CA2174765A1 - Method and apparatus for conveying a communication signal between a communication unit and a base site - Google Patents
Method and apparatus for conveying a communication signal between a communication unit and a base siteInfo
- Publication number
- CA2174765A1 CA2174765A1 CA002174765A CA2174765A CA2174765A1 CA 2174765 A1 CA2174765 A1 CA 2174765A1 CA 002174765 A CA002174765 A CA 002174765A CA 2174765 A CA2174765 A CA 2174765A CA 2174765 A1 CA2174765 A1 CA 2174765A1
- Authority
- CA
- Canada
- Prior art keywords
- sector
- communication signal
- base site
- signal
- uplink
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
Links
Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S3/00—Direction-finders for determining the direction from which infrasonic, sonic, ultrasonic, or electromagnetic waves, or particle emission, not having a directional significance, are being received
- G01S3/02—Direction-finders for determining the direction from which infrasonic, sonic, ultrasonic, or electromagnetic waves, or particle emission, not having a directional significance, are being received using radio waves
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W64/00—Locating users or terminals or network equipment for network management purposes, e.g. mobility management
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S3/00—Direction-finders for determining the direction from which infrasonic, sonic, ultrasonic, or electromagnetic waves, or particle emission, not having a directional significance, are being received
- G01S3/02—Direction-finders for determining the direction from which infrasonic, sonic, ultrasonic, or electromagnetic waves, or particle emission, not having a directional significance, are being received using radio waves
- G01S3/14—Systems for determining direction or deviation from predetermined direction
- G01S3/28—Systems for determining direction or deviation from predetermined direction using amplitude comparison of signals derived simultaneously from receiving antennas or antenna systems having differently-oriented directivity characteristics
- G01S3/30—Systems for determining direction or deviation from predetermined direction using amplitude comparison of signals derived simultaneously from receiving antennas or antenna systems having differently-oriented directivity characteristics derived directly from separate directional systems
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W16/00—Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
- H04W16/24—Cell structures
Abstract
A communication system (100) employs a method (600) and apparatus (101) for coveying a communication signal between a communication unit (105) and a base site (101) that services a sectorized coverage area (103). The communication unit (105) transmits an uplink communication signal (113) to the base site (101). The base site (101) receives (603) the uplink communication signal (113) and determines (605) an approximate location of the communication unit (101) within a first portion (111) of a sector (108) of the sectorized coverage area (103). A downlink communication signal is then transmitted (609, 613) to the communication unit (105) based on the approximate location of the communication unit (105) using an antenna structure that produces a beamwidth (117) narrower than an angular width of the sector (108).
Description
2 ~ 7 ~ 7 6 5 PCT/US95/08277 Method And Apparatus For Conveying A Co~ ---..,iç~tion Signal Between A Co.~u~ ic~tiQn Unit And A Base Site Field of the Invention The present invention relates generally to radio communic~tion systems and, in particular, to a method and ~al~atus 1 5 for conveying a communication signal between a base site and a commllnic~fion unit in a radio communic~tion system.
Background of the Invention - 2 0 Co--.. -l~.. ic~tion ~y~l~ms, such as celllll~r communi~.ation ~ySlt;lllS or trunked two-way co...~-....ic~tion ~y~ s, are known to comprise a plurality of co.~ ..ication units and a plurality of base sites. In a cellular co.-...-l~.ic~tion system, each base site includes one or more base stations and provides co.. ,l~.-ication services to a 2 5 particular coverage area or cell. Each cell is typically partitioned into a plurality of sectors by using directional ~..te~ at the base site serving the cell to increase the capacity of the cell~ r system.
Each sector of a cell is served by one of the base stations at the base site and is allocated a particular set of channels to use for
Background of the Invention - 2 0 Co--.. -l~.. ic~tion ~y~l~ms, such as celllll~r communi~.ation ~ySlt;lllS or trunked two-way co...~-....ic~tion ~y~ s, are known to comprise a plurality of co.~ ..ication units and a plurality of base sites. In a cellular co.-...-l~.ic~tion system, each base site includes one or more base stations and provides co.. ,l~.-ication services to a 2 5 particular coverage area or cell. Each cell is typically partitioned into a plurality of sectors by using directional ~..te~ at the base site serving the cell to increase the capacity of the cell~ r system.
Each sector of a cell is served by one of the base stations at the base site and is allocated a particular set of channels to use for
3 0 communic~tions in that sector. Each ch~nn~l might comprise a receive/tr~n~mi~ frequency pair in a frequency division mllltiple access (FDMA) comm~miç~tion system, a receive/tr~nsmit slot pair in a time division multiple access (TDMA) communic~tion system, or a rlesign~te~l portion of an ~llocated system bandwidth in a spread 3 5 spectrum communiration system. The ch~nnels ~si ned to each set .
WO 96/07108 217 4 7 6 5 PCT/US95/08277~
are ~l~terrnine~l by the desired ch~nnt-.l reuse pattern for ~e c~-llular ~y~
To maximize capacity, without degrading signal quality due to S an ablm~l~nce of co-ch~nnel inl~. re~llce and noise, cellular systems typically employ r-h~nnel reuse p~ttern~ of four and seven. In a four cell reuse p~ttern, all the allocatable channels (i.e., those used for two-way commlmications) are divided into four sets, one set for each cell. Simil~rly, in a seven cell reuse p~ttern, all the alloc~t~blç
10 ch~nnels are divided into seven sets. However, to m~int~in a desired signal quality (e.g., a carrier-to-interference plus noise, C/I+N, of 17 dB), each cell in a four cell reuse p~ttern is typically divided into six 60 degree sectors; whereas, each cell in a seven cell reuse pat~ern it typically divided into three 120 degree sectors. Once a cell is 15 sectorized, the particular set of ch~nn~ols ~signlod to ~at cell is ~imil~rly partitioned, such that each sector in the cell is ~signed its own subset of the ch~nnels allocated to the cell. The channel partitioning within a cell is typically performed to ,.~i,.i..~i7e cochannel intelrerc;llce, adjacent rh~nnel l~telrt;l~ce, and noi~e in 2 0 accordance with known techniques.
To provide adequate coverage at the cell boundary, each base site typically employs high power tr~n~mitters. The power of each tran~mitter is dependent upon the sectorization of a cell. For 2 5 example, a higher power tr~n~mitter is necessary for a 120 degree sector than for a 60 degree sector in order to m~int~in a desired signal level along the sector boundary due to the higher directivity of of an antenna having a 60 degree half power beamwidth (HPBW) as compared wi~ an ~n~eIln~ having a 120 degree HPBW.
As is known, cells in a cellular system are typically hexagonal in shape. Thus, each cell has six neighboring cells. The area near the border between any two cells is generally known as the fringe area, or handoff region, of a cell. Therefore, when a 3 5 commllniç~tion unit is commllnicating and enters the fiinge area of ~ WO 96/07108 2~ :1 7 ~ 7 6 5 PCT/USg5/08277 its host cell, the base site for the host cell might hand off the commlmic~tion to a base site serving one of the neighboring cells.
As is also known, ce~ r co~ l..ication systems use S sign~lling access form~t~, such as TDMA, FDMA, and code division multiple access (CDMA), to convey co,..~ tion sign~l~ between commnnic~tion units and their servicing base stations. In a CDMA
system, all co-~ ic~tion units in the ~y~ tr~ncmit uplink commlmication si n~l~ to their respective base station in a common 10 reverse ch~nnel bandwidth. However, each uplink commllnic~tion signal is associated with the serving base station by the inclusion of a pseudo-noise (PN) sequence (in direct sequence CDMA) or by a predetermined frequency hopping pattern (in slow or fast frequency hopping CDMA). The PN sequence and the frequency hopping 15 pattern permit the base station to identify which uplink sign~l~ are intended for reception by the base station's receiver. In a simil~r m~nner, each base station tr~n~mit~ downlink commlmic~tion sign~l~
to the commllnic ation units in its coverage area in a common forward channel bandwid~.
The discovery and technical advances associated with the advent of CDMA has pPrmitte(l cell~ r system lesi ners to begin using one cell and one sector ch~nnel reuse p~ttern~. One cell ch~nnel repeat p~ttern~ have been ~l~e~ .t~d in FDMA and TDMA
2 5 cellular systems; however, such ~llel~l)t~ have required that the systems operate at degraded signal quality levels (e.g., at a C/I+N of 13 dB). By contrast, CDMA one cell and one sector repeat p~ttern~
generally can m~int~in acceptable signal quality levels.
3 0 In a one sector CDMA reuse configuration, each sector reuses the same channels as its neighboring sectors, as opposed to partitioning the allocatable ch~nnels as in o~er sectorization sch~mes. However, a problem arises in a CDMA ~y~ ll using a one sector ch~nnel reuse pattern when a col"",ll,.ication unit is located in 3 5 the handoff region between two or more sectors. When the WO 96/07108 PCT/US95/08277 ~
~7~7~ 4 commlmication unit is in the handoff region, it .eimlllt~neously receives downlink commlmication sign~e from two or more base station tr~n~ el~s. Consequently, the commllnication unit is also receiving the noise, co-ch~nnel inte relellce, and adjacent channel 5 interference generated in the co_mon fol ~ard channel bandwidth by the base stations since each base station is tr~nemittinp to its respective sector using a tr~nemitter that provides adequate coverage at the sector boundary. Thus, the commnni~tion unit often cannot distinguish the downlink commllnic~tion sign~le from the 10 interference and noise. This indistinguishability results in poor signal quality, dropped calls, and limitetl capacity of the CDMA
system due the fo~ çh~nnel degradation at the fringe areas of the cells.
1 5 A ~imil~r problem arises at the base station due to poor signai-to-noise performance in the common reverse channel bandwidth of a CDMA system when the commlmi~ation unit is in the fringe area of a cell. The base station receives uplink commllniç~tion sign~l~ from comm~lnication units in it's respective sector and from 2 0 commllnic~tion units in fringe areas of neighboring sectors. Thus, if the commllnic~tion unit does not have enough tr~n~mit power to overcome the total noise received by the base station, the base station cannot distinguish the comml-nis~tion unit's uplink signal from the noise.
Therefore, a need exists for a method and aypalatus for conveying a commllnication signal between a commlmication unit and a base site that services a sectorized coverage area. Such a method and apparatus that improves capacity in either the fol ~va~d 3 0 channel, the reverse ch~nnel, or both by reducing intelreLc;llce and noise in the respective channel would be an improvement over ~e prior art. r 3 5 Brief Description of the Drawings ~ WO96/07108 21 7 4 7 6 5 PCT/US9'S/08277 FIG. 1 illustrates a commllnic~tion system that might employ the present invçntion sFIG. 2 illustrates a base site in accordance with the present invention.
FIG. 3 illustrates an ~ltern~te co"~",ll..ic~tion system that might employ the present invention FIG. 4 illustrates an ~ltern~te base site in accordance with the present invention.
FIG. S illustrates a base site ~ntenn~ tower that supports a 15 receive antenna structure and a tr~n~mit ~-,te""~ structure for each sector of a base site's sectori7e~1 coverage area in accordance with the present invention.
FIG. 6 illustrates a logic flow diagram of steps executed by a - 2 0 base site to tr~n~mit a downlink commllnic~tion signal in accordance with ~e present inven~ion FIG. 7 illustrates a logic flow diagram of steps executed to receive an uplink co"""ll..ic~tion signal at a base site in accordance 2 5 with the present invention 3 0Description of a PrefelTed Embo-lime.nt Generally, the present invention encomp~ses a method and apparatus for conveying a comm-lnic~tion signal between a commllnic~tion unit and a base site that services a sectori_ed 3 5 coverage area in a commlmic~tion system. The co.~ ...ic~tion unit WO96/07108 2~ ~ 7~5 6 PCT/U595/08277 ~
transmits an uplink commllnication signal to the base site. The base site receives the uplink commllni~tion signal and determin~s an approximate location of the commllnic~tion unit within a first portion of a sector of the sectQri~ecl coverage area. A downlink S comml-nic~tion signal is then tr~ncmittetl to the comm~-nic~tion unit based on the approximate location of the commlmir.ation unit using an ~ntenn~ structure that produces a beamwidth narrower than an angular width of the sector. By conveying the commllniç~tion signal in this m~nn~r, the present invention effectively reduces the quantity 1 0 of noise and interference received by a commllnir.ation unit in the fringe area of a sector, thereby improving the signal quality of the comm~mic~tion signal received by the coInmlmic~tion unit in the fringe area. Such a signal quality improvement results in an increase in the forward ch~nn~l commlmis~tion capacity of the sector.
The present invention can be more fully described with refer~llce to FIGs. 1-7. FIG. 1 illustrates a comml~nication ~y~l~m 100 that might employ the present invention. The commllni~.ation system 100 comprises a commlmic~tion unit 105 and a base site 101 2 0 that services a sectorized coverage area 103. The coInmllnication sy~lelll 100 ~lefelably comprises a spread spec~um commlmication system, such as the direct sequence CDMA (DS-CDMA) ~y~m set forth in Telecommllnic~tions Industry Association/Electronic Industries Association Tnterim St~ndard 95 (TIA/EIA/IS-95) or a 2 5 frequency hopping system, such as those proposed for the (lQmestic Personal Commllnirations System (PCS). In an ~ltern~te embodiment, the commnnic~ation system might comprise a TDMA
commllnication ~y~ , such as those set for~ in EIAmA/IS-54 and the Global System for Mobile (GSM) commllnic~tions, or an FDMA
3 0 system, such as that set forth in TIA/EIA/IS-91. The co"""l."ication unit 105 preferably comprises a mobile or portable radiotelephone, although other types of two-way commnnicating devices might be ~ltern~tively used. The base site 101 is described in detail below with regard to FIG. 2.
