Method and apparatus for estimating the position of a terminal based on identification codes for tra
专利摘要:
A method of determining the position of a terminal within the coverage area of a repeater in a wireless communication system is presented. In one aspect, the identification code is sent from each repeater and used by the terminal to make it possible to clearly identify the repeater. These identification codes for repeaters in the system may be implemented with PN sequences with defined offsets specifically reserved for repeater identification. In another aspect, the identification code for each repeater is transmitted using a spread spectrum signal designed to have minimal impact on system performance and be recovered by the terminal in a similar manner for forward modulated signals. In this way, no additional hardware is required for the terminal to recover the identifier signal. In a particular design, the spread spectrum identifier signal is generated according to the IS-95 CDMA standard and follows the IS-95 standard. 公开号:KR20030088511A 申请号:KR10-2003-7013934 申请日:2002-04-24 公开日:2003-11-19 发明作者:제레미 엠. 스테인;헤임 웨이스먼 申请人:콸콤 인코포레이티드; IPC主号:
专利说明:
METHOD AND APPARATUS FOR ESTIMATING THE POSITION OF A TERMINAL BASED ON IDENTIFICATION CODES FOR TRANSMISSION SOURCES} [2] A common technique for locating a terminal is to determine the time required for signals transmitted from multiple transmitters to reach the terminal at known locations. One system for providing signals from multiple transmitters at known locations is a known satellite positioning (GPS) system. Satellites in the GPS system are placed in the correct orbit according to the GPS master plan. The position of the GPS satellites may be determined by several sets of information transmitted by the satellites themselves (commonly known as "Almanac" and "Ephemeris"). Another system for providing a signal from a transmitter (eg, base station) at a known earth-boundary location is a wireless (eg, cellular telephone) communication system. [3] Many wireless systems provide repeaters to provide coverage or extend system coverage for designated areas within the system. For example, a repeater may be used to cover certain areas not covered by the base station because of fading conditions (ie, "holes" in the system). Repeaters may also be used to extend coverage to suburban areas outside of the base station's coverage area (eg, along highways). The repeater receives, adjusts and retransmits signals on both the forward link (ie, the path from the base station to the mobile unit) and the reverse link (path from the mobile unit to the base station). [4] Several challenges are encountered when determining the terminal location of a system that uses one or more repeaters. Typically, signals from a single base station are processed and retransmitted at the repeater at relatively high power and with a certain delay. The combination of high power of the relayed signal and normal separation associated with the service area of the repeater often prevents the terminal from receiving other signals from other base stations. Also, in many cases where repeaters are used (eg, buildings, tunnels, subways, etc.), signals from GPS satellites do not have sufficient power levels to be received at the terminal. In this case, a limited number of signals (from the repeater, only one possible signal) can be used to determine the terminal location. In addition, the additional delay induced by the repeater may distort round trip delay / arrival time (RTD / TOA) measurements and TDOA measurements, which inaccurate position estimates based on these measurements. [5] 1A is a diagram of a wireless communication system 100 employing a repeater in accordance with the disclosed methods and apparatus. The system 100 may include one or more known industry standards, such as IS-95, issued by the Telecommunications Industry Association / Electric Industry Association (TIA / EIA), and other industry standards, such as W-CDMA, cdma2000, or a combination thereof. It is designed to follow. System 100 includes a number of base stations 104. Each base station serves a particular service area 102. Although only three base stations 104a-104c are shown in FIG. 1A for simplicity, those skilled in the art will appreciate that there may be more base stations in such a system. For purposes of illustration, the base station and its service area are collectively referred to as "cells". [6] One or more repeaters 114 may be used in the system 100 to provide coverage for areas that may not be covered by the base station (eg, by fading conditions such as area 112a shown in FIG. 1A). Or expand the service coverage of the system (eg, areas 112b and 112c). For example, repeaters are commonly used to improve indoor service coverage for cellular systems at relatively low cost. Each repeater 114 is connected to the “service” base station 104 directly or via another relay via a wireless or wired link (eg, coaxial or fiber optic cable). Depending on the particular system design, any number of base stations in the system may be relayed. [7] In general, multiple terminals 106 are distributed throughout the system (only one terminal is shown in FIG. 1A for simplicity). Each terminal 106 may communicate with one or more base stations on the forward and reverse links at a given moment, depending on whether soft handoff is supported by the system and whether the terminal is actually in soft handoff. Those skilled in the art will appreciate that "soft handoff" refers to a state in which a terminal is communicating with one or more base stations at the same time. [8] Multiple base stations 104 are generally connected to one base station controller (BSC) 120. The BSC 120 regulates communication to the base station 104. To determine the terminal location, base station controller 120 may be coupled to location determination entity (PDE) 130. The PDE 130 receives time measurements and / or identification codes from the terminal, makes control related to positioning and provides other information, which is described in detail below. [9] For location determination, the terminal can measure signal transmission arrival times from multiple base stations. In a CDMA network, these arrival times can be determined from the phase of the pseudo noise (PN) code used at the base station to spread these data before transmitting to the terminal on the forward link. The PN phase detected by the terminal may be reported to the PDE (eg, via IS-801 signaling). The PDE then uses the reported PN phase measurements to determine the pseudo-range, which is used to determine the terminal location. [10] The terminal location may also be determined by a hybrid scheme in which the signal arrival time (ie, arrival time (TOA)) is measured in some combination of base station 104 and satellite positioning system (GPS) satellite 124. Measurements derived from GPS satellites may be used as primary measurements or to augment measurements derived from base stations. In general, measurements from GPS satellites are more accurate than measurements from base stations. In general, however, a clear line of sight to the satellite is required to receive the GPS signal. Thus, using GPS satellites for location determination is limited to external environments where no obstacles exist. In general, GPS signals cannot be used indoors or in other environments where obstacles such as leaves and buildings exist. However, GPS has a wide range of services, and four or more GPS satellites can be received everywhere, potentially without any obstacles. [11] In comparison, base stations are generally located in a crowded area and their signals can penetrate some buildings and obstacles. Thus, it is possible for a base station to be used in the city and potentially in a building to determine the location of a device capable of receiving and / or transmitting such signals. However, measurements derived from base stations are inaccurate compared to measurements from GPS satellites, because a number of signals may be received at a terminal from a particular base station because of a phenomenon known as "multipath." Multipath is called a situation where a signal is received over multiple transmission paths between a transmitter and a receiver. Such multipath is generated by signals reflecting various objects such as buildings, mountains, and the like. In the best case, the signal may be received on a direct path (straight) from the transmitter to the receiver. However, this is rarely practical. [12] In a hybrid scheme, each base station and each GPS satellite represents a transmission source. To determine the bidirectional estimation of terminal location, transmissions from three or more non-spatially aligned sources are received and processed. A fourth source can be used to provide altitude (three dimensions), which can also increase accuracy (ie, uncertainty in the measured arrival time is reduced). The signal arrival time can be determined for the transmission source and used to calculate the pseudo-range, which can then be used to determine the terminal location (eg, via trilateration). Location determination can be made by known means, as described in the 3GPP 25.305, TIA / EIA / IS-801 and TIA / EIA / IS-817 standard documents. [13] In the embodiment shown in FIG. 1A, the terminal 106 may receive transmissions from the GPS satellites 124, the base station 104, and / or the repeater 114. Terminal 106 may measure signal arrival times of transmissions from these transmitters and report these measurements to PDE 130 via BSC 120. PDE 130 may then use this measurement to determine the location of terminal 106. [14] As mentioned above, repeaters can be used to provide coverage for areas not covered by base stations, such as in a building. Repeaters are preferably used where they are more economical than base stations and where no additional capacity is required. However, repeaters are associated with additional delays due to cabling and / or additional transmissions associated with circuits and repeaters within the repeaters. For example, SAW filters, amplifiers, and other components in repeaters cause additional delays comparable to or greater than the transmission delay from the base station to the terminal. [15] If a repeater is not considered, the timing of the signal from the repeater cannot be used reliably to determine the position of the terminal. [16] 1B illustrates the use of repeater 114x to provide indoor coverage for building 150. In the illustrated embodiment, the repeater 114x includes a main unit (MU) connected to a number of remote units (RU) 116. In the forward link, the main unit 115 receives one or more signals from one or more base stations and relays all or a subset of the signals received to each remote unit. And on the reverse link, the main unit 115 receives, combines and relays signals from the remote station 116 to transmit back to one or more base stations on the reverse link. Each remote station 116 provides coverage for a particular area of the building (eg, one floor), and relays forward and reverse link signals to that coverage. [17] When estimating the location of a terminal located in a building where a repeater can be used to provide coverage, problems are encountered. First, in many indoor applications, a terminal may not receive a signal from a base station or a GPS satellite, or may receive a signal from fewer transmitters than the transmitter required to perform the phase measurement. To provide in-building coverage, repeaters typically retransmit signals with a relatively high power delay from a single base station. The combination of the high power of the relayed signal and the isolated internal location of the terminal usually prevents the terminal from receiving other signals from other base stations and satellites. [18] Second, if the amount of delay caused by the repeater is unknown, the signal from the repeater cannot be used reliably as one of the signals for trilateration. This prevents an entity (eg, a PDE or terminal) from using the relayed signal to estimate its location using satellite or base station signals. Third, in various environments where repeaters are used (eg, subways, buildings, etc.), GPS signals may not be received even when the terminal uses a receiver unit with enhanced sensitivity. Fourth, the entity used to determine the location of the terminal uses the terminal's inaccurate timing criteria (caused by uncertain relay delay) that adversely affects the accuracy of the time stamp and round trip delay (RTD) measurement in GPS measurements. It doesn't have a way to determine whether it's doing it. [19] Therefore, there is a need for a technique for estimating the position of a terminal in a wireless communication system using a repeater (or other transmission source with similar characteristics). [1] TECHNICAL FIELD The present invention relates to position determination and, more particularly, to a technique for estimating terminal position in a wireless communication system based on an identification code assigned to a transmission source such as a repeater. [27] 1A illustrates a wireless communication system employing a repeater and capable of implementing various features and embodiments of the methods and apparatus of the present invention. [28] 1B illustrates the use of a repeater to provide coverage for a building. [29] 2 shows an index of a PN sequence used to generate pilot criteria and spread data at a base station. [30] 3 illustrates an embodiment of a repeater that may implement an embodiment of the method and apparatus of the present invention. [31] 4A-4C illustrate three embodiments of modules that may be used to generate