, compares it with the known location of the base station 20 to determine the angle of arrival (AOA) of each mobile unit's signal, and generates a set of complex antenna weights to apply to each antenna output for each mobile unit such that the combined signal represents a beam pattern steered in the direction of the desired mobile unit for both the transmit and receive signals. The complex antenna weights are calculated to simply steer the antenna beam.
    [0061] Instead of calculating the weights in real-time, a set of weights can be stored in a Programmable Read-Only Memory (PROM) for a finite set of angles of arrival, and can be recalled and immediately applied. The beam pattern is preferably widened as the mobile unit [0061] 30 approaches the base station 20 (as described below) because the beam coverage decreases as the mobile unit 30 approaches the base station 20. Furthermore, the assumption that multipath components propagate from approximately the same location as the mobile unit 30 becomes less valid as the mobile unit 30 approaches the base station. Optionally, the beamformer hardware 24 can track multiple mobile units simultaneously and place nulls on interfering mobile units, but this is more computationally complex (although not as complex as a fully adaptive array).
    [0062] The base station antenna array forms an antenna pattern with beamwidth B[0062] 0=30 degrees. Assuming the cell radius is R=6 km, the mobile unit is at radius rm (m), the maximum velocity of the mobile unit is V=100 (km/h), and the location estimate is updated at U=2 times per second, examination of the pie-slice geometry of the antenna pattern reveals that the antenna beam width at the mobile unit's location is Bm=2πrm(B0/360) meters, which decreases as the mobile unit 30 approaches the base station 20. Once a location estimate has been determined for the mobile unit 30 and transmitted to the base station 20, the base station 20 forms an antenna pattern with the main lobe centered on the mobile unit 30.
    [0063] In the worst case, this estimate is wrong by T=30 m. In an update cycle, the mobile travels V/U (m), and as long as this distance is less than B[0063] m/2 (half the beamwidth in meters at the mobile location) minus the error in the location estimate, T, then the mobile will remain within the antenna main lobe: V/U≦(Bm/2)−T. Evaluating this equation with the typical numerical values and solving for the mobile location yields rm≧167.6 m at a velocity V=100 km/h. Therefore the mobile unit 30 remains in the beam coverage area as long as it is further than 167.6 m from the base station 20.
    [0064] The base station [0064] 20 uses the location information to sense when the mobile unit 30 is closer than 167.6 m and widens the beam pattern to omnidirectional (or optionally to 120 degrees). This widening does not significantly increase interference to other users because the low power is used for nearby mobile units 30. The complex antenna weights for the widened beams are preferably stored in memory for a finite set of angles of arrival, and they can be recalled and immediately applied.
    [0065] The mobile units [0065] 30 include a conventional handset 8 preferably augmented with an integrated GPS receiver 350 and modifications to the control logic 320 to incorporate the GPS position data in the transmission to the base station 20. Mobile units 30 embodied in automobiles preferably employ a three-element directional antenna array 35′ mounted on the automobile and beamformer hardware 34 in addition to the handset with the built-in GPS receiver as described above. The beamformer hardware 34 stores the current base station's latitude and longitude, compares it with its own current latitude and longitude, and computes its current heading via GPS doppler information to determine the angle of the arrival of the base station signal. A look-up table (for example in a ROM) provides the antenna weights to steer the transmit and receive beam pattern toward the base station. Optionally, the beamformer hardware can track multiple base stations simultaneously and place nulls on interfering base stations.
    [0066] The necessary accuracy of the mobile position determination depends on the width of the antenna beam. Assuming the location can be determined to within a tolerance of T=30 m (i.e., the location can be determined with high probability to be within a circle of radius T=30 m), as the mobile unit [0066] 30 moves, the antenna beam must cover the entire area in which the mobile unit 30 can move in the two seconds before the position is checked again and the antenna beam pattern is updated. Because of the pie-slice geometry of the beam pattern, as the mobile unit 30 approaches the base station 20, the beam coverage decreases and must be widened to cover the area in which the mobile unit 30 could travel in the two second update cycle.
    [0067] Mobile units employing the antenna array [0067] 35′ can form an antenna pattern with beamwidth B1=120 degrees. Assuming the cell radius is R=6 km, the mobile is at radius rm (meters), the maximum rotation of the mobile unit is Ω=45 degrees/second (i.e., the mobile can turn a 90 degree corner in 2 seconds), and the location estimate is updated at U=2 times per second, examination of the pie-slice geometry of the antenna pattern yields a location tolerance at the base station of Tb=360T/(2πrm) (degrees), which increases as the mobile unit 30 approaches the base station 20.
    [0068] In addition to location, the mobile unit [0068] 30 needs to know its direction of travel so it can determine the orientation of its antenna array. This direction vector can be deduced from GPS doppler data or from a compass.
    [0069] Once a location estimate has been determined, the mobile unit [0069] 30 forms an antenna pattern with the main lobe centered on the base station 20. In the worst case, this estimate is wrong by Tb (degrees) and the mobile unit 30 is turning at maximum rotation Ω=45 degrees/s. In an update cycle, the mobile's main lobe rotates Ω/U (degrees), and as long as this angle is less than B1/2 (half the mobile beamwidth in degrees) minus the error in the location estimate, Tb (degrees), then the base station 20 will remain within the mobile antenna's main lobe, Ω/U≦(B1/2)−Tb. Evaluating this equation with the numerical values above and solving for the mobile location yields rm≧45 m. Therefore the base station 20 remains in the beam coverage area as long as it is further than 45 m from the mobile unit 30.
    [0070] The mobile unit [0070] 30 uses its location information to sense when it is closer than 45 m to the base station 20 and widens the beam pattern to omnidirectional. Again, this widening does not significantly increase interference to other users because the power transmitted is low. A look-up table in a ROM provides the antenna weights to change the beam pattern to omnidirectional when the mobile unit 30 is within 45 m of the beam station or during call hand-off when the mobile unit 30 is communicating with more than one base station 20.
    [0071] A preferred embodiment of the invention includes an aspect which reduces interference and improves capacity as long as the multipath components propagate from approximately the same direction as the line-of-sight (LOS) component, which is a fair assumption. Typically, a multipath signal is limited to a 5-10° arc relative to the receiver. As such, various techniques can be employed to identify and null the multipath component of a received signal. [0071]
    [0072] Aspects of the invention can be practiced even if some users are not equipped with SDMA capability. In the case that a particular user does not employ an antenna array, the user will not use position information and will default to conventional omnidirectional transmission and/or reception. Similarly, in the case that the user does not provide position information, other users will default to conventional omnidirectional transmission to and/or reception from that user. As conventional users are phased out and SDMA equipped users are phased in, the capacity of the system will increase as the fraction of SDMA equipped users increases. [0072]
    [0073] FIG. 10 is a schematic block diagram of a steering circuit. The steering circuit [0073] 52 includes a GPS receiver 522 connected to a GPS antenna 520 for receiving GPS signals from satellites. The GPS receiver 522 computes the unit's latitude and longitude. A deterministic direction finder 524 processes the mobile unit latitude LATM and longitude LNGM data as well as the base station latitude LATB and longitude LNGB data using a first look-up table to compute an angle of arrival (AOA) and a range (RNG) based on the following equations:AOA = tan - 1  (LNG M - LNG B LAT M - LAT B) RNG = ( LAT M - LAT B ) 2 + ( LNG M - LNG B ) 2
    [0074] The AOA and RNG values are processed by a second look-up table in an antenna steering unit [0074] 526 which converts the values into antenna weights. The antenna weights are calculated to steer the beam in the direction of the angle of arrival. That is, the antenna weights become unity (i.e., omnidirectional) when the range is below a prescribed threshold (i.e., the mobile unit is very close to the base station) and for the mobile unit during handoff. The antenna weights are provided to the beamformer.
    [0075] FIG. 11 is a schematic block diagram of a nulling circuit. Position data from each user is processed by a GPS circuit [0075] 521 a, . . . , 521 k. For a particular user “a”, a desired latitude LATMa and longitude LNGMa data are received and for other users undesirable latitude LATMb, . . . , LATMk and longitude LNGMb, . . . , LNGMk data are received. A first look-up table in a deterministic direction finder unit 523 converts the latitude and longitude data from the mobile units into desired AOAa and undesired AOAb, . . . , AOAk angles of arrival and a desired range RNG based on the base station latitude LATB and longitude LNGB data. This information for each user is passed to a second look-up table in a nulling unit 525 which computes antenna weights which are calculated to steer the beam in the direction of the desired angle of arrival AOAa and away from the undesired angle of arrivals AOAb, . . . , AOAk (i.e., a circuit nulls undesired users). The antenna weights can become unity as described above. The antenna weights from the nulling unit 525 are provided to the beamformer.