~ WO 96/07108 . . ~ PCT/US95/08277 7 2~7~
As generally mentioned above, the coverage area 103 of the base site 101 is divided into a plurality of sectors 106-108 (three shown). In a ~r~felled embodiment, each sector 106-108 occupies approxim~tely 120 degrees of the coverage area 103; however, other 5 sectorization schPmes (e.g., six 60 degree sectors) might be ~ltenl~tively employed. As shown in the FIG., sector 106 is adjacent to one side, or boundary 121, of sector 108 and sector 107 is adjacent to another boundary 122 of sector 108. In the depicted embodimçnt, sector 108 is further divided into a plurality of 1 0 portions 110, 111 (two in ~is particular case). However, in a ~refel.ed embo~liml nt, all sectors 106-108 of the coverage area 103 are apportioned simil~r to sector 108. The base site 101 serves each portion 110, 111 of sector 108 with a corresponding narrow beam ~ntenn~ pattern 115, 117.
Conveyance of a commlmic~tion signal between the base site 101 and the commlmic~ion unit 105 in accordance with the present invention is generally performed in the following m~nner. It is assumed for the puIpose of this discussion ~at ~e c(~ tion 2 0 unit 105 is registered in the co"..~ ic~tion system 100 and is being serviced by the base site 101. When the commllnic~tion unit 105 desires to commnnicate, the co~ tion unit 105 tr~n~mi~ an uplink traffic co"""l."ic~tion signal 113 (e.g., a voice or data signal) to the base site 101. The base site 101 receives the uplink 2 5 commllnic~tion signal 113 from receive ~"tel."~ that service each sector 106-108. Each sector 106-108 might be served by one or more receiving ~ntenn~ depel ~ing on the system configuration (e.g., two ~ntenn~ per sector 106-108 is a common configuration when using diversity reception).
Upon receiving the uplink co~ ,-ic~tion signal 113, the base site 101 determin~s an approximate location of the commnnication unit lOS by preferably comparing the uplink sign~l~ 113 received from each sector 106, 107 of the coverage area 103 that is 3 5 subst~nti~lly adjacent to the sector 108 in which the commllnic~tion W O 96/07108 2 ~ 7 ~ 7 6 ~ PCTrUS9~/08277 -unit 105 is currently resi-l~nt- In a preferred embodiment, the comparison is performed on the signal strengths of the received uplink sign~l.c 113, although the comparison could be performed using other signal quality metrics, such as bit error rate, word error 5 rate, or carrier-to-interference plus noise ratio.
When the signal strength of the uplink signal 113 received in sector 107 is greater than the signal strength of the uplink signal 113 received in sector 106, the base site 101 dete. ,.-i,.es ~at the 1 0 commllnir.ation unit lOS is located in portion 111 of sector 108 and tr~ncmits a downlink co~ "ic~tion signal (e.g., a traffic signal or a dedicated control signal) to the commllnication unit lOS using narrow beam antenna pattern 117. In a simil~r m~nner, when the signal strength of the uplink signal 113 received in sector 106 is 1 S greater ~an the signal strength of the uplink signal 113 received in sector 107, the base site 101 determines that the commlmi~tion unit 105 is located in portion 110 and tr~n.cmi~c the downlink conlmllnir,~tion signal to the comm-~nic~tion unit lOS using narrow beam antenna p~ttern l lS.
When the signal strength of the uplink signal 113 received in sector 106 is approxim~tely equal to the signal strength of the uplink signal 113 received in sector 107, the base site 101 might determine that the co~"",~ ication unit lOS is in an overlap region 119 of the 25 two narrow beam ~.-te""~ p~tternc llS, 117 and, ~erefore, might tr~n.cmit the downlink co"""l..,ication signal to the commllni~tion unit lOS using both narrow beam s~tC~ p~tternC l lS, 117. In the ~ref~lled embo-limPnt, the downlink commllnir.~tion signal tr~ncmitte~l using narrow beam ~lltel ~ p~ttern l lS is decorrelated, 3 0 prior to tr~ncmicsion, wi~ respect to the downlink commllnication signal tr~ncmitte-l using narrow beam antenna pattern 117 to provide sufficient coverage in the overlap region 119 (i.e., to minimi7.e ~e probability for destructive interference of the downlink co"-~ "ic~tion signal). Decorrelation of the downlink 3 5 cornmimi~.~rion si~n~l~is ~l~fel~bly accomplished by deiaying one downlink signal by a predetermined interval of time with respect to the other as detailed below.
In an ~ltern~te embo~lim~-nt, the commlmir~tion unit 105 might S include a global positioning satellite (GPS) receiver to dete~ i"e the commnnic~tion unit's location within the coverage area 103. In such an embodiment, the commllnic~tion unit 105 tr~n~mit~ its location to the base site 101 and the base site 101 subsequently tr~n~mit~ the downlink co,,l~ ic~tion signal into the portion (e.g., 111) of the 10 sector 108 in which the commllnication unit 105 is currently resitlent. The use of a GPS receiver in a commllnic~tion unit for determining a location of the co"""l.,.ication unit is described in detail in U.S. Patent No. 5,235,633, çntitl~l "Cellular Telephone System That Uses Position Of A Mobile To Make Call Management 15 Decisions" and incorporated herein by r~fer~llce. Thus, no further explanation will be provided except to facilitate an underst~n-lin~ of the present invention.
As illustrated in FIG. 1, each narrow beam ~"te,.,.~ pattern 2 0 115, 117 in this particular embo~lim~nt occupies approximately one-half, or 60 degrees, of sector 108, although other sector partitioning schemes (e.g., a 100 degree portion and a 20 degree portion) might be ~ltern~tively employed. However, in contrast to prior art sectorization schemes, each portion 110, 111 of sector 108 can utilize 2 5 all the channels allocated to sector 108 instead of requiring disjoint ch~nnel ~si nments in each portion 110, 111 as is the case with prior art sectorization.
The above discussion generally pe~ s to the conveyance of 3 0 traffic commllnication sign~l~ (e.g., voice or data) and de~lic~te~l control ~i~n~l~--e.g., those used to inform the comm-lnication unit 105 of system conditions, such as handoff, particular to the commlmi~ ~tion unit 105--between the base site 101 and the commllnic~tion unit 105. However, the tr~n~mi~sion of common 3 5 system control inform~tion from the base site 101 to the WO 96/07108 217 4 ~ ~ 5 lo PCT/US95/08277 --commlmication units in the base site's coverage area 103 should also be considered, particularly within the apportioned sector 108. To tr~nemit common system control information to the commllnication units (e.g., 105) resident in sector 108, the base site 101 tr~nemite a S downlink common control signal using both narrow beam ~ntenn~
p~tte.rne 115, 117. This tr~nemi.esion is accomplished in a m~nn~r eimil~r to that described above for the tr~nemiesion of a traffic signal into the overlap region 119 of portion 108. That is, the tr~nemiesion of the downlink common control signal into portion 111 is 10 preferably decorrelated with respect to the tr~nemi.esion of the downlink common control signal into portion 110 in order to provide sufficient coverage to those comm-mir.ation units located in the overlap region 119.
In a preferred embodiment, the tr~n~mit power used to tr~n~mit the directional downlink si~ into the respective portions 110, 111 of sector 108 is less than that typically used to tr~n~mit downlink si n~l~ to the complete 120 degree sector 108 due to the directionality of the narrow beam ~ntenn~ p~ttern~ 115, 117. Since 2 0 less tr~n.~mit power is required to service a commllnication unit 105 in a particular portion (e.g., 111) of the base site's coverage area 103, correspondingly less interference and noise is introduced into the fringe areas of the other portions 110 of the coverage area 103, especially when the commllnic~tion system 100 is a DS-CDMA
2 5 ~ys~ . By introducing lower interference and noise levels into the various portions 110, 111 of ~e apportioned sector 108, the overall forward ch~nnel (base site 101 to commllnication unit 105) capacity of the sector 108 is increased as compared wi~ the forward ch~nnel capacity of prior art sectorized coverage areas. Consequently, the 3 0 present invention facilitates the lltili7.~tion of a one sector channel reuse pattern, without reducing the capacity in each sector due to increased interference and noise in the handoff regions (fringe areas) between sectors, as in the prior art.
11 21~7~
.
FIG. 2 illustrate,s the base site 101 of FIG. 1 in accordance with the present invention. The base site 101 comprises, inter alia, a plurality of receive ~-,te,""~ 201-204, a plurality of transmit ~ntenn~ 206, 207, and a receiver 209. In this particular S embo-lim~,nt, receive ~nteTln~ 201 comprises a directional ~ntenn~
having narrow beam ~nt~,nn~ pattern 115 that receives uplink commllnis~tion si~n~l~ from portion 110 of sector 108. Receive ~nte,nn~ 202 comrri~es a directional antenna having narrow beam ~ntçnn~ pattern 117 that receives uplink commlmic~tion ~ from 1 0 portion 111 of sector 108. Receive ~nte,nn~ 203, 204 comprise directional ~.,t~ that receive uplink CO~ ,-.. ic~tion sign~l~ from sectors 106 and 107, respectively. Each receive ~l~tellll~ 201-204 might comprise one or more directional ~nte,nn~ depentling on whether diversity techniques are employed.
In an analogous m~nner, tr~n~mit ~ tel.ll~ 206 comprises a directional ~ntenn~ having narrow beam ~,lte".l~ p~ttern l lS that tr~n~mit~ downlink commllnic~tion si~n~l~ into portion 110 of sector 108, while tr~n~mit ~"te,.~-~ 207 comprises a directional antenna 2 0 having narrow beam ~ntenn~ p~ttern 117 that tr~n~mit~ downlink commllni~,ation sign~ into portion 111 of sector 108. However, as illustrated in FIG. 1, the tr~ncmit ~..te..,~ 206, 207 together form a wide beam ~nte,nn~ pattern that sulJ~ .ti~lly covers sector 108. In a preferred embotlim~nt, the receiver 209 comprises the known 2 5 electronic circ~ ,y (e.g., filters, amplifiers, demodulators, and proces~in,~ devices) n~cess~ry to receive DS-CDMA uplink ~i n~l~
and to measure and compare the signal strengths of those sign~
Reference to FIG. 1 will be made hereinbelow as necessary to 3 0 facilitate an underst~ntling of the invention. When the commllnic~tion unit 105 tr~n~mits an uplink traffic signal 113 from portion 111 of sector 108, the uplink signal 113 is received by the receive ~ntenn~ 201-204. Receive antennas 203 and 204 provide their rec,eived ~ign~l~ independently to the receiver 209; whereas, the 3 5 uplink sign~l~ 113 received by receive ~ntto,I~n~ 201, 202 are first WO 96/07108 PCTIUS95~27 ~747~5 decorrelated and then combined in a combiner 213 prior to being provided to the receiver 209. The decorrelation is ~lefelably accomplished using a delay device 217, such as a microwave delay line or a shift register delay line, that is inserted between one (e.g., 5 202) of the receive ~nteIln~ 201, 202 serving the apportioned sector 108 and the combiner 213. The delay device 217 delays the uplink signal 113 received by the one receive antenna 202 by a predetermined interval of time with respect to the uplink signal 113 received by the other receive ~.lte.~ 201 to decorrelate the two 1 0 received si~n~l.c. In a DS-CDMA system 100, the predetermine~l interval of time preferably comprises one PN chip (i.e., appro~cim~tely 800 nanoseconds). The decorrelation allows the receiver 209 to indepçndently demodulate each received uplink signal 113 in accordance with known techniques. However, since the 1 S uplink signals 113 received by receive ~ntenn~ 201, 202 are combined prior to submission to the receiver 209 in this embo-limPnt, the receiver 209 receives three uplink si~n~l~ 113 from one co"~".l",ication unit tr~ncmi~sion~ wherein each received signal corresponds to a particular sector 106-108.
In a preferred embo~limP-nt, upon receiving ~e three uplink si~n~l~, the receiver 209 determin~-s the approximate location (i.e., the portion 111 of the apportioned sector 108) of the co"~ "ication unit 105 by comr~rin~ the uplink si~ 113 received by receive 2 5 ~ntçnn~s 203 and 204. As discussed above, when the signal strength of ~e uplink signal 113 received by receive ~"te,...~ 204 is larger than the signal strength of the uplink signal 113 received by receive antenna 203, the receiver 209 dete",-i..es that the commlmic~tion unit lOS is located in portion 111 of sector 108. Simil~rly, when the 3 0 signal strength of the uplink signal 113 received by receive ~ntenn~
203 is larger than the signal strength of the uplink signal 113 received by receive ~nte.~n~ 204, the receiver 209 cleterrnines that ~e commlmic~tion unit lOS is located in portion 110 of sector 108.
Thus, in a preferred embocliment, the receiver 209, or at least a 3 ~ portion thereof, effectively becomes a means for iclentifying the WO 96/07108 13 21 7 4 7 6 S PCT/US9~i/08277 portion (e.g., 111) of the sector 108 to route the downlink traffic, or ~e~ic~te~l control, signal into based on the signal strength comparison. Once the ~plv~liate portion 111 is i~le.ntifie-l, the receiver 209 directs a switch 211 (e.g., a known tr~n~mi~sion gate 5 circuit), via a control line 212, to provide the downlink signal to the corresponding narrow beam tr~n~mit ~-.te.~ (e.g., 207) that serves the i~entified portion 111.