an identification signal and combine it with a forward modulated signal to provide a combined signal. [32] 5A illustrates a signal that may be received from a remote unit of a particular repeater. [33] 5B illustrates signals that may be received from remote stations and indoor base stations of a particular repeater. [34] 5C and 5D show identification signals of multiple remote stations delayed by different chip offsets derived based on two different schemes. [35] 6A shows geometric constraints on the time difference of arrival (TDOA) measurements. [36] 6B-6E illustrate four different scenarios for a terminal based on the use of a neighbor list PN for an identifier PN. [37] 7 is a block diagram illustrating a terminal capable of implementing various features and embodiments of the method and apparatus of the present invention. [38] 8 is a block diagram illustrating an embodiment of a positioning entity (PDE) for use with the method and apparatus of the present invention. [20] The method and apparatus of the present invention determine the location of a terminal communicating via a repeater in a wireless communication system. The positioning of such terminals is recognized by methods and apparatus designed for repeaters used to provide indoor coverage to cover relatively narrow geographic areas (eg, buildings, floors of buildings, etc.). If the coverage area of the repeater is narrow, the estimation of the position of the terminal in repeater coverage may be reported as a designated location in the coverage area, which may be the center of the coverage area. In many cases (but not in most cases), the reported position estimate for a terminal is thus within 50 meters of the terminal's actual position. This accuracy is sufficient for enhanced emergency 911 (E-911) services proposed by the Federal Communications Commission (FCC). [21] According to one embodiment of the described method and apparatus, an identification code specifically associated with each repeater is transmitted by each repeater within a particular coverage area (eg, cell). The identification code can then be used by the terminal (or PDE) to correctly identify the repeater. Various types of codes can be used as identification codes. In one embodiment, the identification code includes a similar noise (PN) sequence, specified for identification of the repeater, at a defined offset. [22] In the case where the repeater covers a narrow geographic area, the identification of the particular repeater in which the signal is received may be used to estimate the position of the terminal, for example as the center of the repeater coverage area. In the case where the repeater covers a large area, the identification of the specific repeater in which the signal is received can be used to adjust the measurement according to the delay of the repeater. [23] In another embodiment, the identification code for each repeater is transmitted using a spread spectrum signal. Such a spread spectrum identification signal can be designed to minimize the performance of the CDMA system and can be recovered in a manner similar to the forward modulated signal transmitted from the base station or repeater. In this way, the repeater does not require additional hardware to recover the identification code. In one embodiment, the spread spectrum identification signal is generated according to the IS-95 CDMA standard. [24] In another embodiment of the described method and apparatus, when it is determined that a signal has passed through a repeater, the signal is not used for positioning and positioning calculations. This provides a simple and inexpensive way to ensure that the delay added to the signal transfer time from the base station to the terminal does not cause an error in the positioning calculation. In other words, since the propagation delay between the time the signal is transmitted from the base station and the time signal is received by the terminal does not accurately reflect the distance between the base station and the terminal, the delay should not be used for the positioning calculation. If additional information is available in connection with the identification of the repeater through which the signal passes and the positioning of the repeater, the information can be used for calculation. However, it should be noted that there may be enough signals from other signals not passing through the repeater to be able to calculate the positioning of the terminal without using information from the signals passing through the repeater. In either case, it is important to know that the signal that has passed through the repeater may cause additional delays caused by the repeater to be considered by not using the timing information for the signal or by adjusting the timing information appropriately. [25] The techniques disclosed herein include various CDMA systems (e.g., systems conforming to the following industry standards: IS-95, cdma2000, W-CDMA, IS-801) and various non-CDMA systems (e.g., GSM, TDMA, analog, etc.). Can be used). [26] The features, properties, and advantages of the present invention will be described in more detail with reference to the drawings and detailed description, wherein like elements have like reference numerals. [39] The method and apparatus of the present invention provide a technique for determining the position of a terminal under repeater coverage in a wireless communication system. In one aspect, the present invention provides a technique for transmitting an identification code that each repeater can use by a terminal (or PDE) to identify the identifier of each repeater. This information can then be used to estimate the location of the terminal as described below. [40] It can be seen that the repeaters used to provide indoor coverage by the disclosed methods and apparatus are typically designed to cover relatively small geographic areas (eg, buildings, floors in buildings, etc.). In one embodiment, since the coverage area of the repeater is typically small, the position estimate for the terminal under the coverage of the repeater is reported as the designated location in this coverage area, which is the center of the coverage area. In many (but not most) cases, this reported location estimate for the terminal will be within 50 meters of the terminal's actual location. This accuracy is sufficient for improved emergency 911 (E-911) services specified by the Federal Communications Commission (FCC), which requires the location of the terminal in the 911 call to be transmitted to the Public Safety Response Point (PSAP). For handset terminals, the E-911 designation requires that the location estimate be within 67% 50 meters of time and 95% 150 meters of time. This need meets the described technique. [41] Several schemes are used to identify repeaters for terminals. In one scheme, each repeater