    [0076] FIG. 12 is a schematic block diagram of a receiver module for a mobile unit beamformer. The circuit receives a plurality of RF signals IN[0076] a, INb, INc over a respective antenna 35′a, 35′b, 35′c of a directional antenna array 35′. The RF signals are processed into three baseband signal channels by a three-channel receiver 312. Each baseband signal is processed by a programmable filter 342 a, 342 b, 342 c. A GPS signal from a GPS receiver (not shown) is received by a steering/nulling circuit 344 operating as described above. The steering/nulling circuit 344 controls the programmable filters 342 a, 342 b, 342 c. The outputs from the programmable filters are combined by a RF combiner 346 to produce an output signal OUT.
    [0077] FIG. 13 is a schematic block diagram of a transmitter module for a mobile unit beamformer. The input signal IN is split three ways and processed by respective programmable filters [0077] 341 a, 341 b, 341 c. The programmable filters 341 are controlled by a steering/nulling circuit 343 based on inputs from a GPS receiver (not shown) as described above. Three channels of baseband signals result from the programmable filters and are fed to a three-channel transmitter 314 which sends RF signals OUTa, OUTb, OUTc to a respective antenna 35′a, 35′b, 35′c in the antenna array 35′. In a preferred embodiment of the invention, the system implements programmable filtering by including a vector-matrix product processing system as described in U.S. Pat. No. 5,089,983 to Chiang, the teachings of which are incorporated herein by reference.
    [0078] FIG. 14 is a schematic block diagram of a receiver module for a base station beamformer. As illustrated, the antenna array [0078] 25′ of the base station includes 10 antennas 251, . . . ,2510. The input signals IN1, . . . ,IN10 are received by a ten-channel receiver 212 which yields ten channels of baseband signals. Each channel of baseband signal is processed by a programmable filter array 242, each of which includes a respective programmable filter for each of N possible users. The programmable filters 242 are controlled by a steering/nulling circuit 244 for each user based on GPS data received from each user as described above. The outputs from the programmable filters 242 are combined by an RF combiner 246 into N outputs OUT.
    [0079] FIG. 15 is a schematic block diagram of a transmitter module for a base station beam former. The transmitter section receives an input signal IN which is split ten ways into ten channels. Each channel is processed by a programmable filter array [0079] 241 having a programmable filter for each N possible users. The programmable filters are controlled by a steering/nulling circuit 243 for each user based on GPS data from each mobile user as described above. The programmable filters yield N baseband signals divided into ten channels which are transmitted to the antenna array 25′ by a ten-channel transmitter 214. Each antenna 251, . . . ,2510 receives a respective RF output signal OUT1, . . . ,OUT10 from the transmitter 214.
    [0080] In a preferred embodiment of the invention, a cellular base station includes sufficient signal-processing hardware to support the use of geo-location information, received from mobile transmitters, to optimally shape the receiving antenna-array pattern. This approach is an alternative to using a fully adaptive antenna-array that requires a significantly greater cost in terms of hardware and software. [0080]
    [0081] To implement a fully-adaptive base station receiver, an array of antenna inputs must be processed to yield a set of complex-valued weights that are fed back to regulate the gain and phase of the incoming signals. The need for multiple weights applied to a single input signal implies frequency independence. The weight or weights are applied to each input signal as either a real-valued Finite Impulse Response (FIR) filter at a chosen intermediate frequency (IF) (as depicted in FIG. 16 below) or as complex-valued FIR filter at base band (as depicted in FIG. 17 below). Following the application of the appropriate weights, the outputs from each antenna-channel are summed to yield a beamformed output from the array. [0081]
    [0082] FIG. 16 is a schematic block diagram of a preferred base station employing real-valued FIR filtering at IF. In particular, the base station [0082] 1020 employs a sample-data beam shaping system for downconverted and band limited signals. The mobile unit 30 communicates with the base station 1020 through a plurality of N receiver units 1010 1, 1010 2, . . . 1010 N. Each receiver includes a respective antenna 1022 1, 1022 2, . . . , 1022 N. Received signals are transmitted from the antennas 1022 1, 1022 2, . . . 1022 N through a bandpass filter, 1024 1, 1024 2, . . . 1024 N; a gain controllable amplifier 1026 1, 1026 2, 1026 N; a multiplier 10281, 1028 2, . . . , 1028 N; and a second bandpass filter 1030 1, 1030 2, . . . 1030 N to form N receiver output signals.
    [0083] The receiver output signals are input to a processing chip [0083] 1040 which includes a sampling circuit 10421, 1042 2, . . . , 1042 N and a programmable FIR filter 1044 1, 1044 2, . . . , 1044 N for each input signal. The outputs of the FIR filters are summed by a summing circuit 1046. A postprocessor 1048 communicates with an off-chip automatic gain control (AGC) circuit 1032 to provide a control signal to the amplifiers 1026 1, 1026 2, . . . , 1026 N to vary the amplifier gains.
    [0084] The postprocessor [0084] 1048 also communicates with an off-chip geo-location controller 1038 which provides geo-location data to a weighted circuit 1046. The weighting circuit 1036 provides weights to the on-chip programmable filters 1044 1, 1044 2, . . . , 1044 N.
    [0085] FIG. 17 is a schematic block diagram of a preferred base station employing complex-valued FIR filtering at base band. As with FIG. 16, the base station [0085] 1020′ includes a plurality of receivers that provides an input signal to a processing chip 1050. The processing chip 1050 yields two channels of output to an off-chip postprocessor 1034 which decodes, encodes and equalizes the channels. The postprocessor 1034 transmits a signal to the AGC circuit 1032 to control the receiver amplifiers 1026 1, . . . , 1026 N and is in communication with the geo-location controller 1038. Geo-location data from the geo-location controller 1038 is processed by a weight-update circuit 1036′ to calculate weights for a 2N M stage FIR filter array.
    [0086] The base station includes a beamshaping circuit using a two channel downconversion system. The processing chip [0086] 1050 includes, for each of N receivers, a sampling circuit 1052 1, . . . , 1052 N and a multiplier 1054 1, . . . , 1054 N. The multipliers 1054 1, . . . , 1054 N each provide an in-phase (I) channel 1056 1-I . . . , 1056 N-I and a quadrature (2) channel 1056 1-Q, . . . , 1056 N-Q. The respective channels are passed to respective low pass filters 1058 1-I, . . . , 1058 N-Q. Each channel is then down-converted by downconversion circuit 1060 1-I, . . . , 1060 N-Q. The down-converted channels are fed to respective programmable FIR filters 1062 1-I, . . . , 1062 N-Q. These filters are programmed based on the weight inputs from the weighting circuit 1038. The I and Q channels are individually summed at summing circuits 1064-I, 1064-Q for output to the postprocessing system 1034.