The selected tr~n~mit ~ntenn~ 207 then conveys the downlink 10 signal into the a~pr~liate portion 1 1 1 of the sector 108. In this m~nner, the switch 211, the control line 212, and the tr~ncmit antennas 206, 207 collectively comprise selection means for routing the downlink signal into the ~r~liate portion 110 or portions 110, 111 of the sector 108 in which the commllnic~tion unit 105 is 1 5 currently resident.
In an ~1tern~tç embo~lim~nt, the receiver 209 might determine the approximate location of the comml-ni~tion unit 105 and, accordingly, which portion of the partitioned sector 108 to tr~n~mit 2 0 into based on signal strength me~c-lrem~nt~ made by ~e co"""l...ic~tion unit 105 of downlink commllnif~tion ~ign~l~
tr~n~mitte~l by the base site 101. In this case, the co.~....l...is~tion unit 105 measures the downlink signal received from the base site 101 and ~n~mits the me~.~llred signal strength inform~tion back to the 2 5 base site 101. Based on the commlmi~tion unit's me~cllremtQnts the base site 101 then dete..-~i..es whether ~e downlink signal is being tr~n~mittç~l into the proper portion 111 of the apportioned sector 108. This dete. ~ tioIl might be accomplished by co,~g the commnnication unit's measured signal strength to a predetermine~
3 0 threshold.
In yet another embodiment, the receiver 209 might determinP
the approxim~te location of ~e commlmic~tjon unit 105 based on signal strength measurement.~ made at another base site (not shown) 3 5 of the commlmic~tion system 100. In this emboclim~nt, the other 2i74765 base site measures the signal strength of the uplink signals 113 tr~n~mittetl by the commlmication unit 105. The other base site then conveys those measurements to a central location (e.g., base site 101) where the commllnic~tion unit's location is estim~teA using known S triaIlgulation techniques.
In a further embo~lim~nt, the receiver 209 might determine the approximate location of the commlmic~tion unit 105 based on signal strength measurem~nt~ made by the commllnic~ion UIlit 105 10 of downlink commllnir~ation si n~l~ tr~n~mitte-l by other base sites (not shown) in the co~ llir~tion ~ ~111 100. The commllnis~tion unit 105 then conveys these mP~ remlonts to a central location (e.g., base site 101) where the co""~,l"-ication unit's location is estim~te-l using known triangulation techniques.
To transmit common ~y~ control si~ from the base site 101 into the apportioned sector 108, as discussed above, the base site 101 preferably decorrelates the common control signal provided to one tr~n~mit ~ e",.~ 207 with respect to the common control signal 2 0 provided to the other tr~n~mit antenna 206. In a plef~lled embo(lim~nt, this decorrelation is performed by delaying the common control signal provided to tr~n~mit ~ntenn~ 207 by a predeterrnine~l interval of time--e.g., one PN chip for a DS-CDMA
control signal--using a delay device 221,such as shift register delay 2 5 line. In the ~lefell~d embo~lim~-nt, the downlink common control signal is summed with the downlink traffic signal in a respective sllm mer214,215 prior to being provided to the ~ro~liate ~nsmit ~ntt~nn~ 206,207. Such an approach allows the downlink common control si~n~l~ to be routed to the complete sector 108, while the 3 0 downlink traffic signal is directed only to the selected portion (e.g., 111).
As discussed above, receive ~I~te~ 201,202 receive the uplink comm-mication signal 113 from sector 108. However, since 3 5 ~e received ~ are combined prior to being provided to the ~17476S
receiver 209, they may not be usable in determinin~ the commlmication unit's approximate location. In an alternate emborlim~-nt, the base site 101 further includes a modulator for controlling the delay device 217 that performs the decorrelation.
S The mo~ tor 219 is used to mo~ te the delay--e.g., using a periodic modulation pattern--introduced by the delay device 217, thereby providing an i~le,ntifi~kle sign~tllre for the receiver 209 to recognize. Upon recogni7in~ the modulation pattern, the receiver 209 can detel,.lill~o, that the uplink signal was received from that 1 0 portion (e.g., 111) of the sector 108 served by the receive ~nte,nns~
202 whose received si n~l~ encounter a mo~llll~te-l delay prior to being provided to the receiver 209. In an analogous m~nner, when the receiver 209 receives an uplink signal from combiner 213 that is not mo~ te-l, the receiver 209 can determine that the uplink signal 1 5 was received from that portion '(e.g., 110) of the sector 108 served by the receive ~ntenn~ 201 whose received si n~l~ do not encounter the mo~ te~l delay.
In yet another embo~lime-nt, the uplink sign~l~ received by 2 0 receive ~ntenn~c 201, 202 might be indepe,ntl~,ntly provided to t,he receiver 209 to allow the receiver 209 to easily dete. ..~ , which portion 110, 111 of the sector 108 the commlmication unit 105 resides in. However, this embo~iim~nt increases the complexity of the receiver 209.
FIG. 3 illustrates an ~lte,rn~te commllnic~tion ~y~lelll 300 that might employ the present invention. The commllnic~tion system 300 comprises a commllnication unit 305 and a base site 301 that services a sectori~e~ coverage area 303. The commlmication system 300 3 0 might comprise any one of those ~y~lellls set forth above with regard to FIG. 1. The commlmit~.ation unit 305 preferably comprises a mobile or portable radiotelephone, although other types of two-way commlmic~ting devices might be ~ltem~tively used. The base site 301 is described in detail below with regard to FIG. 4.
The coverage area 303 of the base site 301 is divided into a plurality of sectors 307-309 (~ree shown) eimil~r to the coverage area 103 depicted in FIG. 1. As shown in the FIG., sector 307 is adjacent to one side, or boundary 324, of sector 309 and sector 308 S is adjacent to another boundary 326 of sector 309. Sector 309 is further divided into a plurality of portions 311-316 (six in ~is particular case). In a pleferred embo~lim~t, the base site 301 tr~n~mit~ to each portion 311-316 of sector 309 with a corresponding narrow beam ~ntenn~ pattern 317-322.
Conveyance of a traffic, or ~e~lic~teA control, signal between the base site 301 and the commlmic~tion unit 305 in accordance with this embo~limt nt of the present invention is generally performed in the following m~nner. When the commlmication unit desires to 1 5 commllnic~te, the commllnication unit 305 tr~ncmit~ an uplink commllni~tion signal 334 to the base site 301. The base site 301 receives ~e uplink signal 334 from receive ~ntenn~ that service the sectors 307, 308 adjacent to the apportioned sector 309 and from receive ~ntenn~s that service the apportioned sector 309. For 2 0 example, in this particular embo~liment, ~ree receive ~I~te~
service the apportioned sector 309, each antenna serving a pair (e.g., 311, 312) of the portions 311-316, as det~ rl below with regard to FIG. 4.
2 5 Upon receiving the uplink signal 334, the base site 301 determine~ an approximate location of the commlmic~tion unit 305 by preferably COl~illg the signal streng~s of ~e ~ign~l~ received by the receive ~llte~ serving the apportioned sector 309 and ~e sectors 307, 308 adjacent to the apportioned sector 309. The receive 3 0 antenna providing the highest signal strength corresponds to the sector 307, 308 or pair of portions 313-314 in which the commllnic~tion unit 305 might be located. As illustrated in FIG. 3, the commlmic~tion unit 305 is currently resident in portion 314 of the pair of portions 313-314. To identify which portion 314 of the 3 5 pair 313-314 ~e comml~lnic~tion unit 305 is in, ~e base site 301 then .
compares the received signal strengths for the uplink sign~l~ 334 received by the receive ~nt~nn~ serving the pairs of portions 311-312, 315-316 that are adjacent to the pair of portions 313-314 in which the comm-lnication unit 305 is located.
s When the signal strength of the uplink signal 334 received by the receive ~.-te~ serving portions 311-312 is greater than the signal strength of the uplink signal 334 received by the receive ~ntenn~ serving portions 315-316, the base site 301 dete.rmines that 1 0 the commlmication unit 305 is located in portion 313 of the identified pair of portions 313-314 and tr~n~mit~ a downlink commllnication signal to the commlmic~tion unit 305 using narrow beam ~lte~ a pattern 319. In a simil~r m~nn~r, when the signal strength of the uplink signal 334 received by the receive ~nte.nn~
1 5 sening portions 315-316 is greater than the signal strength of the uplink signal 334 received by the receive 5~-~te~ sening portions 311-312 (as is the case shown in FIG. 3), the base site 301 dete. .-.i..es that the commllnication unit 105 is located in portion 314 of the itlentified pair of portions 313-314 and tr~n~mit~ the downlink 2 0 commlmication signal to the commlmication unit 305 using narrow beam ~nte.nn~ pattern 320.
When the signal strength of the uplink signal 334 received by the receive ~ e.~ serving portions 311 -312 is approxim~tely equal 2 5 to the signal streng~ of the uplink signal 334 received by the receive ~nte.nn~ sening portions 315-316, ~e base site 301 might tietç..~ .P
that the co--"-,-~.ic~tion unit 305 is in an overlap region 330 of the two narrow bearn ~..te....~ p~tternc 319, 320 and, therefore, might tr~n~mit the downlink commllnication signal to the commllnication 3 0 unit 305 using both narrow beam ~..tç....~ p~ttern~ 319, 320. In a preferred embo~limçnt, the downlink commlmic~tion signal tr~n~mitted using narrow beam ~ pattern 320 is decorrelated, prior to tr~n~mi~sion~ with respect to the downlink commlmic~tion signal tr~n.emitte~l using narrow beam st~te~ pS~ttçlTl 319 to provide 3 5 sufficient coverage in the overlap region 330. Decorrelation of the downlink commllnic~tion sign~l~ is preferably accomplished by delaying one downlink signal by a predete.rmin~l interval of time with respect to the other as detailed below.
s In the above discussion, the commllniration unit 305 was centrally located in the apportioned sector 309 and the co~ ..ic~tion unit's approximate location was (1etermin~ by comparing signal strengths of uplink si n~l~ 334 received by receiving ~nt~nn~ serving the apportioned sector 309. However, if 1 0 in an ~ltern~te embodiment, the commllnic~tion unit 305 is located, for example, in portion 316, the base site would then co~ e the signal strength of the uplink signal 334 received in sector 308 with the signal strength of the uplink signal 334 received by the receiving ~nttq.nn~ serving portions 313-314 of the apportioned sector 309 to 1 ~ deterrnine whether the commllnication unit is located in por~on 315, portion 316, or in overlap region 332.
The tr~n~mi.~ n of common system control inform~tion from the base site 301 to the commllniration units in the base site's 2 0 coverage area 303 is accomplished in a m~nner analogous to that described above with regard to FIG. 1, particularly within the apportioned sector 309. To tr~n~mit ~y~leln control inform~tion to the commlmic~tion units (e.g., 305) resident in sector 309, the base site 301 tr~n~mit~ a downlink control signal using all the narrow 2 5 beam ~ntenn~ p~ttern~ 317-322. This tr~n~mi.~sion is accomplished in a m~nnP.r simil~r to that lescribed above for the tr~n~mi~sion of a traf~lc signal into the overlap region 330 of portions 313, 314. That is, the tr~n~mi~sion of ~e downlink control signal into each portion 311-316 is ~referably decorrelated wi~ respect to the ~n~mi~sion 3 0 of the downlink control signal into an adjacent portion 311-316 in order to provide sufficient coverage to those conlmlmic~tion units located in the overlap regions 328-332.
FIG. 4 illustrates the base site 301 of FIG. 3 in accordance 3 5 with the present invention. The base site 301 comprises, inter alia, a ~ WO 96/07108 2 3L ~ 4 ~ ~ 5 PCT/US9S/08277 plurality of receive ~nte.nn~ 401-405, a plurality of transmit antennas 407-412, and a receiver 413. The receiver 413 is preferably co~ alable to the receiver 209 of FIG. 2. In this particular emborlime.nt, receive ~ntenn~ 401 comprises a directional s ~nte.I n~ having a narrow beam ~ntenn~ p~tte,rn that receives uplink commlmication si n~ from portions 311-312 of sector 309.
Receive ~.-te""~ 402 compri~es a directional ~ntenn~ having a narrow, beam ~nte,nn~ pattern that receives uplink commllnication sign~l~ from portions 313-314 of sector 309. Receive ~nte.nn~ 403 1 0 compri~es a directional antenna having a narrow beam ~nte,nn~
pattern that receives uplink commllnication sign~l~ from portions 315-316 of sector 309. Receive ~ntenn~ 404, 405 comprise directional antennas that receive uplink commlmic~tion sign~l~ from sectors 307 and 308, respectively. Each receive antenna 401-405 1 5 might comprise one or more directional ~nte,nn~ depe.n~ling on whether diversity techniques are employed.