within a particular coverage area (eg, cell) is assigned a unique identification code that is used to clearly identify the repeater. Multiple identification codes are assigned to multiple repeaters within a particular coverage area. This can be used, for example, in very large buildings with multiple repeaters used to provide coverage and spaced apart (eg, 100 meters apart). Optionally, multiple repeaters are assigned a common identification code if these repeaters are located in a sufficiently small area. A single position estimate is then used for all these repeaters. [42] For each repeater, an identification code assigned to the repeater and a position estimate to be provided for the terminal in the repeater's coverage (eg, center in the repeater's coverage area) are stored in the table. These tables are maintained in PDE. In this case, the terminal can receive the identification code from the repeater and send it back to the PDE (e.g., in a coded format), which is then sent to a value stored in the table (e.g., coverage center). Provide a location estimate for the terminal based on the Optionally or additionally, the table is maintained at the terminal or some other entity (eg, base station, BSC, etc.). [43] The scheme used to transmit the identification code of the repeater to the terminal is designed based on several criteria. First of all, the identification code must be transmitted in a manner compatible with existing CDMA standards supported by the system (e.g., IS-95, cdma2000, W-CDMA, IS-801, etc.). Secondly, the system must be compatible with the performance of terminals already developed and used in the field, which allows existing terminals to perform positioning based on identification codes. Third, the identification code must be transmitted to the terminal within the same frequency band in which the terminal is tuned so that both the relayed signal and the corresponding identification code can be received simultaneously using a single receiver unit. Fourth, the signal used to transmit the identification code should have minimal impact on the performance of the system. [44] In another feature, the identification code of each repeater is transmitted using a spread-spectrum signal, which has several advantages. First, the spread spectrum identifier signal can be designed to have a minimal impact on the performance of the CDMA system. Secondly, the spread spectrum identifier signal may be recovered in a similar and similar manner to the forward modulated signal from the base station or repeater. In this way, no additional hardware is needed for the terminal to recover the identifier signal. Existing terminals already developed in the field and capable of receiving and processing CDMA signals can receive and process identifier signals from repeaters. [45] In one embodiment, the spread spectrum identifier signal for the repeater is generated in accordance with the IS-95 CDMA standard and conforms to this standard. However, the identifier signal can be designed to conform to some other CDMA standard or design. [46] In one embodiment, the identification code for the repeater includes a pseudo random-noise (PN) sequence at a predetermined offset. In a typical CDMA system, each base station spreads its data with a PN sequence to generate a spread spectrum signal, which is transmitted to the terminal (and possibly a repeater). PN sequences are used to spread pilot data (typically all zero sequences) for generating pilot references, which are used by the terminal to perform coherent demodulation, channel estimation and possibly other functions. . [47] FIG. 2 is a diagram illustrating an index for a PN sequence used to generate pilot criteria and spread data at a base station. In IS-95 and some other CDMA systems, the PN sequence has 32,768 chips of specific data pattern and fixed length. This PN sequence is repeated continuously to generate a continuous spreading sequence used to spread pilot and traffic data. The start of the PN sequence is synchronized to an absolute time reference (T ABS ) defined and defined by the CDMA standard, which is referred to as system time. Each chip of the PN sequence is assigned an individual PN chip index, the beginning of the PN sequence is assigned a PN chip index of zero, and the last chip of the PN sequence is assigned a PN chip index of 32,767. [48] The PN sequence is divided into 512 different "PN INC offsets" numbered from 0 to 511, with PN INC offsets with consecutive numbers separated by 64 chips. Effectively, 512 different PN sequences are defined based on 512 different PN INC offsets, and each 512 PN sequence has a different starting point in an absolute time reference based on its PN INC offset. Thus, PN sequence with a PN INC offset of 0 starts at PN chip index 0 at T ABS, and, PN sequence with a PN INC offset of one is a PN INC offset of PN chips starting at the index 64, and 2 in the T ABS The PN sequence with TN starts at PN chip index 128 in T ABS , and the PN sequence with PN INC offset of 511 continues at PN chip index 32,704 in T ABS . [49] The 512 possible PN sequences are assigned to base stations in CDMA systems and are used to differentiate the base stations among other functions. Each base station is assigned a unique PN INC offset such that the pilot criteria from neighboring base stations can be differentiated, allowing the terminal to identify each received base station by its PN INC offset. [50] The closest PN INC offset assigned to the neighbor base station is determined by the CDMA standard. For example, the IS-95 and IS-856 standards define a minimum value of 1 for the parameter "PN_INC". This particular PN_INC is assigned to a PN sequence in which adjacent base stations are separated by a minimum PN INC offset of 1 (or 64 PN chips). A lower specific PN_INC value (eg 1) results in a more usable PN offset (eg 512) assigned to the base station. As a result, a large unique PN_INC value (eg 4) results in a small usable PN offset (eg 128) assigned to the base station. [51] In one aspect, the PN sequence at the unique offset is used for repeater identification. As used herein, an "identifier PN (IPN)" is a PN sequence, code, bit pattern, or some other means used to identify a repeater. Several PNs are used as identifier PNs. The identifier PN is categorized as follows: [52] Dedicated IPN—one or more PN sequences in a unique PN INC are reserved for use for repeater identification; [53] Neighbor List IPN-The PN sequence for the base station in the neighbor list is used for relay identification. [54] Each of these PN categories corresponds to a different scheme used to select a PN sequence for use as an identifier PN. These PN selection schemes are described in detail below. Other schemes for selecting PN sequences for use as IPNs are contemplated, which are within the scope of the present