    [0087] The effect of the weights is to electronically shape the antenna-array response. Ideally, mobile transmitters that are interfering with the desired user are suppressed or nulled out, while the transmitter of interest is given at least unity gain. Using a fully adaptive antenna array, the weights are updated with time as the mobile unit moves or as propagation conditions change. The update of the weights, however, is computationally intensive requiring the computation of the covariance matrix of the array response. [0087]
    [0088] In comparison, a preferred base station uses position information obtained from the mobile transmitter (or from the base-station network) to automatically compute the weights to be applied to the input signals from each antenna. As in the fully-adaptive system, the weights are updated as the mobile transmitter moves. The potential difficulty with this approach is that it does not explicitly account for changes in the propagation conditions between the mobile transmitter and the base station. [0088]
    [0089] In an effort to characterize the propagation conditions between a mobile transmitter and a base station, a series of operations were performed using a fully operational digital-TDMA cellular system. The base station comprised 6 receiving antennas that can be located with arbitrary spacings. A single, mobile transmitter is used to characterize the propagation conditions. Based on the signals received at the base station, profiles of the signal-propagation delay versus time are mathematically computed. Using these results, the worst case angle-of-arrival is computed. For this case, the delayed signal is assumed to arrive from a reflector along a line perpendicular to a line joining the base station and the mobile. [0089]
    [0090] For geo-location-based array-processing to operate, the true location of the transmitter is preferably very close to the angle of arrival (AOA) of the primary propagation path from the mobile. [0090]
    [0091] When the true location and the AOA of the primary propagation path differ, the beam pattern produced by geo-location information will not exactly produce the desired gain and nulling of the mobiles' signal. This condition produces suppression of the undesired mobile's signal, but may not completely cancel or null out the transmission. [0091]
    [0092] For worst-case propagation conditions, this implies that the electronically synthesized beam pattern does not provide the optimal gain for receiving this mobile, nor does it completely null out the undesired signals. The difference between the ideal (fully adaptive) array beam pattern and one constructed using only geo-location information is not too great, however, when the true position of the mobile and the AOA of the primary propagation path vary by less than a few degrees. [0092]
    [0093] In practice, the preceding situation occurs when the primary propagation between the mobile and the base station are not line-of-sight. This often occurs in urban canyons, where large buildings block line-of-sight transmission from the mobile to the base station (and vice versa); thereby, placing the mobile's transmission in a “deep fade.” To counteract this effect, a preferred base station includes partially adaptive array-processing to incrementally refine the initial beam pattern that is obtained using only geo-location information. Candidate approaches for partially-adaptive array processing can be readily found in the literature for fully-adaptive array processing (e.g., “Novel Adaptive Array Algorithms and Their Impact on Cellular System Capacity,” by Paul Petrus incorporated herein by reference.). [0093]
    [0094] The approaches to computing a mobile's true location have been investigated in detail for CDMA signal communication (see “Performance of Hyperbolic Position Location Techniques for Code-Division Multiple Access,” by George A. Mizusawa, incorporated herein by reference). Implementing a GPS receiver in the phone is one candidate for providing accurate geo-location information to the base station. Alternatively, at least three base stations can be employed to triangulate the mobile location using a variety of algorithms. [0094]
    [0095] FIG. 18 is a schematic block diagram of a beamshaping circuit based on an adaptive-array processing algorithms. As illustrated, the circuitry [0095] 1080 is essentially identical to that illustrated in FIG. 17. The postprocessing circuit, however, communicates with an adaptive-array module 1039 instead of with geo-location data from a mobile unit. An adaptive-array processing algorithm in the module 1039 provides the weighting signal to the on-chip programmable FIR filters 1062 1-I, . . . , 1062 N-Q. The processing chip 1050 can be similarly employed to accomodate other cellular communication techniques.
    [0096] Although preferred embodiments of the invention have been described in the context of a cellular communication system, the principles of the invention can be applied to any communication system. For example, geo-location data and associated beamforming can be embodied in any radio frequency communication system such as satellite communication systems. Furthermore, the invention can be embodied in acoustic or optical communication systems. [0096]
    [0097] EQUIVALENTS [0097]
    [0098] While the invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. In particular, the various aspects of the invention can be embodied in hardware, software or firmware. [0098]
    [0099] These and all other equivalents are intended to be encompassed by the following claims. [0099]
    权利要求:
    Claims (64)
    [1" id="US-20010003443-A1-CLM-00001] 1. A communication system comprising:
    a first transceiver having a first processor and a first directional antenna;
    a second transceiver having a second processor and a second antenna;
    a locator coupled to the first transceiver for determining the physical location of the second antenna relative to the first antenna;
    a spatially multiplexed communication link formed between the first and second transceivers, the link including a wireless beam from the first antenna to the second antenna; and
    a first beamformer in the first transceiver for shaping the wireless beam to be directed between the first antenna and the second antenna.
    [2" id="US-20010003443-A1-CLM-00002] 2. The system of
    claim 1 wherein the first and second antennas are movable relative to one another and the first beamformer updates the direction of the wireless beam in response to the relative motion.
    [3" id="US-20010003443-A1-CLM-00003] 3. The system of
    claim 1 wherein the wireless beam is a radio frequency beam.
    [4" id="US-20010003443-A1-CLM-00004] 4. The system of
    claim 1 wherein the first transceiver is in a base station and the second transceiver is in a mobile unit.
    [5" id="US-20010003443-A1-CLM-00005] 5. The system of
    claim 1 wherein the first transceiver is in a mobile unit and the second transceiver is in a base station.
    [6" id="US-20010003443-A1-CLM-00006] 6. The system of
    claim 1 wherein the locator is responsive to location data from a satellite positioning system.
    [7" id="US-20010003443-A1-CLM-00007] 7. The system of
    claim 1 wherein the locator is responsive to location data from a ground-based positioning system.
    [8" id="US-20010003443-A1-CLM-00008] 8. The system of
    claim 1 wherein the beamformer includes a nulling circuit for suppressing signals outside of the direction of the second antenna.
    [9" id="US-20010003443-A1-CLM-00009] 9. The system of
    claim 1 wherein the beamformer includes an adaptive processing module to alter the shape of the wireless beam over time.
    [10" id="US-20010003443-A1-CLM-00010] 10. A cellular communication system comprising:
    a base transceiver having a directional base antenna, the base antenna having a fixed geographical position within the cell;
    a mobile transceiver having a mobile antenna, the mobile antenna being movable relative to the base antenna;
    a communication link between the base and mobile transceivers formed by a wireless signal between the antennas;
    a positioning system for detecting the geographical position of the mobile antenna, the position of the mobile antenna being communicated from the mobile transceiver to the base transceiver over the communication link;
    a beamformer in the base transceiver for modifying the signal in response to the relative motion of the antennas; and
    a nulling module coupled to the beamformer for suppressing interference to the signal.
    [11" id="US-20010003443-A1-CLM-00011] 11. The system of
    claim 10 wherein the beamformer updates the shape of the signal over time.
    [12" id="US-20010003443-A1-CLM-00012] 12. The system of
    claim 10 wherein the signal is a radio frequency beam.
    [13" id="US-20010003443-A1-CLM-00013] 13. The system of
    claim 10 wherein the positioning system is responsive to position data from a satellite positioning system.
    [14" id="US-20010003443-A1-CLM-00014] 14. The system of
    claim 10 wherein the positioning system is responsive to position data from a ground-based positioning system.
    [15" id="US-20010003443-A1-CLM-00015] 15. The system of
    claim 10 wherein the beamformer includes a plurality of programmable filter arrays.
    [16" id="US-20010003443-A1-CLM-00016] 16. The system of
    claim 10 further comprising a table of stored antenna weights stored in memory, the table accessed by the nulling module to modify the signal.
    [17" id="US-20010003443-A1-CLM-00017] 17. The system of
    claim 10 further comprising an adaptive processing module to alter the shape of the beam over time.
    [18" id="US-20010003443-A1-CLM-00018] 18. The system of
    claim 10 wherein the mobile antenna is a directional antenna.
    [19" id="US-20010003443-A1-CLM-00019] 19. The system of
    claim 10 wherein the communication link is spatially multiplexed.
    [20" id="US-20010003443-A1-CLM-00020] 20. A method for operating a communication system comprising:
    operating a first transceiver having a first processor and a first directional antenna;
    operating a second transceiver having a second processor and a second antenna;
    determining the physical location of the second antenna relative to the first antenna;
    forming a spatially multiplexed communication link between the first and second transceivers, the link including a wireless beam between the first antenna and the second antenna; and
    in a first beamformer in the first transceiver, responding to the physical location of the second antenna and shaping the wireless beam to be directed between the first antenna and the second antenna.
    [21" id="US-20010003443-A1-CLM-00021] 21. The method of
    claim 20 further comprising the steps of:
    moving the first and second antennas relative to one another; and
    in the beamformer, updating the direction of the signal over time in response to the relative movement.
    [22" id="US-20010003443-A1-CLM-00022] 22. The method of
    claim 20 wherein the first wireless beam is a radio frequency beam.
    [23" id="US-20010003443-A1-CLM-00023] 23. The method of
    claim 20 wherein the first transceiver is in a base station and the second transceiver is in a mobile unit.
    [24" id="US-20010003443-A1-CLM-00024] 24. The method of
    claim 20 wherein the first transceiver is in a mobile unit and the second transceiver is in a base station.
    [25" id="US-20010003443-A1-CLM-00025] 25. The method of
    claim 20 wherein the locator is responsive to position data from a satellite positioning system.
    [26" id="US-20010003443-A1-CLM-00026] 26. The method of
    claim 20 wherein the locator is responsive to position data from a ground-based positioning system.
    [27" id="US-20010003443-A1-CLM-00027] 27. The method of
    claim 20 wherein the beamformer includes a nulling circuit to suppress signals outside the direction of the second antenna.