In an analogous m~nner, tr~n~mit ~l~telll~7/ 407 comprises a directional ~nte,nn~ having narrow beam ~ntenn~ p~ttern 317 that 2 0 tr~n~mh~ downlink commlmic~tion ~i n~ into portion 311 of sector 309, while tr~n~mit ~.. t~.. ~ 408 comprises a directional antenna having narrow beam ~ntenn~ p~ttern 318 that tr~n~mits downlink co~ l,lic~tion sign~l.c into portion 312 of sector 309. Tr~n~mit ~.,te,."~ 409 co~ ises a directional ~nte.Im~ having narrow beam 2 5 ~ntenn~ p~tte,m 319 that tr~ncmits downlink commnnicc~tion si n~l~
into portion 313 of sector 309, while tr~n~mit ~nte,nn~ 410 comprises a directional ~nte,nn~ having narrow beam ~nt~nn~ pattern 320 ~at tr~n~mits downlink co~ .ication si~n~ls into portion 314 of sector 309. Tr~ncmit ~ e~ 411 comprises a directional ~.~te....~ having 3 0 narrow beam ~nte,nn~ pattern 321 that transmits downlink commllnic~tion sign~ into portion 315 of sector 309, while transmit antenna 412 conlprises a directional ~ntt~,nn~ having narrow beam antenna pattern 322 that tr~n~mits downlink commllnic~tion ~i n~l~
into portion 316 of sector 309. As illustrated in FIG. 3, the tr~n~mit WO96/07108 ~ 7~$ 20 PCT/US95/08277 ~--~nte.nn~ 407-412 together form a wide beam antenna pattern that subst~nti~lly covers the apportioned sector 309.
Reference to FIG. 3 will be made hereinbelow as n~cess~ry to 5 facilitate an underst~n~ling of the invention. When the commllnication unit 305 tr~ncmit~ an uplink traffic signal 334 from portion 314 of sector 309, the uplink signal 334 is received by ~e receive antennas 401-405. Each received signal is then individually provided to the receiver 413. The receiver 413 compares the signal 1 0 strengths of the received sign~l~ to determine an approxim~te loc~tion of the commllnic~tion unit 305 and to ill~.ntify the ap~ro~liate portion 314 of the apportioned sector 309 to tr~ncmit into, as discussed above with regard to FIG. 3. Once the appro~liate portion 314 is icl~ntifie~ the receiver 409 directs a switch 414, via a 1 5 control line 415, to provide a downlink traffic signal or dedicated control signal to the tr~ncmit ~.~te.~ 410 that serves the identifie portion 314. The selected ~ntenn~ 410 then conveys the downlink signal to the co".",l~.~ication unit 305 in the identifi~.~l portion 314.
2 0 To tr~n~mit common system control si~ from the base site 301 into the apportioned sector 309, the base site 301 l.refelably decorrelates the common control signal provided to tr~ncmit ~nte.nn~ 408, 410, 412 with respect to the common control signal provided to tr~n~mit ~ntenn~ 407, 409, 411. In a preferred 2 5 embodiment, this decorrelation is perfolmed by delaying the common control ~ign~l~ provided to tr~n~mit ~ntenn~ 408, 410, 412 by a predete,.,li"e~l interval of time--e.g., one PN chip for a DS-CDMA control signal--using delay devices 416-418. In an ~1~P.rn~te embo~lim~nt, ~ litional delay devices (not shown) might be 3 0 incorporated to introduce a unique delay for each common control signal. Each delay device 416-418 might comprise a microwave delay line or shift register delay line, as discussed above with regard to FIG. 2. The decorrelation of the common control ~ign~ls provided to ~ltern~tinp antennas 408, 410, 412 insures sufficient 3 5 coverage of the apportioned sector 309, especially in the overlap WO96/07108 217 ~ 7 65 PCT/US95/08277 regions 328-332, by minimi7in~ the probability for destructive intelrelence of the common control ~i n~l~ in any portion 311-316 of the sector 309.
S In a preferred embo~lim~-nt, the downlink common control signal is s~lmme~l with the downlink traffic signal in a respective snmrner 419-424 prior to being provided to the a~ro~liate tr~ncmit ~..te"..~ 407-412. Such an approach allows the downlink common control si n~l~ to be routed to the complete sector 309, while the 1 0 downlink traffic signal is routed only to the selected portion (e.g., 314).
FIG. 5 illustrates a base site ~ntenn~ tower 500 that supports a receive ~..te.-"~ structure and a tr~ncmit ~.~te.~ structure for each 1 5 sector of a base site's sectori7e~ coverage area in accordance with the present invention. Each receive ~ntenn~ structure ~r~ferably comprises a plurality of directional receive ~llte~ ; (e.g., 501-504 and 508, 509) that receive uplink commlmic~tion ~ign~l~ from a particular sector of ~e base site's coverage area. As depicted in 2 0 FIG. 5., receive ~.~te....~ 501, 503 provide diversity reception to one portion of a first sector of the coverage area, while receive ~.,ten.
502, 504 provide diversity reception to another portion of the first sector. Simil~rly, receive ~te~ as 508, 509 provide diversity reception to a second sector of the coverage area.
Each tr~n~mit ~ntenn~ structure might comprise one or more tr~n~mit ~.~te.~ 510-513, as shown. In a preferred embo~lim~nt, the tr~n~mit ~..t~,..-~ structure comprises a plurality of directional tr~n~mit ~..te....~ 511-513 (as discussed above with regard to FIGs.
3 0 1-4) that are used to tr~n~mit downlinl~ co-...---.~.ir~tion sign~l~ to respective portions of a first sector of the coverage area. Thus, in the ~refelled embo~lim~nt, each tr~n~mit ~ntenn~ 511-513 has an ~ntenn~ pattern with a beamwidth (e.g., 40 degrees) narrower than an angular width (e.g., 120 degrees) of the first sector. In an 3 s ~lt~ tç embodiment, the tr~n~mit ~ntenn~ structure might comprise WO96/07108 21 74 7~ ~ 22 PCT/US95/08277 ~
a single ~ntenn~ 510 that independently tr~n~mit~ to each portion of a second sector. In this embo~lim~-nt~ the single ~ntçnn~ 510 preferably comprises a well-known steerable beam ~nt~Im~
S FIG. 6 illustrates a logic flow diagram 600 of steps executed by a base site in accordance with the present invention. The logic flow begins (601) when the base site receives (603) an uplink commlmication signal from a comm-lni~ ~tion unit with mllltiple receive antennas at the base site. In a preferred emborlimçnt, ~e multiple receive antennas comprise the one or more receive ~ntenn~c (depen-lin,~ on whether diversity is used) that receive cign~l~ from each sector of the base site's sectori7~1 coverage area. In an alternate embo~lim~ont, the multiple receive ~ntenn~ might comprise the one or more receive ~ntenn~ that receive ~ign~lc from each l S portion of an apportioned sector of the base site's coverage area.
Upon receiving the uplink signal with each receive ~-~te""~, the base site determines (605) an approximate location of the commllni~tion unit within a first portion of a particular sector of 2 0 the base site's coverage area based on a co~ ison of the uplink sign~lc received by the mlllt;ple receive ~lltellll~s. The base site preferably measures the signal strengths of the received si~ and determines the particular sector that the commllni~tion unit is in based on which receive ~lltel~ , or collection of receive antennas 2 5 (e.g., those serving an apportioned sector), provides the uplink signal having the highest signal strength.
Once the particular sector is identifie~l, the base site compares the signal strengths of the sign~l.c received from the sectors adjacent 3 0 to the particular sector, as discussed above with regard to FIGs. 1 and 2, to determine which portion of the particular sector the commlmic~tion unit is currently located in. In an ~ltern~te embo~lim~n~, as discussed above wi~ regard to FlGs. 3 and 4, ~e base site might compare ~e signal strengths of the si~ received -_ WO 96tO7108 PCT/US95/08277 ~t~7~
from portions of the particular sector that are adjacent to the portions in which the coInmlmic-~tion unit might be located.
Upon determinin~ the approximate location of the 5 commlmic~tion unit, the base site determine~ (607) whether the downlink signal to be tr~n~mitte~ to the co~ ic~tion unit is a lic~te~l control sign~l~ a traffic ~i n~l, or a common system control signal. When the downlink signal is a common system control sign~l, the base site decorrelates (609) the control signal 10 provided to each l~ ..te.~ serving a respective portion of the particular sector. The base site then tr~n~mit~ (611) the control signal into the particular sector using the tr~n~mit ~ntenn~ and the logic flow ends (617).
When the signal to be tr~n~mitted is a traffic signal or a ted control ~ign~l, the base site routes (613) the downlink signal to the tr~n~mit ~nt~nn~ serving the h~pl~liate portion of the particular sector (i.e., the portion in which the commlmic~tion unit is resit1e-nt). The base site tr~n~mit~ (615) the downlink signal to the 2 0 co.~-.-5l.-.ic~tion unit using ~e selected sl.~te....5l and the logic flow ends (617).
FIG. 7 illustrates a logic flow diagram 700 of steps executed to receive an uplink co...~ ic~tion signal at a base site in accordance 2 5 with the present invention. The logic flow be~in~ (701) when the base site receives (703) an uplink commllnication signal from a first portion of a sector to produce a first received signal and receives (705) an uplink co~ ..ication signal from a second portion of a sector to produce a second received si~n~l. In a preferred 3 0 emborliment, each uplink signal is received via a narrow beam directional ~ntenn~ serving the respective portion of ~e sector.
Upon receiving the uplink si~n~l~, the base site decorrelates (707) the second received signal with respect to the first received 3 5 si~n~l This decorrelation is preferably accomplished by delaying WO 96/07108 PCT/US95/08277 ~
~?7 ~ 7~ 2~
the second received signal by a predetermined time interval with respect to the first received si n~l, as discussed above with regard to FIG. 2. The decorrelated sign~l~ are then combined (709) and provided to a receiver at the base site, and the logic flow ends (711).
5 Since the received si n~l.c are decorrelated prior to submission to the receiver, the receiver can distinguish each received signal by the imposed time delay. Such a techni~lue of ~icting~ hin~ decorrelated sign~l~ is often denoted "raking." Thus, by ex~l-.;";~g the decorrelated si~n~ls, the base site can dete"--;.,e which portion of the 10 sector the co""~ "ication unit is located in and, if so desired, tr~n~mit a responsive downlink signal into the iclentified portion, as described above. This approach effectively improves the reverse ch~nnel capacity of the sector by limiting the power received from any particular portion. By limitin~ the reverse ch~nnel power, 15 uplink inlelrelt;llce is proportionally reduced in each portion of the apportioned sector. The amount of reverse channel capacity improvement is proportional to the number of transmit ~nter~n~
employed at the base site to cover the apportioned sector.
2 0 The present invention encomp~ses a method and apparatus for conveying a commlmication signal between a commllnic~tion unit and a base site that services a sectorized coverage area in a co"~ ,-iç~tion ~yslelll. With this invention, a downlink signal can be directionally tr~n~mitte~l from the base site to the commlmication 2 5 unit upon determinin the co~nmlmication unit's appro~imate location, thereby re~luc-ing the amount of rOl ~var~ ch~nnel interference and noise perceived by the commlmic~tion unit during the tr~n.~micsion and effectiveiy increasing the fol~v~d ch~nnel capacity of the base site's coverage area as compared to the prior art.
3 0 Conversely, an uplink co.-,.-,lication signal can be directionally received from the commnnication unit by the base site, thereby reducing the amount of reverse ch~nnel intelre~ ce and noise perceived by the base site during the tr~nsmi.csion and effectively increasing the reverse c~nnel capacity of the base site's coverage 3 5 area. Fur~er, the present invention facilitates the use of lower ~7~765 power ~mrlif;ers at the base site since less power is needed to obtain coverage at the fnnge of a sector when using narrow beam trans_it ~ntçnn~
S What is cl~im~A is:
WO 96/07108 217 4 7 6 5 PCT/US95/08277~
are ~l~terrnine~l by the desired ch~nnt-.l reuse pattern for ~e c~-llular ~y~
To maximize capacity, without degrading signal quality due to S an ablm~l~nce of co-ch~nnel inl~. re~llce and noise, cellular systems typically employ r-h~nnel reuse p~ttern~ of four and seven. In a four cell reuse p~ttern, all the allocatable channels (i.e., those used for two-way commlmications) are divided into four sets, one set for each cell. Simil~rly, in a seven cell reuse p~ttern, all the alloc~t~blç
10 ch~nnels are divided into seven sets. However, to m~int~in a desired signal quality (e.g., a carrier-to-interference plus noise, C/I+N, of 17 dB), each cell in a four cell reuse p~ttern is typically divided into six 60 degree sectors; whereas, each cell in a seven cell reuse pat~ern it typically divided into three 120 degree sectors. Once a cell is 15 sectorized, the particular set of ch~nn~ols ~signlod to ~at cell is ~imil~rly partitioned, such that each sector in the cell is ~signed its own subset of the ch~nnels allocated to the cell. The channel partitioning within a cell is typically performed to ,.~i,.i..~i7e cochannel intelrerc;llce, adjacent rh~nnel l~telrt;l~ce, and noi~e in 2 0 accordance with known techniques.
To provide adequate coverage at the cell boundary, each base site typically employs high power tr~n~mitters. The power of each tran~mitter is dependent upon the sectorization of a cell. For 2 5 example, a higher power tr~n~mitter is necessary for a 120 degree sector than for a 60 degree sector in order to m~int~in a desired signal level along the sector boundary due to the higher directivity of of an antenna having a 60 degree half power beamwidth (HPBW) as compared wi~ an ~n~eIln~ having a 120 degree HPBW.
As is known, cells in a cellular system are typically hexagonal in shape. Thus, each cell has six neighboring cells. The area near the border between any two cells is generally known as the fringe area, or handoff region, of a cell. Therefore, when a 3 5 commllniç~tion unit is commllnicating and enters the fiinge area of ~ WO 96/07108 2~ :1 7 ~ 7 6 5 PCT/USg5/08277 its host cell, the base site for the host cell might hand off the commlmic~tion to a base site serving one of the neighboring cells.