invention. [55] For dedicated IPN schemes, one or more PN INC offsets from 512 possible PN INC offsets (if 1 PN_INC is specified) or 128 possible PN INC offsets (if 4 PN_INC are specified) are dedicated for relay identification. do. At this dedicated PN INC offset, the PN sequence is used to identify the repeater. [56] The use of the identifier PN allows the terminal to clearly identify the intra-cell repeater. If multiple repeaters are used within a particular cell, these repeaters are assigned to the same or different identifier PN depending on several factors. In one embodiment, different identifier PNs at different PN INC offsets are assigned to repeaters in the same cell. In another embodiment, different chip offsets of the same identifier PN are assigned to repeaters in the same cell. These offsets are defined with respect to system time as determined by the offset of the relayed PN. For example, if a two-chip offset is used, eleven different PN sequences can be generated from a single identifier PN in a 20-chip window. PN sequences assigned to repeaters in the same cell may have different PN INCs or chip offsets so that these repeaters can be uniquely identified. [57] 3 is a diagram of an embodiment of a repeater 114y that may implement various features and embodiments of the disclosed methods and apparatus. Repeater 114y is a high gain bidirectional amplifier used to receive, amplify and transmit modulated signals on the forward and reverse links. In the forward link, a modulated signal serving a base station 104 (also referred to as a "donor" cell or sector) is a repeater via a (eg directional) antenna or (eg coaxial or fiber) cable. Received by 114y. Repeater 114y then retransmits the forward modulated signal to terminals 106 within its coverage area. [58] Thus, on the reverse link, iterator 114y receives the modulated signal from the terminal in the coverage area and examines and retransmits the reverse modulated signal returning to the serving base station. [59] In the particular embodiment shown in FIG. 3, the repeater 114y includes a repeater unit 310 coupled to the identifier signal generator 320. Repeater unit 310 performs a signal check to generate a repeated signal for both the forward and reverse links. The identifier signal generator 320 generates one or more spread spectrum identifier signals that include an identification code (eg, identifier PN) assigned to the iterator 114y. [60] In the illustrated embodiment, the identifier signal generator 320 includes a receiver module 322 and an upconverter module 324 coupled to the PN generator. Coupler 308 provides a portion of the forward modulated signal from the serving base station to receiver module 322. Receiver module 322 processes the synthesized portion of the forward modulated signal to provide a timing reference and a frequency reference, which is used to generate a spread spectrum identifier signal for repeater 114y. The PN generator and upconverter module 324 generates an identifier PN for the repeater based on the timing criteria to further upconvert the PN to the appropriate intermediate frequency (IF) and radio frequency (RF). The operation of the identifier signal generator 320 is described in more detail below. [61] In the illustrated embodiment, the repeater unit 310 includes a pair of duplexers 312a and 312b, which are coupled to antennas 302a and 302b, respectively, and used to communicate with the serving base station and terminal, respectively. The duplexer 312a routes the forward modulated signal from the serving base station to the inspection unit 314 and adds the reverse modulated signal examined from the inspection unit 318 to the antenna 302a for transmission back to the serving base station. Combine with The inspection unit 314 examines the forward modulated signal and provides the inspected forward modulated signal to the synthesizer 316. Signal checking may include amplifying, forward modulating the signal down to an intermediate frequency (IF) or baseband, filtering, and upconverting the signal to an IF or radio frequency (RF). A synthesizer (which may be executed using a hybrid coupler) 316 further receives a spread spectrum identifier signal from the identifier signal generator 320, synthesizes the identifier signal with the checked forward modulated signal, and combines the synthesized signal with a duplexer. Provided to 312b. The synthesized signal is then routed to antenna 302b and transmitted to the terminal. [62] As shown in FIG. 3, the repeater unit 310 may receive a frequency reference from the cooler signal generator 320. The frequency reference may be required if an identifier signal is added to the IF or baseband Bb. The frequency reference can be used to ensure that the repeater's IF / BB is accurate. In this case, the test unit 314 receives the frequency reference and the synthesizer 316 is included in the test unit 314. [63] On the reverse link, the reverse modulated signal from the terminal is received by the antenna 302b and routed through the duplexer 312b and inspected by the inspection unit 318. The examined reverse modulated signal is then routed through duplexer 312a and transmitted via antenna 302a to the serving base station. In general, the processing of the forward and reverse modulated signals in repeater 310 is not affected by the processing and addition of the spread spectrum identifier signal. [64] As shown in FIG. 3, the identifier signal is added to the examined forward modulated signal (eg, either IF or RF) within the repeater unit 310. In general, the identifier signal may be added at any point along the signal path from antenna 302a to antenna 302b. For example, the identifier signal may be added to the generated and received forward modulated signal, and the synthesized signal may then be provided to the repeater unit 310. Optionally, the indicator signal may be added to the forward modulated signal examined from the repeater unit 310 and the synthesized signal may then be transmitted via the antenna 302b. Thus, the identifier signal may be added to the forward modulated signal outside or inside the repeater unit 310. For an iterator that is already placed in the field and that does not include a suitable circuit (eg, synthesizer 316 of FIG. 3) and synthesizes the forward modulated signal and the identifier signal, the function may be accomplished outside the iterator. In addition, the coupler 308 may be located at the front end (input) or end (output) of the repeater. Optionally, the combined portion of the forward modulated signal may be obtained with RF, IF, or baseband in the repeater depending on the particular implementation of the repeater. 