    [28" id="US-20010003443-A1-CLM-00028] 28. The method of
    claim 20 wherein the beamformer includes an adaptive processing module for altering the shape of the wireless beam over time.
    [29" id="US-20010003443-A1-CLM-00029] 29. A method of operating a cellular communication system comprising:
    operating a base transceiver having a directional base antenna, the base antenna having a fixed geographical position within a cell;
    operating a mobile transceiver having a mobile antenna, the mobile antenna being movable relative to the base transceiver;
    forming a communication link between the base and mobile transceivers by a wireless signal between the antennas;
    in a positioning system, detecting the geographical position of the mobile antenna, the position of the mobile antenna being communicated to the base transceiver over the communication link;
    in a beamformer in the base transceiver, modifying the signal in response to the relative motion of the antennas; and
    in a nulling module coupled to the beamformer, suppressing interference with the signal.
    [30" id="US-20010003443-A1-CLM-00030] 30. The method of
    claim 29 wherein the step of modifying the signal comprises updating the direction of the signal over time in response to relative motion between the antennas.
    [31" id="US-20010003443-A1-CLM-00031] 31. The method of
    claim 29 wherein the signal is a radio frequency beam.
    [32" id="US-20010003443-A1-CLM-00032] 32. The method of
    claim 29 wherein the step of detecting comprises receiving position data from a satellite positioning system.
    [33" id="US-20010003443-A1-CLM-00033] 33. The method of
    claim 29 wherein the step of detecting comprises receiving position data from a ground-based positioning system.
    [34" id="US-20010003443-A1-CLM-00034] 34. The method of
    claim 29 wherein the beamformer includes a plurality of programmable filter arrays.
    [35" id="US-20010003443-A1-CLM-00035] 35. The method of
    claim 29 wherein the step of modifying the signal comprises providing antenna weights from a table stored in memory.
    [36" id="US-20010003443-A1-CLM-00036] 36. The method of
    claim 29 wherein the step of modifying includes adaptively altering the shape of the signal over time.
    [37" id="US-20010003443-A1-CLM-00037] 37. The method of
    claim 29 wherein the mobile antenna is a directional antenna.
    [38" id="US-20010003443-A1-CLM-00038] 38. The method of
    claim 29 wherein the step of forming a communication link comprises spatially multiplexing the signal within the cell.
    [39" id="US-20010003443-A1-CLM-00039] 39. A cellular communication system comprising:
    a base transceiver having a directional base antenna, the base antenna having a fixed geographical position;
    a mobile transceiver having a directional mobile antenna, the mobile antenna being movable relative to the base transceiver;
    a communication link between the base and mobile transceivers formed by a wireless signal between the antennas;
    a positioning system for detecting the geographical position of the mobile antenna, the position of the mobile antenna being communicated to the base transceiver over the communication link; and
    a first beamformer in the base transceiver and a second beamformer in the mobile transceiver for modifying the signal in response to the relative motion of the antennas.
    [40" id="US-20010003443-A1-CLM-00040] 40. The system of
    claim 39 wherein the beamformers update the direction of the signal over time in response to the relative movement between the antennas.
    [41" id="US-20010003443-A1-CLM-00041] 41. The system of
    claim 39 wherein the beamformers modify the signal to be omnidirectional when the antennas are separated by less than a specific range.
    [42" id="US-20010003443-A1-CLM-00042] 42. The system of
    claim 39 wherein the signal is a radio frequency beam.
    [43" id="US-20010003443-A1-CLM-00043] 43. The system of
    claim 39 wherein the positioning system is responsive to position data from a satellite positioning system.
    [44" id="US-20010003443-A1-CLM-00044] 44. The system of
    claim 39 wherein the positioning system is responsive to position data from a ground-based positioning system.
    [45" id="US-20010003443-A1-CLM-00045] 45. The system of
    claim 39 wherein the beamformers include a plurality of programmable filter arrays.
    [46" id="US-20010003443-A1-CLM-00046] 46. The system of
    claim 39 further comprising a table stored in memory for providing antenna weights to the beamformer to modify the signal.
    [47" id="US-20010003443-A1-CLM-00047] 47. The system of
    claim 39 further comprising an adaptive processing module coupled to the beamformer to alter the shape of the signal over time.
    [48" id="US-20010003443-A1-CLM-00048] 48. The system of
    claim 39 further comprising a nulling module coupled to the beamformer to suppress interference with the signal.
    [49" id="US-20010003443-A1-CLM-00049] 49. The system of
    claim 39 wherein the communication link includes a spatially multiplexed signal.
    [50" id="US-20010003443-A1-CLM-00050] 50. A method of operating a cellular communication system comprising:
    operating a base transceiver having a directional base antenna, the base antenna having a fixed geographical position within a cell;
    operating a mobile transceiver having a directional mobile antenna, the mobile antenna being movable relative to the base antenna;
    forming a communication link between the base and mobile transceivers by a wireless signal between the antennas;
    in a positioning system, detecting the geographical position of the mobile antenna, the position of the mobile antenna being communicated to the base transceiver over the communication link; and
    in a first beamformer in the base transceiver and a second beamformer in the mobile transceiver, modifying the signal in response to the relative motion of the antennas.
    [51" id="US-20010003443-A1-CLM-00051] 51. The method of
    claim 50 wherein the step of modifying the signal comprises updating the direction of the signal over time in response to the relative movement of the antennas.
    [52" id="US-20010003443-A1-CLM-00052] 52. The method of
    claim 50 wherein the step of modifying comprises determining the range between the base antenna and the mobile antenna and, when the range is less than a specific range, modifying the signal to be omnidirectional.
    [53" id="US-20010003443-A1-CLM-00053] 53. The method of
    claim 50 wherein the signal is a radio frequency beam.
    [54" id="US-20010003443-A1-CLM-00054] 54. The method of
    claim 50 wherein the step of detecting comprises receiving position data from a satellite positioning system.
    [55" id="US-20010003443-A1-CLM-00055] 55. The method of
    claim 50 wherein the step of detecting comprises receiving position data from a ground-based positioning system.
    [56" id="US-20010003443-A1-CLM-00056] 56. The method of
    claim 50 wherein the beamformers include a plurality of programmable filter arrays.
    [57" id="US-20010003443-A1-CLM-00057] 57. The method of
    claim 50 wherein the step of modifying the signal comprises providing antenna weights from a table stored in memory.
    [58" id="US-20010003443-A1-CLM-00058] 58. The method of
    claim 50 wherein the step of modifying the signal comprises performing adaptive processing to alter the shape of the signal over time.
    [59" id="US-20010003443-A1-CLM-00059] 59. The method of
    claim 50 wherein the step of modifying the signal comprises suppressing interference with the signal in a nulling module.
    [60" id="US-20010003443-A1-CLM-00060] 60. The method of
    claim 50 wherein the step of forming the communication link comprises a spatially multiplex signal.
    [61" id="US-20010003443-A1-CLM-00061] 61. A beamforming circuit for a communication system comprising:
    a plurality of sampling circuits for receiving communication signals;
    a plurality of programmable finite impulse response (FIR) filters, each FIR filter being connected to a sampling circuit;
    a summing circuit that sums filtered signals from the plurality of FIR filters; and
    a directional wireless signal formed from the summed signals.
    [62" id="US-20010003443-A1-CLM-00062] 62. The circuit of
    claim 61 wherein the sampling circuits, the plurality of programmable FIR filters and the summing circuit are formed on a single integrated circuit.
    [63" id="US-20010003443-A1-CLM-00063] 63. The circuit of
    claim 61 further comprising a multiplier connected to each sampling circuit to generate an in-phase channel and a quadrature channel, each channel being connected to a filter, a converter and one of the FIR filters.
    [64" id="US-20010003443-A1-CLM-00064] 64. The circuit of
    claim 61 wherein the communication system comprises a cellular network including a plurality of transceivers that communicate by wireless link with mobile transceiver units, and further including a base station having an adaptive array processor providing weighting signals to the FIR filters.