As is also known, ce~ r co~ l..ication systems use S sign~lling access form~t~, such as TDMA, FDMA, and code division multiple access (CDMA), to convey co,..~ tion sign~l~ between commnnic~tion units and their servicing base stations. In a CDMA
system, all co-~ ic~tion units in the ~y~ tr~ncmit uplink commlmication si n~l~ to their respective base station in a common 10 reverse ch~nnel bandwidth. However, each uplink commllnic~tion signal is associated with the serving base station by the inclusion of a pseudo-noise (PN) sequence (in direct sequence CDMA) or by a predetermined frequency hopping pattern (in slow or fast frequency hopping CDMA). The PN sequence and the frequency hopping 15 pattern permit the base station to identify which uplink sign~l~ are intended for reception by the base station's receiver. In a simil~r m~nner, each base station tr~n~mit~ downlink commlmic~tion sign~l~
to the commllnic ation units in its coverage area in a common forward channel bandwid~.
The discovery and technical advances associated with the advent of CDMA has pPrmitte(l cell~ r system lesi ners to begin using one cell and one sector ch~nnel reuse p~ttern~. One cell ch~nnel repeat p~ttern~ have been ~l~e~ .t~d in FDMA and TDMA
2 5 cellular systems; however, such ~llel~l)t~ have required that the systems operate at degraded signal quality levels (e.g., at a C/I+N of 13 dB). By contrast, CDMA one cell and one sector repeat p~ttern~
generally can m~int~in acceptable signal quality levels.
3 0 In a one sector CDMA reuse configuration, each sector reuses the same channels as its neighboring sectors, as opposed to partitioning the allocatable ch~nnels as in o~er sectorization sch~mes. However, a problem arises in a CDMA ~y~ ll using a one sector ch~nnel reuse pattern when a col"",ll,.ication unit is located in 3 5 the handoff region between two or more sectors. When the WO 96/07108 PCT/US95/08277 ~
~7~7~ 4 commlmication unit is in the handoff region, it .eimlllt~neously receives downlink commlmication sign~e from two or more base station tr~n~ el~s. Consequently, the commllnication unit is also receiving the noise, co-ch~nnel inte relellce, and adjacent channel 5 interference generated in the co_mon fol ~ard channel bandwidth by the base stations since each base station is tr~nemittinp to its respective sector using a tr~nemitter that provides adequate coverage at the sector boundary. Thus, the commnni~tion unit often cannot distinguish the downlink commllnic~tion sign~le from the 10 interference and noise. This indistinguishability results in poor signal quality, dropped calls, and limitetl capacity of the CDMA
system due the fo~ çh~nnel degradation at the fringe areas of the cells.
1 5 A ~imil~r problem arises at the base station due to poor signai-to-noise performance in the common reverse channel bandwidth of a CDMA system when the commlmi~ation unit is in the fringe area of a cell. The base station receives uplink commllniç~tion sign~l~ from comm~lnication units in it's respective sector and from 2 0 commllnic~tion units in fringe areas of neighboring sectors. Thus, if the commllnic~tion unit does not have enough tr~n~mit power to overcome the total noise received by the base station, the base station cannot distinguish the comml-nis~tion unit's uplink signal from the noise.
Therefore, a need exists for a method and aypalatus for conveying a commllnication signal between a commlmication unit and a base site that services a sectorized coverage area. Such a method and apparatus that improves capacity in either the fol ~va~d 3 0 channel, the reverse ch~nnel, or both by reducing intelreLc;llce and noise in the respective channel would be an improvement over ~e prior art. r 3 5 Brief Description of the Drawings ~ WO96/07108 21 7 4 7 6 5 PCT/US9'S/08277 FIG. 1 illustrates a commllnic~tion system that might employ the present invçntion sFIG. 2 illustrates a base site in accordance with the present invention.
FIG. 3 illustrates an ~ltern~te co"~",ll..ic~tion system that might employ the present invention FIG. 4 illustrates an ~ltern~te base site in accordance with the present invention.
FIG. S illustrates a base site ~ntenn~ tower that supports a 15 receive antenna structure and a tr~n~mit ~-,te""~ structure for each sector of a base site's sectori7e~1 coverage area in accordance with the present invention.
FIG. 6 illustrates a logic flow diagram of steps executed by a - 2 0 base site to tr~n~mit a downlink commllnic~tion signal in accordance with ~e present inven~ion FIG. 7 illustrates a logic flow diagram of steps executed to receive an uplink co"""ll..ic~tion signal at a base site in accordance 2 5 with the present invention 3 0Description of a PrefelTed Embo-lime.nt Generally, the present invention encomp~ses a method and apparatus for conveying a comm-lnic~tion signal between a commllnic~tion unit and a base site that services a sectori_ed 3 5 coverage area in a commlmic~tion system. The co.~ ...ic~tion unit WO96/07108 2~ ~ 7~5 6 PCT/U595/08277 ~
transmits an uplink commllnication signal to the base site. The base site receives the uplink commllni~tion signal and determin~s an approximate location of the commllnic~tion unit within a first portion of a sector of the sectQri~ecl coverage area. A downlink S comml-nic~tion signal is then tr~ncmittetl to the comm~-nic~tion unit based on the approximate location of the commlmir.ation unit using an ~ntenn~ structure that produces a beamwidth narrower than an angular width of the sector. By conveying the commllniç~tion signal in this m~nn~r, the present invention effectively reduces the quantity 1 0 of noise and interference received by a commllnir.ation unit in the fringe area of a sector, thereby improving the signal quality of the comm~mic~tion signal received by the coInmlmic~tion unit in the fringe area. Such a signal quality improvement results in an increase in the forward ch~nn~l commlmis~tion capacity of the sector.
The present invention can be more fully described with refer~llce to FIGs. 1-7. FIG. 1 illustrates a comml~nication ~y~l~m 100 that might employ the present invention. The commllni~.ation system 100 comprises a commlmic~tion unit 105 and a base site 101 2 0 that services a sectorized coverage area 103. The coInmllnication sy~lelll 100 ~lefelably comprises a spread spec~um commlmication system, such as the direct sequence CDMA (DS-CDMA) ~y~m set forth in Telecommllnic~tions Industry Association/Electronic Industries Association Tnterim St~ndard 95 (TIA/EIA/IS-95) or a 2 5 frequency hopping system, such as those proposed for the (lQmestic Personal Commllnirations System (PCS). In an ~ltern~te embodiment, the commnnic~ation system might comprise a TDMA
commllnication ~y~ , such as those set for~ in EIAmA/IS-54 and the Global System for Mobile (GSM) commllnic~tions, or an FDMA
3 0 system, such as that set forth in TIA/EIA/IS-91. The co"""l."ication unit 105 preferably comprises a mobile or portable radiotelephone, although other types of two-way commnnicating devices might be ~ltern~tively used. The base site 101 is described in detail below with regard to FIG. 2.
~ WO 96/07108 . . ~ PCT/US95/08277 7 2~7~
As generally mentioned above, the coverage area 103 of the base site 101 is divided into a plurality of sectors 106-108 (three shown). In a ~r~felled embodiment, each sector 106-108 occupies approxim~tely 120 degrees of the coverage area 103; however, other 5 sectorization schPmes (e.g., six 60 degree sectors) might be ~ltenl~tively employed. As shown in the FIG., sector 106 is adjacent to one side, or boundary 121, of sector 108 and sector 107 is adjacent to another boundary 122 of sector 108. In the depicted embodimçnt, sector 108 is further divided into a plurality of 1 0 portions 110, 111 (two in ~is particular case). However, in a ~refel.ed embo~liml nt, all sectors 106-108 of the coverage area 103 are apportioned simil~r to sector 108. The base site 101 serves each portion 110, 111 of sector 108 with a corresponding narrow beam ~ntenn~ pattern 115, 117.
Conveyance of a commlmic~tion signal between the base site 101 and the commlmic~ion unit 105 in accordance with the present invention is generally performed in the following m~nner. It is assumed for the puIpose of this discussion ~at ~e c(~ tion 2 0 unit 105 is registered in the co"..~ ic~tion system 100 and is being serviced by the base site 101. When the commllnic~tion unit 105 desires to commnnicate, the co~ tion unit 105 tr~n~mi~ an uplink traffic co"""l."ic~tion signal 113 (e.g., a voice or data signal) to the base site 101. The base site 101 receives the uplink 2 5 commllnic~tion signal 113 from receive ~"tel."~ that service each sector 106-108. Each sector 106-108 might be served by one or more receiving ~ntenn~ depel ~ing on the system configuration (e.g., two ~ntenn~ per sector 106-108 is a common configuration when using diversity reception).
Upon receiving the uplink co~ ,-ic~tion signal 113, the base site 101 determin~s an approximate location of the commnnication unit lOS by preferably comparing the uplink sign~l~ 113 received from each sector 106, 107 of the coverage area 103 that is 3 5 subst~nti~lly adjacent to the sector 108 in which the commllnic~tion W O 96/07108 2 ~ 7 ~ 7 6 ~ PCTrUS9~/08277 -unit 105 is currently resi-l~nt- In a preferred embodiment, the comparison is performed on the signal strengths of the received uplink sign~l.c 113, although the comparison could be performed using other signal quality metrics, such as bit error rate, word error 5 rate, or carrier-to-interference plus noise ratio.
When the signal strength of the uplink signal 113 received in sector 107 is greater than the signal strength of the uplink signal 113 received in sector 106, the base site 101 dete. ,.-i,.es ~at the 1 0 commllnir.ation unit lOS is located in portion 111 of sector 108 and tr~ncmits a downlink co~ "ic~tion signal (e.g., a traffic signal or a dedicated control signal) to the commllnication unit lOS using narrow beam antenna pattern 117. In a simil~r m~nner, when the signal strength of the uplink signal 113 received in sector 106 is 1 S greater ~an the signal strength of the uplink signal 113 received in sector 107, the base site 101 determines that the commlmi~tion unit 105 is located in portion 110 and tr~n.cmi~c the downlink conlmllnir,~tion signal to the comm-~nic~tion unit lOS using narrow beam antenna p~ttern l lS.
When the signal strength of the uplink signal 113 received in sector 106 is approxim~tely equal to the signal strength of the uplink signal 113 received in sector 107, the base site 101 might determine that the co~"",~ ication unit lOS is in an overlap region 119 of the 25 two narrow beam ~.-te""~ p~tternc llS, 117 and, ~erefore, might tr~n.cmit the downlink co"""l..,ication signal to the commllni~tion unit lOS using both narrow beam s~tC~ p~tternC l lS, 117. In the ~ref~lled embo-limPnt, the downlink commllnir.~tion signal tr~ncmitte~l using narrow beam ~lltel ~ p~ttern l lS is decorrelated, 3 0 prior to tr~ncmicsion, wi~ respect to the downlink commllnication signal tr~ncmitte-l using narrow beam antenna pattern 117 to provide sufficient coverage in the overlap region 119 (i.e., to minimi7.e ~e probability for destructive interference of the downlink co"-~ "ic~tion signal). Decorrelation of the downlink 3 5 cornmimi~.~rion si~n~l~is ~l~fel~bly accomplished by deiaying one downlink signal by a predetermined interval of time with respect to the other as detailed below.
In an ~ltern~te embo~lim~-nt, the commlmir~tion unit 105 might S include a global positioning satellite (GPS) receiver to dete~ i"e the commnnic~tion unit's location within the coverage area 103. In such an embodiment, the commllnic~tion unit 105 tr~n~mit~ its location to the base site 101 and the base site 101 subsequently tr~n~mit~ the downlink co,,l~ ic~tion signal into the portion (e.g., 111) of the 10 sector 108 in which the commllnication unit 105 is currently resitlent. The use of a GPS receiver in a commllnic~tion unit for determining a location of the co"""l.,.ication unit is described in detail in U.S. Patent No. 5,235,633, çntitl~l "Cellular Telephone System That Uses Position Of A Mobile To Make Call Management 15 Decisions" and incorporated herein by r~fer~llce. Thus, no further explanation will be provided except to facilitate an underst~n-lin~ of the present invention.
As illustrated in FIG. 1, each narrow beam ~"te,.,.~ pattern 2 0 115, 117 in this particular embo~lim~nt occupies approximately one-half, or 60 degrees, of sector 108, although other sector partitioning schemes (e.g., a 100 degree portion and a 20 degree portion) might be ~ltern~tively employed. However, in contrast to prior art sectorization schemes, each portion 110, 111 of sector 108 can utilize 2 5 all the channels allocated to sector 108 instead of requiring disjoint ch~nnel ~si nments in each portion 110, 111 as is the case with prior art sectorization.
The above discussion generally pe~ s to the conveyance of 3 0 traffic commllnication sign~l~ (e.g., voice or data) and de~lic~te~l control ~i~n~l~--e.g., those used to inform the comm-lnication unit 105 of system conditions, such as handoff, particular to the commlmi~ ~tion unit 105--between the base site 101 and the commllnic~tion unit 105. However, the tr~n~mi~sion of common 3 5 system control inform~tion from the base site 101 to the WO 96/07108 217 4 ~ ~ 5 lo PCT/US95/08277 --commlmication units in the base site's coverage area 103 should also be considered, particularly within the apportioned sector 108. To tr~nemit common system control information to the commllnication units (e.g., 105) resident in sector 108, the base site 101 tr~nemite a S downlink common control signal using both narrow beam ~ntenn~
p~tte.rne 115, 117. This tr~nemi.esion is accomplished in a m~nn~r eimil~r to that described above for the tr~nemiesion of a traffic signal into the overlap region 119 of portion 108. That is, the tr~nemiesion of the downlink common control signal into portion 111 is 10 preferably decorrelated with respect to the tr~nemi.esion of the downlink common control signal into portion 110 in order to provide sufficient coverage to those comm-mir.ation units located in the overlap region 119.