4A illustrates an embodiment of a module 400a that may be used to generate an identifier signal and synthesize it with a forward modulated signal to provide a synthesized signal. Module 400a can be implemented as a separate unit and coupled to the input port or output port of the repeater unit. If coupled to an input port, the synthesized signal from module 400a may be examined and retransmitted by the repeater unit in a manner similar to that for forward modulated signals. And if coupled to the output port, the identifier signal may be combined with the forward modulated signal examined from the repeater unit to generate a composite signal for transmission to the terminal. In another case, the repeater unit can be operated in a regular manner, such as when no identifier signal is provided. [65] In the embodiment shown in FIG. 4A, the forward modulated signal (ie, forward RF input) within module 400a may be coupled through coupler 408 and routed through separator 412 to run with the hybrid coupler. Provided to synthesizer 416. The synthesizer 416 also receives an identifier signal from the identifier signal generator 420a to synthesize the forward forged signal and the identifier signal and provide the synthesized signal to an output (ie, a forward RF output). [66] 4A also illustrates an embodiment of an identifier signal generator 420a that may be used for the identifier signal generator 320 of FIG. The combined portion of the forward modulated signal is provided to the receiver module 422 and processed to provide timing and frequency references as described above. In one embodiment, receiver module 422 includes a receiver processing unit similar to that contained within a terminal and may demodulate a forward modulated signal from a serving base station. In particular, receiver module 422 filters, amplifies, downconverts, and digitizes the forward modulated signal to provide a sample. The samples are then despread with a varying chip offset using locally generated PN sequences to recover the pilot criteria sent by the serving base station. [67] Pilot search and demodulation is described in US Pat. No. 5,754,687 entitled " Mobile Demodulator Structure for Spectrum Spread Multiple Access Communication System "; US Pat. Nos. 5,805,648 and 5,644,591, entitled "Methods and Apparatus for Performing Search Acquisition in a CDMA Communication System"; And US Patent 5,577,022 entitled "Pilot Signal Searching Techniques for Cellular Communication Systems". [68] In one embodiment, the receiving module 422 includes a timing tracking loop and a carrier tracking loop (not shown in FIG. 4A for simplicity). The frequency tracking loop locks the frequency of the local reference oscillator (eg, temperature compensated crystal oscillator (TCXO)) to the frequency of the pilot reference within the received forward modulated signal (ie, the signal to be repeated). The timing reference can then be derived by detecting the beginning of the PN sequence extracted from the recovered pilot reference. The timing reference may be provided by the receiver unit 422 via a timing signal having a pulse that coincides with a periodic offset determined from the system time (such as derived from the recovered pilot reference) and assigns the identifier PN to the system time. Sort it. [69] The carrier tracking loop locks the local oscillator (LO) to the carrier frequency of the forward modulated signal. The frequency reference can then be derived from a fixed local oscillator. The frequency reference may be provided via a clock signal having a frequency related to the frequency of the recovered carrier (eg 1 / N times). [70] In the embodiment shown in FIG. 4A, the PN generator and upconverter module 424 includes a controller 430, a PN generator 432, and an upconverter 434. The PN generator 432 may be further provided with other signals that may be required for generating the identifier PN by receiving timing criteria from the receiver module 422. For example, the PN generator 432 may be a clock signal at a multiple PN chip rate (e.g., a 16 times chip rate, or a clock signal at Chipx 16) and within a specific time period (e.g., two seconds). It may be provided with another signal having a number of Chipx16 cycles. PN generator 432 then generates one or more identifier PNs at a desired offset, depending on the particular implementation, and further performs pulse shaping of each identifier PN using a digital filter to generate a properly shaped PN sequence. can do. [71] The downconverter 434 receives the frequency reference from the receiver module 422 and the identifier PN (waveformed) from the PN generator 432 to each identifier signal corresponding to a different carrier frequency and / or PN offset. Together with one or more spread spectrum identifier signals. Multiple identifier signals may be required for a particular application, as described below. [72] Using the frequency reference from the receiver module 422, each identifier signal may be provided at a carrier frequency having a negligible frequency error. The negligible frequency error causes the terminal to receive the identifier signal. It is possible to recover the identifier PN even when the identifier PN is locked with the forward modulated signal. The generation of the identifier signal can be performed digitally, using analog and digital circuits together or using some other method. [73] Controller 430 may communicate with receiver module 422, PN generator 432, and upconverter 434 for various functions. For example, the controller 430 causes the receiver module 422 to be locked to a particular one of the received modulated forward signals to detect the forward modulated signal within a particular frequency window. Controller 430 instructs PN generator 432 to generate the identifier PN at a particular offset that was assigned to the repeater. Controller 430 also causes upconverter 434 to generate the identifier signal at a particular carrier frequency and at a particular transmit power. [74] In one embodiment, the power level of each identifier signal is controlled so as not to harm the capacity of the system. In a CDMA system, each transmitted signal (e.g., an identifier signal) acts as a disturbance to other transmitted signals (e.g., a forward modulated signal), and that of the other transmitted signal received at the terminal. It can degrade the quality. The degradation in signal quality can affect the transmission capacity of the forward link. In order to minimize the degradation, the power level of the identifier signal may be controlled to a certain level (eg 15 dB) below the total signal power of the forward modulated signal being relayed. The power level of the identifier signal is also controlled within the reception range of most terminals. This allows the identifier signal to be properly received by the terminal. [75] In one embodiment, only one identifier PN is used to identify each repeater regardless of the number of forward modulated signals retransmitted by the repeater. However, multiple