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    同族专利:
    公开号 | 公开日
    US6593880B2|2003-07-15|
    AU4907497A|1998-05-05|
    TW379488B|2000-01-11|
    WO1998016077A3|1998-08-20|
    US6512481B1|2003-01-28|
    EP0931425A2|1999-07-28|
    CN1233376A|1999-10-27|
    US20040104839A1|2004-06-03|
    KR20000049007A|2000-07-25|
    WO1998016077A2|1998-04-16|
    CA2267184A1|1998-04-16|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20020077122A1|2000-12-14|2002-06-20|Koninklijke Philips Electronics N.V.|Method of providing travel information to a mobile communications device|
    US20020115452A1|2000-02-17|2002-08-22|Whikehart J. William|Antenna beam steering responsive to receiver and broadcast trasmitter|
    EP1341326A1|2002-02-26|2003-09-03|Alcatel|Link restoration in a fixed wireless transmission network|
    US6697644B2|2001-02-06|2004-02-24|Kathrein-Werke Kg|Wireless link quality using location based learning|
    US20040063430A1|2002-09-27|2004-04-01|Interdigital Technology Corporation|Mobile communications system and method for providing mobile unit handover in wireless communication systems that employ beamforming antennas|
    US20040073538A1|2002-10-09|2004-04-15|Lasoo, Inc.|Information retrieval system and method employing spatially selective features|
    US20040098433A1|2002-10-15|2004-05-20|Narayan Anand P.|Method and apparatus for channel amplitude estimation and interference vector construction|
    US6750818B2|2000-12-04|2004-06-15|Tensorcomm, Inc.|Method and apparatus to compute the geolocation of a communication device using orthogonal projections|
    US20040136445A1|2002-10-15|2004-07-15|Olson Eric S.|Method and apparatus for interference suppression with efficient matrix inversion in a DS-CDMA system|
    US20040146093A1|2002-10-31|2004-07-29|Olson Eric S.|Systems and methods for reducing interference in CDMA systems|
    US20040148039A1|2003-01-24|2004-07-29|Farchmin David W|Position based machine control in an industrial automation environment|
    US20040151235A1|2001-11-19|2004-08-05|Olson Eric S.|Interference cancellation in a signal|
    US20040160924A1|2001-11-19|2004-08-19|Narayan Anand P.|Systems and methods for parallel signal cancellation|
    US20040162626A1|2003-02-14|2004-08-19|Farchmin David Walter|Location based programming and data management in an automated environment|
    US20040166881A1|2003-02-06|2004-08-26|Farchmin David Walter|Phased array wireless location method and apparatus|
    US6791959B1|1999-04-12|2004-09-14|Broadcom Corporation|Method for determining when a communication device should rate shift or roam in a wireless environment|
    US20040204111A1|2002-12-26|2004-10-14|Juha Ylitalo|Method of allocating radio resources in telecommunication system, and telecommunication system|
    US20040203874A1|2002-09-27|2004-10-14|Brandt David D.|Machine associating method and apparatus|
    US20040208238A1|2002-06-25|2004-10-21|Thomas John K.|Systems and methods for location estimation in spread spectrum communication systems|
    WO2004054153A3|2002-08-07|2004-12-29|Interdigital Tech Corp|Mobile communications system and method for providing common channel coverage using beamforming antennas|
    US20050012660A1|2002-11-15|2005-01-20|Lockheed Martin Corporation|All-weather precision guidance and navigation system|
    US20050031060A1|2002-09-20|2005-02-10|Thomas John K.|Interference matrix construction|
    US6856945B2|2000-12-04|2005-02-15|Tensorcomm, Inc.|Method and apparatus for implementing projections in singal processing applications|
    US20050071498A1|2003-09-30|2005-03-31|Farchmin David W.|Wireless location based automated components|
    US20050075140A1|2003-10-02|2005-04-07|Toshiba America Research Inc.|Harmonized Adaptive Arrays|
    US20050075845A1|2001-11-19|2005-04-07|Thomas John K.|Orthogonalization and directional filtering|
    US20050123080A1|2002-11-15|2005-06-09|Narayan Anand P.|Systems and methods for serial cancellation|
    US20050136943A1|2003-10-07|2005-06-23|Banerjee Debarag N.|Location-assisted wireless communication|
    US20050163039A1|2004-01-23|2005-07-28|Narayan Anand P.|Systems and methods for analog to digital conversion with a signal cancellation system of a receiver|
    US20050169354A1|2004-01-23|2005-08-04|Olson Eric S.|Systems and methods for searching interference canceled data|
    US20050180364A1|2002-09-20|2005-08-18|Vijay Nagarajan|Construction of projection operators for interference cancellation|
    US20050180496A1|2001-09-28|2005-08-18|Olson Eric S.|Serial cancellation receiver design for a coded signal processing engine|
    US20050188267A1|2004-02-06|2005-08-25|Farchmin David W.|Location based diagnostics method and apparatus|
    US20050204061A1|2004-03-12|2005-09-15|Farchmin David W.|Juxtaposition based machine addressing|
    EP1612997A1|2004-07-01|2006-01-04|ABB PATENT GmbH|Point-to-point radio communications system for open-pit mining or transshipping place for bulk goods|
    US20060040675A1|2002-08-13|2006-02-23|Rudiger Halfmann|Method for operating a radio system, emitting station and radio system|
    US7009557B2|2001-07-11|2006-03-07|Lockheed Martin Corporation|Interference rejection GPS antenna system|
    US20060071849A1|2004-09-30|2006-04-06|Lockheed Martin Corporation|Tactical all weather precision guidance and navigation system|
    US20060125689A1|2004-12-10|2006-06-15|Narayan Anand P|Interference cancellation in a receive diversity system|
    US7065373B2|2002-10-18|2006-06-20|Itt Manufacturing Enterprises, Inc.|Method of steering smart antennas|
    US7075909B1|1999-05-31|2006-07-11|Sanyo Electric Co., Ltd.|Radio spectrum management apparatus for base stations|
    US20060217091A1|2004-04-02|2006-09-28|Yasunobu Tsukio|Mobile receiver|
    US20060227909A1|2005-04-07|2006-10-12|Thomas John K|Optimal feedback weighting for soft-decision cancellers|
    US20060229051A1|2005-04-07|2006-10-12|Narayan Anand P|Interference selection and cancellation for CDMA communications|
    US20060227908A1|2005-04-07|2006-10-12|Scharf Louis L|Advanced signal processors for interference cancellation in baseband receivers|
    US7123940B1|2001-02-27|2006-10-17|Sprint Communications Company L.P.|Wireless communication system including omni-directional transmitter and directional receiver|
    US7129890B1|2004-03-16|2006-10-31|Verizon Corporate Services Group Inc.|Dynamic beamforming for ad hoc networks|
    US20060267834A1|2005-05-31|2006-11-30|Research In Motion Limited|Mobile wireless communications device comprising a satellite positioning system antenna and electrically conductive director element therefor|
    US20070025299A1|2005-07-29|2007-02-01|Scharf Louis L|Interference cancellation within wireless transceivers|
    US7200183B2|2001-11-16|2007-04-03|Tensorcomm Inc.|Construction of an interference matrix for a coded signal processing engine|
    US20070135051A1|2005-01-05|2007-06-14|Dunmin Zheng|Adaptive beam forming with multi-user detection and interference reduction in satellite communication systems and methods|
    US20070183483A1|2002-09-23|2007-08-09|Narayan Anand P|Method and apparatus for selectively applying interference cancellation in spread spectrum systems|
    US20070191022A1|2006-02-14|2007-08-16|Oki Electric Industry Co., Ltd.|Method and a system for location estimation using location estimated|
    US20070293170A1|2006-06-15|2007-12-20|The Mitre Corporation|Assessment of idle portions of multidimensional radio spectrum access|
    US7324782B1|2000-08-14|2008-01-29|Lucent Technologies Inc.|Location based adaptive antenna scheme for wireless data applications|
    US20080258971A1|2007-01-22|2008-10-23|Raytheon Company|Method and System for Controlling the Direction of an Antenna Beam|
    US20080299912A1|2007-05-30|2008-12-04|Sony Corporation|Method and Structure in Support of the Formation of Substantially Co-Linear Wireless Device Pairings and Mitigation of Interference Effects in a Digital Multi-Media Communication Environment|