In a preferred embodiment, the tr~n~mit power used to tr~n~mit the directional downlink si~ into the respective portions 110, 111 of sector 108 is less than that typically used to tr~n~mit downlink si n~l~ to the complete 120 degree sector 108 due to the directionality of the narrow beam ~ntenn~ p~ttern~ 115, 117. Since 2 0 less tr~n.~mit power is required to service a commllnication unit 105 in a particular portion (e.g., 111) of the base site's coverage area 103, correspondingly less interference and noise is introduced into the fringe areas of the other portions 110 of the coverage area 103, especially when the commllnic~tion system 100 is a DS-CDMA
2 5 ~ys~ . By introducing lower interference and noise levels into the various portions 110, 111 of ~e apportioned sector 108, the overall forward ch~nnel (base site 101 to commllnication unit 105) capacity of the sector 108 is increased as compared wi~ the forward ch~nnel capacity of prior art sectorized coverage areas. Consequently, the 3 0 present invention facilitates the lltili7.~tion of a one sector channel reuse pattern, without reducing the capacity in each sector due to increased interference and noise in the handoff regions (fringe areas) between sectors, as in the prior art.
11 21~7~
.
FIG. 2 illustrate,s the base site 101 of FIG. 1 in accordance with the present invention. The base site 101 comprises, inter alia, a plurality of receive ~-,te,""~ 201-204, a plurality of transmit ~ntenn~ 206, 207, and a receiver 209. In this particular S embo-lim~,nt, receive ~nteTln~ 201 comprises a directional ~ntenn~
having narrow beam ~nt~,nn~ pattern 115 that receives uplink commllnis~tion si~n~l~ from portion 110 of sector 108. Receive ~nte,nn~ 202 comrri~es a directional antenna having narrow beam ~ntçnn~ pattern 117 that receives uplink commlmic~tion ~ from 1 0 portion 111 of sector 108. Receive ~nte,nn~ 203, 204 comprise directional ~.,t~ that receive uplink CO~ ,-.. ic~tion sign~l~ from sectors 106 and 107, respectively. Each receive ~l~tellll~ 201-204 might comprise one or more directional ~nte,nn~ depentling on whether diversity techniques are employed.
In an analogous m~nner, tr~n~mit ~ tel.ll~ 206 comprises a directional ~ntenn~ having narrow beam ~,lte".l~ p~ttern l lS that tr~n~mit~ downlink commllnic~tion si~n~l~ into portion 110 of sector 108, while tr~n~mit ~"te,.~-~ 207 comprises a directional antenna 2 0 having narrow beam ~ntenn~ p~ttern 117 that tr~n~mit~ downlink commllni~,ation sign~ into portion 111 of sector 108. However, as illustrated in FIG. 1, the tr~ncmit ~..te..,~ 206, 207 together form a wide beam ~nte,nn~ pattern that sulJ~ .ti~lly covers sector 108. In a preferred embotlim~nt, the receiver 209 comprises the known 2 5 electronic circ~ ,y (e.g., filters, amplifiers, demodulators, and proces~in,~ devices) n~cess~ry to receive DS-CDMA uplink ~i n~l~
and to measure and compare the signal strengths of those sign~
Reference to FIG. 1 will be made hereinbelow as necessary to 3 0 facilitate an underst~ntling of the invention. When the commllnic~tion unit 105 tr~n~mits an uplink traffic signal 113 from portion 111 of sector 108, the uplink signal 113 is received by the receive ~ntenn~ 201-204. Receive antennas 203 and 204 provide their rec,eived ~ign~l~ independently to the receiver 209; whereas, the 3 5 uplink sign~l~ 113 received by receive ~ntto,I~n~ 201, 202 are first WO 96/07108 PCTIUS95~27 ~747~5 decorrelated and then combined in a combiner 213 prior to being provided to the receiver 209. The decorrelation is ~lefelably accomplished using a delay device 217, such as a microwave delay line or a shift register delay line, that is inserted between one (e.g., 5 202) of the receive ~nteIln~ 201, 202 serving the apportioned sector 108 and the combiner 213. The delay device 217 delays the uplink signal 113 received by the one receive antenna 202 by a predetermined interval of time with respect to the uplink signal 113 received by the other receive ~.lte.~ 201 to decorrelate the two 1 0 received si~n~l.c. In a DS-CDMA system 100, the predetermine~l interval of time preferably comprises one PN chip (i.e., appro~cim~tely 800 nanoseconds). The decorrelation allows the receiver 209 to indepçndently demodulate each received uplink signal 113 in accordance with known techniques. However, since the 1 S uplink signals 113 received by receive ~ntenn~ 201, 202 are combined prior to submission to the receiver 209 in this embo-limPnt, the receiver 209 receives three uplink si~n~l~ 113 from one co"~".l",ication unit tr~ncmi~sion~ wherein each received signal corresponds to a particular sector 106-108.
In a preferred embo~limP-nt, upon receiving ~e three uplink si~n~l~, the receiver 209 determin~-s the approximate location (i.e., the portion 111 of the apportioned sector 108) of the co"~ "ication unit 105 by comr~rin~ the uplink si~ 113 received by receive 2 5 ~ntçnn~s 203 and 204. As discussed above, when the signal strength of ~e uplink signal 113 received by receive ~"te,...~ 204 is larger than the signal strength of the uplink signal 113 received by receive antenna 203, the receiver 209 dete",-i..es that the commlmic~tion unit lOS is located in portion 111 of sector 108. Simil~rly, when the 3 0 signal strength of the uplink signal 113 received by receive ~ntenn~
203 is larger than the signal strength of the uplink signal 113 received by receive ~nte.~n~ 204, the receiver 209 cleterrnines that ~e commlmic~tion unit lOS is located in portion 110 of sector 108.
Thus, in a preferred embocliment, the receiver 209, or at least a 3 ~ portion thereof, effectively becomes a means for iclentifying the WO 96/07108 13 21 7 4 7 6 S PCT/US9~i/08277 portion (e.g., 111) of the sector 108 to route the downlink traffic, or ~e~ic~te~l control, signal into based on the signal strength comparison. Once the ~plv~liate portion 111 is i~le.ntifie-l, the receiver 209 directs a switch 211 (e.g., a known tr~n~mi~sion gate 5 circuit), via a control line 212, to provide the downlink signal to the corresponding narrow beam tr~n~mit ~-.te.~ (e.g., 207) that serves the i~entified portion 111.
The selected tr~n~mit ~ntenn~ 207 then conveys the downlink 10 signal into the a~pr~liate portion 1 1 1 of the sector 108. In this m~nner, the switch 211, the control line 212, and the tr~ncmit antennas 206, 207 collectively comprise selection means for routing the downlink signal into the ~r~liate portion 110 or portions 110, 111 of the sector 108 in which the commllnic~tion unit 105 is 1 5 currently resident.
In an ~1tern~tç embo~lim~nt, the receiver 209 might determine the approximate location of the comml-ni~tion unit 105 and, accordingly, which portion of the partitioned sector 108 to tr~n~mit 2 0 into based on signal strength me~c-lrem~nt~ made by ~e co"""l...ic~tion unit 105 of downlink commllnif~tion ~ign~l~
tr~n~mitte~l by the base site 101. In this case, the co.~....l...is~tion unit 105 measures the downlink signal received from the base site 101 and ~n~mits the me~.~llred signal strength inform~tion back to the 2 5 base site 101. Based on the commlmi~tion unit's me~cllremtQnts the base site 101 then dete..-~i..es whether ~e downlink signal is being tr~n~mittç~l into the proper portion 111 of the apportioned sector 108. This dete. ~ tioIl might be accomplished by co,~g the commnnication unit's measured signal strength to a predetermine~
3 0 threshold.
In yet another embodiment, the receiver 209 might determinP
the approxim~te location of ~e commlmic~tjon unit 105 based on signal strength measurement.~ made at another base site (not shown) 3 5 of the commlmic~tion system 100. In this emboclim~nt, the other 2i74765 base site measures the signal strength of the uplink signals 113 tr~n~mittetl by the commlmication unit 105. The other base site then conveys those measurements to a central location (e.g., base site 101) where the commllnic~tion unit's location is estim~teA using known S triaIlgulation techniques.
In a further embo~lim~nt, the receiver 209 might determine the approximate location of the commlmic~tion unit 105 based on signal strength measurem~nt~ made by the commllnic~ion UIlit 105 10 of downlink commllnir~ation si n~l~ tr~n~mitte-l by other base sites (not shown) in the co~ llir~tion ~ ~111 100. The commllnis~tion unit 105 then conveys these mP~ remlonts to a central location (e.g., base site 101) where the co""~,l"-ication unit's location is estim~te-l using known triangulation techniques.
To transmit common ~y~ control si~ from the base site 101 into the apportioned sector 108, as discussed above, the base site 101 preferably decorrelates the common control signal provided to one tr~n~mit ~ e",.~ 207 with respect to the common control signal 2 0 provided to the other tr~n~mit antenna 206. In a plef~lled embo(lim~nt, this decorrelation is performed by delaying the common control signal provided to tr~n~mit ~ntenn~ 207 by a predeterrnine~l interval of time--e.g., one PN chip for a DS-CDMA
control signal--using a delay device 221,such as shift register delay 2 5 line. In the ~lefell~d embo~lim~-nt, the downlink common control signal is summed with the downlink traffic signal in a respective sllm mer214,215 prior to being provided to the ~ro~liate ~nsmit ~ntt~nn~ 206,207. Such an approach allows the downlink common control si~n~l~ to be routed to the complete sector 108, while the 3 0 downlink traffic signal is directed only to the selected portion (e.g., 111).
As discussed above, receive ~I~te~ 201,202 receive the uplink comm-mication signal 113 from sector 108. However, since 3 5 ~e received ~ are combined prior to being provided to the ~17476S
receiver 209, they may not be usable in determinin~ the commlmication unit's approximate location. In an alternate emborlim~-nt, the base site 101 further includes a modulator for controlling the delay device 217 that performs the decorrelation.
S The mo~ tor 219 is used to mo~ te the delay--e.g., using a periodic modulation pattern--introduced by the delay device 217, thereby providing an i~le,ntifi~kle sign~tllre for the receiver 209 to recognize. Upon recogni7in~ the modulation pattern, the receiver 209 can detel,.lill~o, that the uplink signal was received from that 1 0 portion (e.g., 111) of the sector 108 served by the receive ~nte,nns~
202 whose received si n~l~ encounter a mo~llll~te-l delay prior to being provided to the receiver 209. In an analogous m~nner, when the receiver 209 receives an uplink signal from combiner 213 that is not mo~ te-l, the receiver 209 can determine that the uplink signal 1 5 was received from that portion '(e.g., 110) of the sector 108 served by the receive ~ntenn~ 201 whose received si n~l~ do not encounter the mo~ te~l delay.
In yet another embo~lime-nt, the uplink sign~l~ received by 2 0 receive ~ntenn~c 201, 202 might be indepe,ntl~,ntly provided to t,he receiver 209 to allow the receiver 209 to easily dete. ..~ , which portion 110, 111 of the sector 108 the commlmication unit 105 resides in. However, this embo~iim~nt increases the complexity of the receiver 209.
FIG. 3 illustrates an ~lte,rn~te commllnic~tion ~y~lelll 300 that might employ the present invention. The commllnic~tion system 300 comprises a commllnication unit 305 and a base site 301 that services a sectori~e~ coverage area 303. The commlmication system 300 3 0 might comprise any one of those ~y~lellls set forth above with regard to FIG. 1. The commlmit~.ation unit 305 preferably comprises a mobile or portable radiotelephone, although other types of two-way commlmic~ting devices might be ~ltem~tively used. The base site 301 is described in detail below with regard to FIG. 4.
The coverage area 303 of the base site 301 is divided into a plurality of sectors 307-309 (~ree shown) eimil~r to the coverage area 103 depicted in FIG. 1. As shown in the FIG., sector 307 is adjacent to one side, or boundary 324, of sector 309 and sector 308 S is adjacent to another boundary 326 of sector 309. Sector 309 is further divided into a plurality of portions 311-316 (six in ~is particular case). In a pleferred embo~lim~t, the base site 301 tr~n~mit~ to each portion 311-316 of sector 309 with a corresponding narrow beam ~ntenn~ pattern 317-322.
Conveyance of a traffic, or ~e~lic~teA control, signal between the base site 301 and the commlmic~tion unit 305 in accordance with this embo~limt nt of the present invention is generally performed in the following m~nner. When the commlmication unit desires to 1 5 commllnic~te, the commllnication unit 305 tr~ncmit~ an uplink commllni~tion signal 334 to the base site 301. The base site 301 receives ~e uplink signal 334 from receive ~ntenn~ that service the sectors 307, 308 adjacent to the apportioned sector 309 and from receive ~ntenn~s that service the apportioned sector 309. For 2 0 example, in this particular embo~liment, ~ree receive ~I~te~
service the apportioned sector 309, each antenna serving a pair (e.g., 311, 312) of the portions 311-316, as det~ rl below with regard to FIG. 4.