identifier signals may be generated by module 400a for various reasons. For example, if a forward modulated signal is retransmitted on multiple frequency bands, the identifier PN corresponds to the identifier PN of the relayed signals. Can be upconverted to the number of carrier frequencies. Multiple identifier signals may also be digitally generated, for example with a low IF (eg 10 MHz) and thus upconverted to the desired RF or IF. The identifier PN is used for repeater identification and is not used for base station identification, only one identifier PN is assigned to each repeater even if multiple forward modulated signals from multiple base stations are relayed. [76] 4B illustrates one embodiment of another module 400b that may be used to generate an identifier signal and combine it with a forward modulated signal to provide a combined signal. Module 400b is similar in some respects to module 400a of FIG. 4A, but further includes a transmitter module 426 used to provide approval for the remote structure with an inversely modulated signal. The remote structure of the repeater can be carried out via PDE, for example. In that case, the transmitter module 426 may be used to retransmit information to the PDE regarding the structure. The information may include acknowledgment of a command to change the identifier signal (eg, offset and / or relative power of the identifier signal) sent by the PDE. Feedback from the repeater causes the PDE to monitor and authenticate such remote structures. The positions of the combiner 416 and separator 412 can be interchanged, which allows the receiver module 422 to monitor the identifier signal itself. In this way, the receiver module 422 can receive the identifier signal similarly to the terminal and enable monitoring of the added signal. [77] 4C illustrates one embodiment of another module 400c that may be used to generate an identifier signal and combine it with a forward modulated signal to provide a combined signal. Module 400c is similar in some respects to module 400b of FIG. 4B, but uses forward and reverse modulated signals to combine forward and reverse modulated signals at the input and output ports of module 400c, respectively. And a single cable can be used at each port for the forward and reverse links. In the illustrated embodiment, each unit 450 may include a pair of bandpass filters BPFs 452 and 454 used to filter the reverse and forward modulated signals, respectively. Circulator 456 forwards the forward and reverse modulated signals to their appropriate destinations, and further allows for separate forward and reverse links. Units 450a and 450b may also be implemented by a duplexer. [78] Repeaters are associated with multiple remote units (RUs), which are used to provide coverage of their respective areas. In the internal application shown in FIG. 1B, the repeater 114x includes a main unit 115 and a plurality of remote units 116, each providing coverage for an individual floor. The identifier signal transmitted by the remote station can be generated in various ways based on various ways (eg depending on whether the remote unit is individually identified). [79] In Figure 5A, Figure 5D illustrates certain specific implementations for generating identifier PNs for multiple remote units of a repeater. In certain CDMA systems (corresponding to the IS-95 CDMA specification), the terminal only reports the earliest arriving pilot signal relative to the reference time (ie, the first signal that can be used for demodulation). Currently, the IS-801 specification is also only used to report the fastest arriving pilot. Since the pilot data are all zero or all one sequences, the pilot signal is essentially a PN sequence. In the system, a specific offset for the identifier PN is assigned to each identifier PN so that the remote unit can be identified in a manner specifically described below. In other systems that allow multiple pilots to be reported, the reported pilot profile is also used to identify the remote unit. 5A to 5D are exemplary cases for explanation. The concepts described below can be modified or extended for other cases and are included within the scope of the present invention. [80] The relayed signal transmitted from the remote unit of a particular repeater is typically delayed, so that the relayed signals are not received at the same power and delay at the terminal and are received in the opposite state, in which case the relayed signals are discarded. . Since the area covered by the remote unit is typically small, the delay of two chips between the remote units is generally adequate. [81] In the description of FIG. 5D to FIG. 5A, assume that a dedicated IPN can be used for repeater identification. In the concept described with reference to FIG. 5D in FIG. 5A, the extension to integrate the neighbor list IPN is described below. [82] 5A is a system diagram showing a signal received from a remote unit of a particular repeater. As shown in Figure 5A, the identifier PN is delayed from the relayed donor PN (R DPN ) by the offset d (i.e., from the PN from the relayed donor base station, and relayed for each remote unit). And the identifier signals are delayed by two chips relative to each other, if the terminal receives only a signal from the repeater (ie, one or more remote units of the repeater), and if not receiving from the donor base station, the terminal has the following range: Will report the delay of the identifier PN for the relayed donor PN. [83] R RIPN ∈ [d; 2 (n-1) + d] formula (1) [84] Equation (1) indicates that the offset of the earliest identifier PN reported by the terminal is from d (if relayed from the first remote unit and an identifier signal is received) to 2 (n-1) + d (the first remote). If a relayed signal from the unit and an identifier signal from the nth remote unit are received). The reason for the range of possible offsets R RIPN is that the terminal reports the fastest received identifier PN and the fastest received relay and identifier signals come from the same or different remote unit. [85] 5B is a system diagram showing signals received from the remote unit and the donor base station of a specific repeater. If the terminal is capable of receiving the forward modulated signal directly from the donor base station as well as the signal relayed from the repeater, the terminal receives the donor PN (DPN) received from the base station and the identification PN that arrives fastest for the repeater. Will report. The offset of the repeater PN relative to the donor PN will be in the following range. [86] R RIPN ∈ [d + x; 2 (n-1) + d + x] Formula (2) [87] Where x is the delay between the donor base station and the first (fastest arriving) remote unit for the repeater. [88] Note that from equations (1) and (2), the offset d for the identifier PN is common to the two ranges R RIPN and