    US20090021370A1|2001-01-02|2009-01-22|Fish Robert D|Panic Device With Local Alarm And Distal Signaling Capability|
    US20090135064A1|2006-04-20|2009-05-28|Panasonic Corporation|Method and device for wireless directional beam-forming transmission|
    US20090141776A1|2003-09-23|2009-06-04|Tensorcomm, Inc.|Systems and methods for control of advanced receivers|
    US20090163210A1|2007-12-21|2009-06-25|Fujitsu Limited|Communications systems|
    US20100124212A1|2008-11-14|2010-05-20|Ralink TechnologyCorporation|Method and system for rf transmitting and receiving beamforming with location or gps guidance|
    US20110080923A1|2002-09-20|2011-04-07|Rambus Inc.|Interference Suppression for CDMA Systems|
    US8005128B1|2003-09-23|2011-08-23|Rambus Inc.|Methods for estimation and interference cancellation for signal processing|
    US20110280330A1|2009-01-22|2011-11-17|Kyocera Corporation|Radio communication system, radio terminal, radio base station, control device and radio communication method|
    US8085889B1|2005-04-11|2011-12-27|Rambus Inc.|Methods for managing alignment and latency in interference cancellation|
    WO2012016223A1|2010-07-30|2012-02-02|Raytheon Applied Signal Technology, Inc.|Near-vertical direction finding and geolocation system|
    US20120281672A1|2008-09-04|2012-11-08|Michael Ohm|System architecture for providing communications in a wireless communication network|
    US20130343338A1|2012-06-21|2013-12-26|Cable Television Laboratories, Inc.|Efficient adaptable wireless network system with agile beamforming|
    US8654689B2|2002-09-20|2014-02-18|Rambus Inc.|Advanced signal processors for interference cancellation in baseband receivers|
    US20140293870A1|2011-12-13|2014-10-02|Guoqing Li|Beamforming based on information from platform sensors|
    US8861466B2|2002-08-07|2014-10-14|Interdigital Technology Corporation|Mobile communication system and method for providing common channel coverage using beamforming antennas|
    US9026161B2|2012-04-19|2015-05-05|Raytheon Company|Phased array antenna having assignment based control and related techniques|
    US9172456B2|2005-04-07|2015-10-27|Iii Holdings 1, Llc|Iterative interference suppressor for wireless multiple-access systems with multiple receive antennas|
    US20160112112A1|2014-10-20|2016-04-21|Electronics And Telecommunications Research Institute|Method and apparatus for beamforming|
    US20170006613A1|2014-03-20|2017-01-05|Ntt Docomo, Inc.|User equipment and base station|
    US20170230092A1|2002-11-04|2017-08-10|Xr Communications, Llc D/B/A Vivato Technologies|Directed wireless communication|
    US9844077B1|2015-03-19|2017-12-12|Sprint Spectrum L.P.|Secondary component carrier beamforming|
    US10028120B2|2015-02-18|2018-07-17|Global Life-Line, Inc.|Identification card holder with personal locator|
    WO2018146198A1|2017-02-09|2018-08-16|Sony Mobile Communications Inc.|Message transmission based on a determined beam configuration|
    US20190007950A1|2011-08-17|2019-01-03|Skyline Partners Technology Llc|Radio with interference measurement during a blanking interval|
    US10193733B2|2005-10-26|2019-01-29|Intel Corporation|Wireless communication system to communicate using different beamwidths|
    TWI656755B|2017-01-09|2019-04-11|國家中山科學研究院|Array antenna communication system and method thereof|
    US10548132B2|2011-08-17|2020-01-28|Skyline Partners Technology Llc|Radio with antenna array and multiple RF bands|
    US10700733B2|2013-12-05|2020-06-30|Skyline Partners Technology Llc|Advanced backhaul services|
    US10708918B2|2011-08-17|2020-07-07|Skyline Partners Technology Llc|Electronic alignment using signature emissions for backhaul radios|
    US10716111B2|2011-08-17|2020-07-14|Skyline Partners Technology Llc|Backhaul radio with adaptive beamforming and sample alignment|
    US10720969B2|2011-08-17|2020-07-21|Skyline Partners Technology Llc|Radio with spatially-offset directional antenna sub-arrays|
    US10735979B2|2011-08-17|2020-08-04|Skyline Partners Technology Llc|Self organizing backhaul radio|
    US10736110B2|2012-02-10|2020-08-04|Skyline Partners Technology Llc|Method for installing a fixed wireless access link with alignment signals|
    US10764891B2|2011-08-17|2020-09-01|Skyline Partners Technology Llc|Backhaul radio with advanced error recovery|
    US10785754B2|2011-10-11|2020-09-22|Skyline Partners Technology Llc|Method for deploying a backhaul radio with antenna array|
    US10932267B2|2012-04-16|2021-02-23|Skyline Partners Technology Llc|Hybrid band radio with multiple antenna arrays|
    CN112566038A|2020-11-25|2021-03-26|南通先进通信技术研究院有限公司|Method for automatically reporting real-time position information by UE based on LTE communication system|FR727268A|1930-11-19|1932-06-15||Molding machine|
    US4827268A|1986-08-14|1989-05-02|Hughes Aircraft Company|Beam-forming network|
    US4802227A|1987-04-03|1989-01-31|American Telephone And Telegraph Company|Noise reduction processing arrangement for microphone arrays|
    US4894842A|1987-10-15|1990-01-16|The Charles Stark Draper Laboratory, Inc.|Precorrelation digital spread spectrum receiver|
    US5119504A|1990-07-19|1992-06-02|Motorola, Inc.|Position aided subscriber unit for a satellite cellular system|
    US5146231A|1991-10-04|1992-09-08|Motorola, Inc.|Electronic direction finder|
    DE4134357A1|1991-10-17|1993-04-22|Standard Elektrik Lorenz Ag|MESSAGE TRANSFER SYSTEM|
    US5592490A|1991-12-12|1997-01-07|Arraycomm, Inc.|Spectrally efficient high capacity wireless communication systems|
    US5235633A|1991-12-26|1993-08-10|Everett Dennison|Cellular telephone system that uses position of a mobile unit to make call management decisions|
    US5317322A|1992-01-06|1994-05-31|Magnavox Electronic Systems Company|Null processing and beam steering receiver apparatus and method|
    US5327143A|1992-06-22|1994-07-05|Trw Inc.|Multiple arm spiral antenna system with multiple beamforming capability|
    JPH0659013A|1992-08-05|1994-03-04|Pioneer Electron Corp|Signal acquisition method for gps receiver|
    GB2271486B|1992-10-07|1997-04-16|Motorola Ltd|A communication system|
    WO1994009568A1|1992-10-09|1994-04-28|E-Systems, Inc.|Adaptive co-channel interference reduction system for cellular telephone central base stations|
    US5345426A|1993-05-12|1994-09-06|Hewlett-Packard Company|Delay interpolator for digital phased array ultrasound beamformers|
    US5383164A|1993-06-10|1995-01-17|The Salk Institute For Biological Studies|Adaptive system for broadband multisignal discrimination in a channel with reverberation|
    TW351886B|1993-09-27|1999-02-01|Ericsson Telefon Ab L M|Using two classes of channels with different capacity|
    US5548813A|1994-03-24|1996-08-20|Ericsson Inc.|Phased array cellular base station and associated methods for enhanced power efficiency|
    US5818385A|1994-06-10|1998-10-06|Bartholomew; Darin E.|Antenna system and method|
    US5928152A|1994-08-05|1999-07-27|Acuson Corporation|Method and apparatus for a baseband processor of a receive beamformer system|
    US5564098A|1994-09-13|1996-10-08|Trimble Navigation Limited|Ultra low-power integrated circuit for pseudo-baseband down-conversion of GPS RF signals|
    US5539415A|1994-09-15|1996-07-23|Space Systems/Loral, Inc.|Antenna feed and beamforming network|
    US5594453A|1994-11-01|1997-01-14|Trimble Navigation, Ltd|GPS receiver having a rapid acquisition of GPS satellite signals|
    FR2727268B1|1994-11-22|1997-02-07|||
    US5596600A|1995-04-06|1997-01-21|Mayflower Communications Company, Inc.|Standalone canceller of narrow band interference for spread spectrum receivers|
    US5680142A|1995-11-07|1997-10-21|Smith; David Anthony|Communication system and method utilizing an antenna having adaptive characteristics|
    US5917446A|1995-11-08|1999-06-29|The Charles Stark Draper Laboratory, Inc.|Radio-wave reception system using inertial data in the receiver beamforming operation|