2 5 Upon receiving the uplink signal 334, the base site 301 determine~ an approximate location of the commlmic~tion unit 305 by preferably COl~illg the signal streng~s of ~e ~ign~l~ received by the receive ~llte~ serving the apportioned sector 309 and ~e sectors 307, 308 adjacent to the apportioned sector 309. The receive 3 0 antenna providing the highest signal strength corresponds to the sector 307, 308 or pair of portions 313-314 in which the commllnic~tion unit 305 might be located. As illustrated in FIG. 3, the commlmic~tion unit 305 is currently resident in portion 314 of the pair of portions 313-314. To identify which portion 314 of the 3 5 pair 313-314 ~e comml~lnic~tion unit 305 is in, ~e base site 301 then .
compares the received signal strengths for the uplink sign~l~ 334 received by the receive ~nt~nn~ serving the pairs of portions 311-312, 315-316 that are adjacent to the pair of portions 313-314 in which the comm-lnication unit 305 is located.
s When the signal strength of the uplink signal 334 received by the receive ~.-te~ serving portions 311-312 is greater than the signal strength of the uplink signal 334 received by the receive ~ntenn~ serving portions 315-316, the base site 301 dete.rmines that 1 0 the commlmication unit 305 is located in portion 313 of the identified pair of portions 313-314 and tr~n~mit~ a downlink commllnication signal to the commlmic~tion unit 305 using narrow beam ~lte~ a pattern 319. In a simil~r m~nn~r, when the signal strength of the uplink signal 334 received by the receive ~nte.nn~
1 5 sening portions 315-316 is greater than the signal strength of the uplink signal 334 received by the receive 5~-~te~ sening portions 311-312 (as is the case shown in FIG. 3), the base site 301 dete. .-.i..es that the commllnication unit 105 is located in portion 314 of the itlentified pair of portions 313-314 and tr~n~mit~ the downlink 2 0 commlmication signal to the commlmication unit 305 using narrow beam ~nte.nn~ pattern 320.
When the signal strength of the uplink signal 334 received by the receive ~ e.~ serving portions 311 -312 is approxim~tely equal 2 5 to the signal streng~ of the uplink signal 334 received by the receive ~nte.nn~ sening portions 315-316, ~e base site 301 might tietç..~ .P
that the co--"-,-~.ic~tion unit 305 is in an overlap region 330 of the two narrow bearn ~..te....~ p~tternc 319, 320 and, therefore, might tr~n~mit the downlink commllnication signal to the commllnication 3 0 unit 305 using both narrow beam ~..tç....~ p~ttern~ 319, 320. In a preferred embo~limçnt, the downlink commlmic~tion signal tr~n~mitted using narrow beam ~ pattern 320 is decorrelated, prior to tr~n~mi~sion~ with respect to the downlink commlmic~tion signal tr~n.emitte~l using narrow beam st~te~ pS~ttçlTl 319 to provide 3 5 sufficient coverage in the overlap region 330. Decorrelation of the downlink commllnic~tion sign~l~ is preferably accomplished by delaying one downlink signal by a predete.rmin~l interval of time with respect to the other as detailed below.
s In the above discussion, the commllniration unit 305 was centrally located in the apportioned sector 309 and the co~ ..ic~tion unit's approximate location was (1etermin~ by comparing signal strengths of uplink si n~l~ 334 received by receiving ~nt~nn~ serving the apportioned sector 309. However, if 1 0 in an ~ltern~te embodiment, the commllnic~tion unit 305 is located, for example, in portion 316, the base site would then co~ e the signal strength of the uplink signal 334 received in sector 308 with the signal strength of the uplink signal 334 received by the receiving ~nttq.nn~ serving portions 313-314 of the apportioned sector 309 to 1 ~ deterrnine whether the commllnication unit is located in por~on 315, portion 316, or in overlap region 332.
The tr~n~mi.~ n of common system control inform~tion from the base site 301 to the commllniration units in the base site's 2 0 coverage area 303 is accomplished in a m~nner analogous to that described above with regard to FIG. 1, particularly within the apportioned sector 309. To tr~n~mit ~y~leln control inform~tion to the commlmic~tion units (e.g., 305) resident in sector 309, the base site 301 tr~n~mit~ a downlink control signal using all the narrow 2 5 beam ~ntenn~ p~ttern~ 317-322. This tr~n~mi.~sion is accomplished in a m~nnP.r simil~r to that lescribed above for the tr~n~mi~sion of a traf~lc signal into the overlap region 330 of portions 313, 314. That is, the tr~n~mi~sion of ~e downlink control signal into each portion 311-316 is ~referably decorrelated wi~ respect to the ~n~mi~sion 3 0 of the downlink control signal into an adjacent portion 311-316 in order to provide sufficient coverage to those conlmlmic~tion units located in the overlap regions 328-332.
FIG. 4 illustrates the base site 301 of FIG. 3 in accordance 3 5 with the present invention. The base site 301 comprises, inter alia, a ~ WO 96/07108 2 3L ~ 4 ~ ~ 5 PCT/US9S/08277 plurality of receive ~nte.nn~ 401-405, a plurality of transmit antennas 407-412, and a receiver 413. The receiver 413 is preferably co~ alable to the receiver 209 of FIG. 2. In this particular emborlime.nt, receive ~ntenn~ 401 comprises a directional s ~nte.I n~ having a narrow beam ~ntenn~ p~tte,rn that receives uplink commlmication si n~ from portions 311-312 of sector 309.
Receive ~.-te""~ 402 compri~es a directional ~ntenn~ having a narrow, beam ~nte,nn~ pattern that receives uplink commllnication sign~l~ from portions 313-314 of sector 309. Receive ~nte.nn~ 403 1 0 compri~es a directional antenna having a narrow beam ~nte,nn~
pattern that receives uplink commllnication sign~l~ from portions 315-316 of sector 309. Receive ~ntenn~ 404, 405 comprise directional antennas that receive uplink commlmic~tion sign~l~ from sectors 307 and 308, respectively. Each receive antenna 401-405 1 5 might comprise one or more directional ~nte,nn~ depe.n~ling on whether diversity techniques are employed.
In an analogous m~nner, tr~n~mit ~l~telll~7/ 407 comprises a directional ~nte,nn~ having narrow beam ~ntenn~ p~ttern 317 that 2 0 tr~n~mh~ downlink commlmic~tion ~i n~ into portion 311 of sector 309, while tr~n~mit ~.. t~.. ~ 408 comprises a directional antenna having narrow beam ~ntenn~ p~ttern 318 that tr~n~mits downlink co~ l,lic~tion sign~l.c into portion 312 of sector 309. Tr~n~mit ~.,te,."~ 409 co~ ises a directional ~nte.Im~ having narrow beam 2 5 ~ntenn~ p~tte,m 319 that tr~ncmits downlink commnnicc~tion si n~l~
into portion 313 of sector 309, while tr~n~mit ~nte,nn~ 410 comprises a directional ~nte,nn~ having narrow beam ~nt~nn~ pattern 320 ~at tr~n~mits downlink co~ .ication si~n~ls into portion 314 of sector 309. Tr~ncmit ~ e~ 411 comprises a directional ~.~te....~ having 3 0 narrow beam ~nte,nn~ pattern 321 that transmits downlink commllnic~tion sign~ into portion 315 of sector 309, while transmit antenna 412 conlprises a directional ~ntt~,nn~ having narrow beam antenna pattern 322 that tr~n~mits downlink commllnic~tion ~i n~l~
into portion 316 of sector 309. As illustrated in FIG. 3, the tr~n~mit WO96/07108 ~ 7~$ 20 PCT/US95/08277 ~--~nte.nn~ 407-412 together form a wide beam antenna pattern that subst~nti~lly covers the apportioned sector 309.
Reference to FIG. 3 will be made hereinbelow as n~cess~ry to 5 facilitate an underst~n~ling of the invention. When the commllnication unit 305 tr~ncmit~ an uplink traffic signal 334 from portion 314 of sector 309, the uplink signal 334 is received by ~e receive antennas 401-405. Each received signal is then individually provided to the receiver 413. The receiver 413 compares the signal 1 0 strengths of the received sign~l~ to determine an approxim~te loc~tion of the commllnic~tion unit 305 and to ill~.ntify the ap~ro~liate portion 314 of the apportioned sector 309 to tr~ncmit into, as discussed above with regard to FIG. 3. Once the appro~liate portion 314 is icl~ntifie~ the receiver 409 directs a switch 414, via a 1 5 control line 415, to provide a downlink traffic signal or dedicated control signal to the tr~ncmit ~.~te.~ 410 that serves the identifie portion 314. The selected ~ntenn~ 410 then conveys the downlink signal to the co".",l~.~ication unit 305 in the identifi~.~l portion 314.
2 0 To tr~n~mit common system control si~ from the base site 301 into the apportioned sector 309, the base site 301 l.refelably decorrelates the common control signal provided to tr~ncmit ~nte.nn~ 408, 410, 412 with respect to the common control signal provided to tr~n~mit ~ntenn~ 407, 409, 411. In a preferred 2 5 embodiment, this decorrelation is perfolmed by delaying the common control ~ign~l~ provided to tr~n~mit ~ntenn~ 408, 410, 412 by a predete,.,li"e~l interval of time--e.g., one PN chip for a DS-CDMA control signal--using delay devices 416-418. In an ~1~P.rn~te embo~lim~nt, ~ litional delay devices (not shown) might be 3 0 incorporated to introduce a unique delay for each common control signal. Each delay device 416-418 might comprise a microwave delay line or shift register delay line, as discussed above with regard to FIG. 2. The decorrelation of the common control ~ign~ls provided to ~ltern~tinp antennas 408, 410, 412 insures sufficient 3 5 coverage of the apportioned sector 309, especially in the overlap WO96/07108 217 ~ 7 65 PCT/US95/08277 regions 328-332, by minimi7in~ the probability for destructive intelrelence of the common control ~i n~l~ in any portion 311-316 of the sector 309.
S In a preferred embo~lim~-nt, the downlink common control signal is s~lmme~l with the downlink traffic signal in a respective snmrner 419-424 prior to being provided to the a~ro~liate tr~ncmit ~..te"..~ 407-412. Such an approach allows the downlink common control si n~l~ to be routed to the complete sector 309, while the 1 0 downlink traffic signal is routed only to the selected portion (e.g., 314).
FIG. 5 illustrates a base site ~ntenn~ tower 500 that supports a receive ~..te.-"~ structure and a tr~ncmit ~.~te.~ structure for each 1 5 sector of a base site's sectori7e~ coverage area in accordance with the present invention. Each receive ~ntenn~ structure ~r~ferably comprises a plurality of directional receive ~llte~ ; (e.g., 501-504 and 508, 509) that receive uplink commlmic~tion ~ign~l~ from a particular sector of ~e base site's coverage area. As depicted in 2 0 FIG. 5., receive ~.~te....~ 501, 503 provide diversity reception to one portion of a first sector of the coverage area, while receive ~.,ten.
502, 504 provide diversity reception to another portion of the first sector. Simil~rly, receive ~te~ as 508, 509 provide diversity reception to a second sector of the coverage area.
Each tr~n~mit ~ntenn~ structure might comprise one or more tr~n~mit ~.~te.~ 510-513, as shown. In a preferred embo~lim~nt, the tr~n~mit ~..t~,..-~ structure comprises a plurality of directional tr~n~mit ~..te....~ 511-513 (as discussed above with regard to FIGs.
3 0 1-4) that are used to tr~n~mit downlinl~ co-...---.~.ir~tion sign~l~ to respective portions of a first sector of the coverage area. Thus, in the ~refelled embo~lim~nt, each tr~n~mit ~ntenn~ 511-513 has an ~ntenn~ pattern with a beamwidth (e.g., 40 degrees) narrower than an angular width (e.g., 120 degrees) of the first sector. In an 3 s ~lt~ tç embodiment, the tr~n~mit ~ntenn~ structure might comprise WO96/07108 21 74 7~ ~ 22 PCT/US95/08277 ~
a single ~ntenn~ 510 that independently tr~n~mit~ to each portion of a second sector. In this embo~lim~-nt~ the single ~ntçnn~ 510 preferably comprises a well-known steerable beam ~nt~Im~
S FIG. 6 illustrates a logic flow diagram 600 of steps executed by a base site in accordance with the present invention. The logic flow begins (601) when the base site receives (603) an uplink commlmication signal from a comm-lni~ ~tion unit with mllltiple receive antennas at the base site. In a preferred emborlimçnt, ~e multiple receive antennas comprise the one or more receive ~ntenn~c (depen-lin,~ on whether diversity is used) that receive cign~l~ from each sector of the base site's sectori7~1 coverage area. In an alternate embo~lim~ont, the multiple receive ~ntenn~ might comprise the one or more receive ~ntenn~ that receive ~ign~lc from each l S portion of an apportioned sector of the base site's coverage area.
Upon receiving the uplink signal with each receive ~-~te""~, the base site determines (605) an approximate location of the commllni~tion unit within a first portion of a particular sector of 2 0 the base site's coverage area based on a co~ ison of the uplink sign~lc received by the mlllt;ple receive ~lltellll~s. The base site preferably measures the signal strengths of the received si~ and determines the particular sector that the commllni~tion unit is in based on which receive ~lltel~ , or collection of receive antennas 2 5 (e.g., those serving an apportioned sector), provides the uplink signal having the highest signal strength.
Once the particular sector is identifie~l, the base site compares the signal strengths of the sign~l.c received from the sectors adjacent 3 0 to the particular sector, as discussed above with regard to FIGs. 1 and 2, to determine which portion of the particular sector the commlmic~tion unit is currently located in. In an ~ltern~te embo~lim~n~, as discussed above wi~ regard to FlGs. 3 and 4, ~e base site might compare ~e signal strengths of the si~ received -_ WO 96tO7108 PCT/US95/08277 ~t~7~
from portions of the particular sector that are adjacent to the portions in which the coInmlmic-~tion unit might be located.
Upon determinin~ the approximate location of the 5 commlmic~tion unit, the base site determine~ (607) whether the downlink signal to be tr~n~mitte~ to the co~ ic~tion unit is a lic~te~l control sign~l~ a traffic ~i n~l, or a common system control signal. When the downlink signal is a common system control sign~l, the base site decorrelates (609) the control signal 10 provided to each l~ ..te.~ serving a respective portion of the particular sector. The base site then tr~n~mit~ (611) the control signal into the particular sector using the tr~n~mit ~ntenn~ and the logic flow ends (617).
When the signal to be tr~n~mitted is a traffic signal or a ted control ~ign~l, the base site routes (613) the downlink signal to the tr~n~mit ~nt~nn~ serving the h~pl~liate portion of the particular sector (i.e., the portion in which the commlmic~tion unit is resit1e-nt). The base site tr~n~mit~ (615) the downlink signal to the 2 0 co.~-.-5l.-.ic~tion unit using ~e selected sl.~te....5l and the logic flow ends (617).
FIG. 7 illustrates a logic flow diagram 700 of steps executed to receive an uplink co...~ ic~tion signal at a base site in accordance 2 5 with the present invention. The logic flow be~in~ (701) when the base site receives (703) an uplink commllnication signal from a first portion of a sector to produce a first received signal and receives (705) an uplink co~ ..ication signal from a second portion of a sector to produce a second received si~n~l. In a preferred 3 0 emborliment, each uplink signal is received via a narrow beam directional ~ntenn~ serving the respective portion of ~e sector.
Upon receiving the uplink si~n~l~, the base site decorrelates (707) the second received signal with respect to the first received 3 5 si~n~l This decorrelation is preferably accomplished by delaying WO 96/07108 PCT/US95/08277 ~
~?7 ~ 7~ 2~
the second received signal by a predetermined time interval with respect to the first received si n~l, as discussed above with regard to FIG. 2. The decorrelated sign~l~ are then combined (709) and provided to a receiver at the base site, and the logic flow ends (711).
5 Since the received si n~l.c are decorrelated prior to submission to the receiver, the receiver can distinguish each received signal by the imposed time delay. Such a techni~lue of ~icting~ hin~ decorrelated sign~l~ is often denoted "raking." Thus, by ex~l-.;";~g the decorrelated si~n~ls, the base site can dete"--;.,e which portion of the 10 sector the co""~ "ication unit is located in and, if so desired, tr~n~mit a responsive downlink signal into the iclentified portion, as described above. This approach effectively improves the reverse ch~nnel capacity of the sector by limiting the power received from any particular portion. By limitin~ the reverse ch~nnel power, 15 uplink inlelrelt;llce is proportionally reduced in each portion of the apportioned sector. The amount of reverse channel capacity improvement is proportional to the number of transmit ~nter~n~
employed at the base site to cover the apportioned sector.
2 0 The present invention encomp~ses a method and apparatus for conveying a commlmication signal between a commllnic~tion unit and a base site that services a sectorized coverage area in a co"~ ,-iç~tion ~yslelll. With this invention, a downlink signal can be directionally tr~n~mitte~l from the base site to the commlmication 2 5 unit upon determinin the co~nmlmication unit's appro~imate location, thereby re~luc-ing the amount of rOl ~var~ ch~nnel interference and noise perceived by the commlmic~tion unit during the tr~n.~micsion and effectiveiy increasing the fol~v~d ch~nnel capacity of the base site's coverage area as compared to the prior art.
3 0 Conversely, an uplink co.-,.-,lication signal can be directionally received from the commnnication unit by the base site, thereby reducing the amount of reverse ch~nnel intelre~ ce and noise perceived by the base site during the tr~nsmi.csion and effectively increasing the reverse c~nnel capacity of the base site's coverage 3 5 area. Fur~er, the present invention facilitates the use of lower ~7~765 power ~mrlif;ers at the base site since less power is needed to obtain coverage at the fnnge of a sector when using narrow beam trans_it ~ntçnn~
S What is cl~im~A is:
Claims (10)
1. A method for transmitting a downlink communication signal from a base site that services a sectorized coverage area to a communication unit residing in the sectorized coverage area, the method comprising the steps of:
a) determining an approximate location of the communication unit within a first sector of the sectorized coverage area; and b) transmitting the downlink communication signal to the approximate location of the communication unit using an antenna structure that produces a beamwidth narrower than an angular width of the first sector.
a) determining an approximate location of the communication unit within a first sector of the sectorized coverage area; and b) transmitting the downlink communication signal to the approximate location of the communication unit using an antenna structure that produces a beamwidth narrower than an angular width of the first sector.
2. The method of claim 1, wherein the antenna structure comprises a plurality of transmit antennas, each of the plurality of transmit antennas being characterized by a narrow beam antenna pattern, and wherein the step of transmitting comprises the step of transmitting the downlink communication signal from a first transmit antenna of the plurality of transmit antennas;
wherein the step of transmitting further comprises the step of transmitting the downlink communication signal from at least a second transmit antenna of the plurality of transmit antennas;
wherein the downlink communication signal comprises a common system control signal;
wherein the step of transmitting the downlink communication signal from at least a second transmit antenna further comprises the step of, prior to transmitting, decorrelating the downlink communication signal to be transmitted by the first transmit antenna with respect to the downlink communication signal to be transmitted by the second transmit antenna;
wherein the step of decorrelating comprises the step of delaying the downlink communication signal to be transmitted by the first transmit antenna by a predetermined interval of time with respect to the downlink communication signal to be transmitted by the second transmit antenna; and wherein the predetermined interval of time comprises at least one pseudo-noise chip.
wherein the step of transmitting further comprises the step of transmitting the downlink communication signal from at least a second transmit antenna of the plurality of transmit antennas;
wherein the downlink communication signal comprises a common system control signal;
wherein the step of transmitting the downlink communication signal from at least a second transmit antenna further comprises the step of, prior to transmitting, decorrelating the downlink communication signal to be transmitted by the first transmit antenna with respect to the downlink communication signal to be transmitted by the second transmit antenna;
wherein the step of decorrelating comprises the step of delaying the downlink communication signal to be transmitted by the first transmit antenna by a predetermined interval of time with respect to the downlink communication signal to be transmitted by the second transmit antenna; and wherein the predetermined interval of time comprises at least one pseudo-noise chip.
3. The method of claim 1, wherein the step of determining comprises the steps of:
a1) transmitting, by the communication unit, an uplink communication signal;
a2) receiving, by the base site, the uplink communication signal from a first portion of the first sector;
a3) receiving, by the base site, the uplink communication signal from a second portion of the first sector; and a4) comprising, at the base site, the uplink communication signal received from the first portion with the uplink communication signal received from the second portion to determine the approximate location of the communication unit.
a1) transmitting, by the communication unit, an uplink communication signal;
a2) receiving, by the base site, the uplink communication signal from a first portion of the first sector;
a3) receiving, by the base site, the uplink communication signal from a second portion of the first sector; and a4) comprising, at the base site, the uplink communication signal received from the first portion with the uplink communication signal received from the second portion to determine the approximate location of the communication unit.
4. A method for receiving an uplink communication signal at a base site from a communication unit residing in a sectorized coverage area of the base site, the method comprising the steps of:
a) receiving the uplink communication signal from a first portion of a first sector of the sectorized coverage area to produce a first received signal;
b) receiving the uplink communication signal from a second portion of the first sector to produce a second received signal;
c) decorrelating the second received signal with respect to the first received signal to produce decorrelated uplink signals; and d) combining the decorrelated uplink signals.
a) receiving the uplink communication signal from a first portion of a first sector of the sectorized coverage area to produce a first received signal;
b) receiving the uplink communication signal from a second portion of the first sector to produce a second received signal;
c) decorrelating the second received signal with respect to the first received signal to produce decorrelated uplink signals; and d) combining the decorrelated uplink signals.
5. A base site that services a sectorized coverage area, comprising:
a receiver for receiving an uplink communication signal from a first sector of the sectorized coverage area; and selection means, operably coupled to the receiver, for routing a downlink communication signal to a first portion of a plurality of portions of the first sector based on reception of the uplink communication signal.
a receiver for receiving an uplink communication signal from a first sector of the sectorized coverage area; and selection means, operably coupled to the receiver, for routing a downlink communication signal to a first portion of a plurality of portions of the first sector based on reception of the uplink communication signal.
6. The base site of claim 5, wherein the selection means further comprises a transmit antenna structure for transmitting to the plurality of portions;
wherein the transmit antenna structure comprises a plurality of transmit antennas, each of the plurality of transmit antennas being characterized by a narrow beam antenna pattern for transmitting to a corresponding one of the plurality of portions;
wherein the selection means comprises means for providing the downlink communication signal to a first transmit antenna of the plurality of transmit antennas and to a second transmit antenna of the plurality of transmit antennas;
further comprising means, operably coupled to the selection means, for decorrelating the downlink communication signal provided to the second transmit antenna with respect to the downlink communication signal provided to the first transmit antenna; and wherein the means for decorrelating comprises a delay device for delaying the downlink communication signal provided to the second transmit antenna by a predetermined time interval.
wherein the transmit antenna structure comprises a plurality of transmit antennas, each of the plurality of transmit antennas being characterized by a narrow beam antenna pattern for transmitting to a corresponding one of the plurality of portions;
wherein the selection means comprises means for providing the downlink communication signal to a first transmit antenna of the plurality of transmit antennas and to a second transmit antenna of the plurality of transmit antennas;
further comprising means, operably coupled to the selection means, for decorrelating the downlink communication signal provided to the second transmit antenna with respect to the downlink communication signal provided to the first transmit antenna; and wherein the means for decorrelating comprises a delay device for delaying the downlink communication signal provided to the second transmit antenna by a predetermined time interval.
7. The base site of claim 6, further comprising means, operably coupled to the selection means, for identifying a portion of the plurality of portions to route the downlink communication signal into based on a comparison of an uplink communication signal received from a second sector of the sectorized coverage area and an uplink communication signal received from a third sector of the sectorized coverage area, wherein the second sector is adjacent to a first side of the first sector and wherein the third sector is adjacent to a second side of the first sector.
8. The base site of claim 6, further comprising means, operably coupled to the selection means for identifying a portion of the plurality of portions to route the downlink communication signal into based on a comparison of signals received from at least two portions of the plurality of portions.
9. A base site that services a sectorized coverage area, comprising:
a first receive antenna for receiving an uplink communication signal from a first portion of a first sector of the sectorized coverage area;
a second receive antenna for receiving the uplink communication signal from a second portion of the first sector;
decorrelating means, operably coupled to the first receive antenna and the second receive antenna, for decorrelating the uplink communication signal received by the second receive antenna with respect to the uplink communication signal received by the first receive antenna to produce decorrelated uplink signals; and combining means, operably coupled to the decorrelating means, for combining the decorrelated uplink signals.
a first receive antenna for receiving an uplink communication signal from a first portion of a first sector of the sectorized coverage area;
a second receive antenna for receiving the uplink communication signal from a second portion of the first sector;
decorrelating means, operably coupled to the first receive antenna and the second receive antenna, for decorrelating the uplink communication signal received by the second receive antenna with respect to the uplink communication signal received by the first receive antenna to produce decorrelated uplink signals; and combining means, operably coupled to the decorrelating means, for combining the decorrelated uplink signals.
10. The base site of claim 9, wherein the decorrelating means comprises a delay device for delaying the uplink communication signal received by the second receive antenna by a predetermined time interval with respect to the uplink communication signal received by, the first receive antenna; and wherein the delay device delays the uplink communication signal received by the second receive antenna based on a predetermined modulation pattern.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US08/298,918 | 1994-08-31 | ||
| US08/298,918 US5596333A (en) | 1994-08-31 | 1994-08-31 | Method and apparatus for conveying a communication signal between a communication unit and a base site |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA2174765A1 true CA2174765A1 (en) | 1996-03-07 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA002174765A Abandoned CA2174765A1 (en) | 1994-08-31 | 1995-06-30 | Method and apparatus for conveying a communication signal between a communication unit and a base site |
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| US (1) | US5596333A (en) |
| JP (1) | JP3887013B2 (en) |
| KR (1) | KR0169890B1 (en) |
| CA (1) | CA2174765A1 (en) |
| SE (2) | SE520835C2 (en) |
| WO (1) | WO1996007108A1 (en) |
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1995
- 1995-06-30 KR KR1019960702197A patent/KR0169890B1/en not_active IP Right Cessation
- 1995-06-30 WO PCT/US1995/008277 patent/WO1996007108A1/en active Application Filing
- 1995-06-30 JP JP50872496A patent/JP3887013B2/en not_active Expired - Fee Related
- 1995-06-30 CA CA002174765A patent/CA2174765A1/en not_active Abandoned
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2002
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| JP3887013B2 (en) | 2007-02-28 |
| SE9601587D0 (en) | 1996-04-26 |
| JPH09504934A (en) | 1997-05-13 |
| KR0169890B1 (en) | 1999-03-20 |
| SE521629C2 (en) | 2003-11-18 |
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| US5596333A (en) | 1997-01-21 |
| SE0202722D0 (en) | 2002-09-13 |
| SE0202722L (en) | 2002-09-13 |
| KR960706083A (en) | 1996-11-08 |
| SE9601587L (en) | 1996-06-28 |
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