    US5736909A|1996-02-02|1998-04-07|Philips Electronics North America Corporation|Monolithic continuous-time analog filters|
    US5722412A|1996-06-28|1998-03-03|Advanced Technology Laboratories, Inc.|Hand held ultrasonic diagnostic instrument|
    US5857155A|1996-07-10|1999-01-05|Motorola, Inc.|Method and apparatus for geographic based control in a communication system|
    US5848105A|1996-10-10|1998-12-08|Gardner; William A.|GMSK signal processors for improved communications capacity and quality|
    US6512481B1|1996-10-10|2003-01-28|Teratech Corporation|Communication system using geographic position data|
    US5736785A|1996-12-20|1998-04-07|Industrial Technology Research Institute|Semiconductor package for improving the capability of spreading heat|
    US6018643A|1997-06-03|2000-01-25|Texas Instruments Incorporated|Apparatus and method for adaptively forming an antenna beam pattern in a wireless communication system|
    US6011512A|1998-02-25|2000-01-04|Space Systems/Loral, Inc.|Thinned multiple beam phased array antenna|US6512481B1|1996-10-10|2003-01-28|Teratech Corporation|Communication system using geographic position data|
    FI973663A|1997-09-11|1999-03-12|Nokia Telecommunications Oy|Mobile Phone System|
    US6275187B1|1998-03-03|2001-08-14|General Electric Company|System and method for directing an adaptive antenna array|
    US7218890B1|1998-08-07|2007-05-15|Input/Output, Inc.|Seismic telemetry system|
    DE19849294C2|1998-10-16|2001-09-27|Daimler Chrysler Ag|Method of spreading a message|
    KR100275707B1|1998-11-26|2000-12-15|윤종용|Home networl system and node id assignment method thereof|
    GB2349045A|1999-04-16|2000-10-18|Fujitsu Ltd|Base station transmission beam pattern forming; interference reduction|
    US7664492B1|1999-07-27|2010-02-16|Cellco Partnership|Network engineering in a wireless network|
    SE9903038L|1999-08-27|2001-02-28|Ericsson Telefon Ab L M|Procedures and devices in a telecommunications system|
    CA2325644A1|1999-11-24|2001-05-24|Lucent Technologies Inc.|Network enhancement by utilizing geolocation information|
    JP2001177864A|1999-12-15|2001-06-29|Toshiba Corp|Wireless communication system, wireless communication method, and wireless control station|
    DE69938185T2|1999-12-21|2009-07-23|Lucent Technologies Inc.|A method and apparatus for operating a cellular telecommunications system|
    DE10004000A1|2000-01-29|2001-08-02|Bosch Gmbh Robert|Mobile communication system|
    US6931235B2|2000-02-29|2005-08-16|Dynamic Telecommunications, Inc.|Method and apparatus for co-channel interference measurements and base station color code decoding for drive tests in TDMA, cellular, and PCS networks|
    JP3467226B2|2000-04-20|2003-11-17|埼玉日本電気株式会社|Mobile phone system|
    JP3874991B2|2000-04-21|2007-01-31|株式会社東芝|Radio base station and frame configuration method thereof|
    US6950678B1|2000-05-24|2005-09-27|Lucent Technologies Inc.|Control technique for a communication system|
    CN1290271C|2000-07-14|2006-12-13|三洋电机株式会社|Wireless information terminal, wireless communication system, communication method and program|
    US7013165B2|2000-08-16|2006-03-14|Samsung Electronics Co., Ltd.|Antenna array apparatus and beamforming method using GPS signal for base station in mobile telecommunication system|
    EP1323710B1|2000-10-06|2008-09-10|Mitsubishi Tanabe Pharma Corporation|Nitrogenous five-membered ring compounds|
    US7072315B1|2000-10-10|2006-07-04|Adaptix, Inc.|Medium access control for orthogonal frequency-division multiple-accesscellular networks|
    US6870808B1|2000-10-18|2005-03-22|Adaptix, Inc.|Channel allocation in broadband orthogonal frequency-division multiple-access/space-division multiple-access networks|
    US20050288034A1|2001-11-15|2005-12-29|Judson Bruce A|Method and apparatus for using position location to direct narrow beam antennas|
    US7181244B2|2000-11-16|2007-02-20|Qualcomm, Incorporated|Method and apparatus for using position location to direct narrow beam antennas|
    WO2002049306A2|2000-12-15|2002-06-20|Broadstorm Telecommunications, Inc.|Multi-carrier communications with group-based subcarrier allocation|
    US6947748B2|2000-12-15|2005-09-20|Adaptix, Inc.|OFDMA with adaptive subcarrier-cluster configuration and selective loading|
    US7062273B2|2000-12-25|2006-06-13|Kabushiki Kaisha Toshiba|Mobile communication terminal apparatus having an array antenna for communication to at least one base station|
    US7161997B2|2000-12-26|2007-01-09|Intel Corporation|Programmable baseband module|
    US7164669B2|2001-01-19|2007-01-16|Adaptix, Inc.|Multi-carrier communication with time division multiplexing and carrier-selective loading|
    US6940827B2|2001-03-09|2005-09-06|Adaptix, Inc.|Communication system using OFDM for one direction and DSSS for another direction|
    US7340279B2|2001-03-23|2008-03-04|Qualcomm Incorporated|Wireless communications with an adaptive antenna array|
    US20020142783A1|2001-03-28|2002-10-03|Yoldi Cesar Sanchez|Reduced acquisition time for GPS cold and warm starts|
    US8290098B2|2001-03-30|2012-10-16|Texas Instruments Incorporated|Closed loop multiple transmit, multiple receive antenna wireless communication system|
    US7274677B1|2001-04-16|2007-09-25|Cisco Technology, Inc.|Network management architecture|
    GB2375267B|2001-05-04|2006-02-22|Nokia Corp|A communication system|
    US6751444B1|2001-07-02|2004-06-15|Broadstorm Telecommunications, Inc.|Method and apparatus for adaptive carrier allocation and power control in multi-carrier communication systems|
    US7003310B1|2001-09-28|2006-02-21|Arraycomm Llc.|Coupled uplink/downlink power control and spatial processing with adaptive antenna arrays|
    US8977284B2|2001-10-04|2015-03-10|Traxcell Technologies, LLC|Machine for providing a dynamic data base of geographic location information for a plurality of wireless devices and process for making same|
    US20030069043A1|2001-10-10|2003-04-10|Pallav Chhaochharia|Methods and devices for wirelessly transmitting data in dependence on location|
    TW595857U|2001-11-29|2004-06-21|Us|091219345|
    WO2003075471A2|2002-03-01|2003-09-12|Cognio, Inc.|System and method for joint maximal ratio combining|
    US6687492B1|2002-03-01|2004-02-03|Cognio, Inc.|System and method for antenna diversity using joint maximal ratio combining|
    US6785520B2|2002-03-01|2004-08-31|Cognio, Inc.|System and method for antenna diversity using equal power joint maximal ratio combining|
    US6862456B2|2002-03-01|2005-03-01|Cognio, Inc.|Systems and methods for improving range for multicast wireless communication|
    CN1653784A|2002-03-08|2005-08-10|Ipr特许公司|Adaptive receive and omnidirectional transmit antenna array|
    US6871049B2|2002-03-21|2005-03-22|Cognio, Inc.|Improving the efficiency of power amplifiers in devices using transmit beamforming|
    US7289556B2|2002-04-08|2007-10-30|Faraday Technology Corp.|Apparatus and method for compensating signal attenuation based on an equalizer|
    JP4370076B2|2002-04-22|2009-11-25|株式会社エヌ・ティ・ティ・ドコモ|Cell area formation control method, control apparatus, cell area formation control program, and computer-readable recording medium|
    US6917337B2|2002-06-05|2005-07-12|Fujitsu Limited|Adaptive antenna unit for mobile terminal|
    KR100850888B1|2002-06-28|2008-08-07|에이스안테나|Adaptive antenna device by using GPS signal of mobile phone and beam control method thereof|
    US6768459B2|2002-07-31|2004-07-27|Interdigital Technology Corporation|Method and system for positioning mobile units based on angle measurements|
    US7130662B2|2002-08-01|2006-10-31|Interdigital Technology Corporation|Simple smart-antenna system for MUD-enabled cellular networks|
    US10659071B2|2002-10-24|2020-05-19|Teledyne Lecroy, Inc.|High bandwidth oscilloscope|
    US7219037B2|2002-10-24|2007-05-15|Lecroy Corporation|High bandwidth oscilloscope|
    CN1732698B|2002-11-07|2012-10-31|艾达普蒂斯公司|Method and apparatus for adaptive carrier allocation and power control in multi-carrier communication systems|
    US7088288B1|2003-01-10|2006-08-08|Xilinx, Inc.|Method and circuit for controlling an antenna system|
    US20040246174A1|2003-02-13|2004-12-09|Frederic Lamour|Antenna system for links between mobile vehicles and airborne devices|
    GB2402553B|2003-06-06|2007-06-20|Westerngeco Seismic Holdings|A segmented antenna system for offshore radio networks and method of using the same|
    DE10328570B4|2003-06-25|2005-08-25|Infineon Technologies Ag|Method for reducing the radiation load by a mobile radio terminal with directional radiation and mobile radio terminal with directional radiation|
    JP2005026733A|2003-06-30|2005-01-27|Hitachi Ltd|Wireless communication apparatus and wireless communication method|
    US20050068228A1|2003-09-25|2005-03-31|Burchfiel Jerry D.|Systems and methods for implementing vector models for antenna communications|
    US20050111427A1|2003-11-21|2005-05-26|Qinghua Li|SDMA training and operation|
    KR100570451B1|2003-12-16|2006-04-12|한국항공우주연구원|Airship Communication Antenna Polarization Tilting and Main Beam Steering System Using a GPS|
    FI120570B|2003-12-23|2009-11-30|Teliasonera Finland Oyj|Transmission of data at sea|
    US7206550B2|2003-12-29|2007-04-17|Intel Corporation|Antenna subsystem calibration apparatus and methods in spatial-division multiple-access systems|
    US8369790B2|2003-12-30|2013-02-05|Intel Corporation|Communication overhead reduction apparatus, systems, and methods|
    CN100378717C|2004-01-17|2008-04-02|华为技术有限公司|Method for obtaining target place and direction via hard-held device|
    US8900149B2|2004-04-02|2014-12-02|Teratech Corporation|Wall motion analyzer|
    WO2005109369A1|2004-04-05|2005-11-17|Advancemontech International, Inc.|Mobile telephone safety system with motion detection|
    US7308247B2|2004-04-05|2007-12-11|Demetrius Thompson|Cellular telephone safety system|
    US20060033659A1|2004-08-10|2006-02-16|Ems Technologies Canada, Ltd.|Mobile satcom antenna discrimination enhancement|
    CN101175280B|2004-09-02|2010-06-02|华为技术有限公司|Method for acquiring objective position direction by handhold equipment|
    US20060068822A1|2004-09-29|2006-03-30|Amit Kalhan|Method and apparatus for implementation of ad hoc mesh network|
    US7573851B2|2004-12-07|2009-08-11|Adaptix, Inc.|Method and system for switching antenna and channel assignments in broadband wireless networks|
    JP2006203782A|2005-01-24|2006-08-03|Nec Corp|Radio communication system, receiving device, demodulation method, and program|
    US20070167705A1|2005-08-04|2007-07-19|Chiang Alice M|Integrated ultrasound imaging system|
    US7221318B2|2005-09-13|2007-05-22|Kyocera Wireless Corp.|System and method for controlling antenna pattern|
    US7466627B2|2005-10-20|2008-12-16|Pgs Geophysical As|System and method for wireless data collection from seismic recording buoys|
    DE102005053510A1|2005-11-09|2007-05-10|Siemens Ag|Motor vehicle for automotive vehicle communication and associated method for operating an antenna structure of a motor vehicle|
    WO2007068879A1|2005-12-15|2007-06-21|British Telecommunications Public Limited Company|Call admission control in an ad hoc network|
    GB2433859B|2005-12-29|2008-04-16|Motorola Inc|Mobile station, system and method for use in wireless communications|
    US8195240B2|2007-04-18|2012-06-05|Cisco Technology, Inc.|Hybrid time-spatial multiplexing for wireless broadcast messages through antenna radiation beam synthesis|
    US8032134B2|2007-04-24|2011-10-04|Ralink Technology Corporation|Beamforming with global positioning and orientation systems|
    CN102138352A|2008-02-25|2011-07-27|爱立信电话股份有限公司|Relays in multi-user MIMO systems|
    TWI411164B|2008-03-26|2013-10-01|Quanta Comp Inc|Method for generating optimal communication direction|
    US8081210B2|2008-10-31|2011-12-20|GM Global Technology Operations LLC|Location of broadcast transmitters and mobile-adaptation using map-based navigation|
    EP2362973A1|2008-11-12|2011-09-07|Nokia Corporation|A method, apparatus, computer program and a computer readable storage medium|
    TWI393373B|2009-02-17|2013-04-11|Mediatek Inc|Method and system for rf transmitting and receiving beamforming with location or gps guidance|
    US20100124210A1|2008-11-14|2010-05-20|Ralink Technology Corporation|Method and system for rf transmitting and receiving beamforming with gps guidance|
    CN102362519B|2009-03-20|2015-09-09|瑞典爱立信有限公司|The transponder improved|
    DE102009019995A1|2009-05-05|2010-11-11|Airbus Deutschland Gmbh|Method for directional digital data transmission between an aircraft and a ground station|
    US8154450B2|2009-06-05|2012-04-10|Qualcomm Incorporated|Optimization for finding direction of arrival in smart antennas|
    ES2382794B1|2009-09-22|2013-05-08|Vodafone España, S.A.U.|METHOD FOR DYNAMICALLY ESTABLISHING THE RADIATION PATTERN OF AN ANTENNA BASED ON USER EQUIPMENT POSITIONING INFORMATION|
    WO2011078750A1|2009-12-21|2011-06-30|Telefonaktiebolaget L M Ericsson |Method for suppressing opposite direction interference|
    CN101795164B|2010-01-29|2014-01-08|上海微小卫星工程中心|Method for monitoring co-channel interference in satellite uplink channel|
    US20120068880A1|2010-09-17|2012-03-22|Raytheon Company|System and Method for Dual-Band Antenna Pointing, Acquisition, And Tracking|
    US8712679B1|2010-10-29|2014-04-29|Stc.Unm|System and methods for obstacle mapping and navigation|
    CN102879790A|2011-07-13|2013-01-16|北京泰豪联星技术有限公司|Anti-interference system and method based on digital beam forming and space-time zeroing cascade|
    KR101966724B1|2011-09-15|2019-04-08|삼성전자주식회사|Apparatus and method for beam selecting in beamformed wireless communication system|
    CN102721971A|2011-12-31|2012-10-10|武汉苍穹数码仪器有限公司|Method for improving anti-interference performance of GNSS receiver|
    WO2013120536A1|2012-02-17|2013-08-22|Sony Ericsson Mobile Communications Ab|Antenna tunning arrangement and method|
    US9357534B2|2013-08-09|2016-05-31|Qualcomm Incorporated|Method and apparatus for location aided high frequency operations|
    US9608709B1|2013-10-19|2017-03-28|GoNet Systems, Ltd.|Methods and systems for beamforming and antenna synthesis|
    CN103986508B|2014-05-30|2017-08-01|北京智谷睿拓技术服务有限公司|mode switching method and device|
    US10075221B2|2015-12-31|2018-09-11|Motorola Mobility Llc|Method and apparatus for directing an antenna beam based on motion of a communication device|
    US10433184B2|2015-12-31|2019-10-01|Motorola Mobility Llc|Method and apparatus for directing an antenna beam based on a location of a communication device|
    EP3306327B1|2016-10-06|2019-06-12|Rohde & Schwarz GmbH & Co. KG|Antenna array, test system and method for testing a device under test|
    CN108736161B|2017-04-14|2021-10-01|京东方科技集团股份有限公司|Mobile device and mobile device directional antenna adjusting method|
    US10098085B1|2017-06-05|2018-10-09|Cisco Technology, Inc.|Detecting a location of a wireless device|
    US20190123433A1|2017-10-25|2019-04-25|Ford Global Technologies, Llc|Beamforming for wireless vehicle communication|
    CN110896324A|2019-05-15|2020-03-20|腾讯科技(深圳)有限公司|Enhanced beam forming method, device, system and equipment|
    WO2021144607A1|2020-01-14|2021-07-22|Telefonaktiebolaget Lm Ericsson |Methods of managing communication based on information defining an operational environment and related nodes|
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    优先权:
    申请号 | 申请日 | 专利标题
    US08/729,289|US6512481B1|1996-10-10|1996-10-10|Communication system using geographic position data|
    PCT/US1997/018780|WO1998016077A2|1996-10-10|1997-10-10|Communication system using geographic position data|
    US09/188,835|US6593880B2|1996-10-10|1998-11-09|Communication system using geographic position data|US09/188,835| US6593880B2|1996-10-10|1998-11-09|Communication system using geographic position data|
    US10/619,382| US20040104839A1|1996-10-10|2003-07-14|Communication system using geographic position data|
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