R IPN . If the delay x between the donor base station and the fastest arriving remote base station satisfies the condition x> 2n, it may be determined whether the terminal can receive a forward modulated signal from the donor base station or from a repeater. The information may be useful, for example, when the terminal is located in the coverage of the repeater receiving a signal from the donor base station or when the terminal is located away from the repeater coverage area receiving the leakage from the repeater. Can be. [89] In certain embodiments, multiple identifier signals may be generated based on different chip offsets of the signal identifier PN. [90] This may be desirable, for example, if different identifier signals are needed to individually identify each of the multiple remote units of the repeater. In this case, one identifier signal can be generated for each remote unit, and each identifier signal includes an identifier PN of a particular chip offset assigned to that remote unit. By using different chip offsets for identifier signals for different remote units, more specific estimation of the position of the terminal is possible. For example, different chip offsets may be used to estimate the position of the terminal relative to the coverage area of a particular remote unit (eg, a particular floor of a building) as opposed to the coverage area of the main unit (eg, a particular building). [91] 5C is a diagram illustrating an identifier signal of multiple remote units, the identifier signal being delayed by linearly increasing the chip offset. The delay for the identifier signal may be in addition to the delay for the signal being relayed. For example, if the relay signal for the remote unit is delayed by 2 chips, the identifier signal for the remote unit may be delayed by 4 chips. In an embodiment, the chip offset assigned to the remote unit is defined as [92] d IPN (i) = d + 2 (i-1), 1 ≤ i ≤ n (3) [93] Where d IPN (i) is the offset assigned to the i-th remote unit and d is the offset of the identifier PN relative to the relayed donor PN for the first remote unit (ie d = d IPN (1)). . As in the specific example shown in Fig. 5C, if the relay signal for the remote unit is delayed by two chips, and d = 8, and n = 3, the offset d IPN (i) for three remote units is {8, 10,12}. [94] By using different offsets for the remote unit, if a relay signal and an identifier signal from only one remote unit are received by the terminal at any given moment, the remote unit is specifically set by an offset between the relay signal and the identifier signal. Can be identified. [95] Multiple identifier signals of different chip offsets delay identifier signals (eg, signals in IF or RF) through filters with different delays, generate PN sequences with different chip offsets, upconvert such PN sequences, or partially It may be generated by another mechanism (eg by the main unit). [96] 5D is a diagram illustrating an identifier signal for multiple remote units, where the identifier signal is delayed by nonlinearly reducing the chip offset. In an embodiment, the chip offset assigned to the remote unit is defined as [97] d IPN (i) = d- (i-1) (i + 2), 1 ≤ i ≤ n (4) [98] Where d IPN (i) is the offset assigned to the i-th remote unit and d is the offset of the identifier PN relative to the relayed donor PN for the first remote unit (ie d = d IPN (1)). . As in the specific example shown in FIG. 5D, if the relay signal for the remote unit is delayed by two chips, and d = 14, and n = 5, the offset d IPN (i) for five remote units is equal to {14, 10,4, -4, -14}. [99] The different offsets generated by Equation 4 can be identified by the identification of the particular remote unit (where only one remote unit is received) where the identifier signal is detected or by two (or more) remote units where the identifier signal is detected. Enable the identification of the above remote unit). Table 1 lists the possible offset measurements by the terminal (column 1), the remote unit (column 2) that can be detected for the measured offset, and the remote unit (column 3) presented. [100] Table 1 [101] Measured offsetRemote unit (RU) detectable by terminaldecision dRU1RU1 d-2(RU1, RU2)(RU1, RU2) d-4RU2RU2 d-6RU2(RU1, RU3) d-8(RU1, RU3), optional RU2(RU2, RU3) d-10(RU2, RU3)RU3 d-12RU3(RU1, RU4) d-14(RU1, RU4), optional RU2, RU3(RU2, RU4) d-16(RU2, RU4), optional RU3(RU3, RU4) d-18(RU3, RU4)RU4 d-20RU4(RU1, RU5) d-22(RU1, RU5), optional RU2, RU3, RU4(RU2, RU5) d-24(RU2, RU5), optional RU3, RU4(RU3, RU5) d-26(RU4, RU5)(RU4, RU5) d-28RU5RU5 [102] The remote unit (column 3) presented in Table 1 can be derived as follows. For even values of d (eg, d = 14 for the example shown in FIG. 5D), the measured offset of the identifier PN relative to the relayed donor PN is first rounded off to the nearest value. It is indicated by. The remote unit (s) from which the identifier signal (s) are received Can be identified as follows: [103] (5) [104] For odd values of d, the measured offset of the identifier PN is rounded off to the nearest odd value, and the remote unit (s) are identified in a similar manner based on equation (5). [105] If multiple repeaters are used in a given coverage area (eg one cell or all cells) of the donor PN, and each repeater can have multiple remote units, the range of offsets reported by the terminal for each repeater is as follows. Can be expressed as: [106] R K ∈ R k, RIPN ∪R k, IPN , (6) [107] here, [108] R k is the range of offsets that can be reported to the k-th repeater, [109] R k, RIPN is the range of offsets when the k-th repeater is received but the donor base station is not received, [110] R k, IPN is the range of offsets when both the k-th relay and the donor base station are received, [111] "∪" is a union operation. [112] If x k = 2 (n k +1), the range R k can be expressed as follows. [113] R k ∈ [d k ; d k +4 n k ] (7) [114] Where d k is the planned offset between the relayed PN for the k-th repeater and the identifier PN, and n k is the number of remote units for the k-th repeater. Equation 7 is derived from Equations 1, 2, and 6. The first value of the range R k is the lower value of Equation 1 (ie d), and the last value of the range is given as the upper value in Equation 2 (ie 2 (n-1) + d + x). By replacing x = 2 (n + 1) and maintaining the condition of x> 2n, the end of the range R k is calculated as 4n + d as shown in equation (7). [115] The delay d k is chosen such that the following equation is satisfied: [116] d k + 1 = d k +4 n k +2 (8) [117] If Equation 8 is satisfied, the repeater where the relayed signal is received at the terminal can be clearly identified. The delay d 1 may be selected such that the identifier signal is in the search window used for pilot search. [118] In general, if a range of offsets is used for the identifier signal, the terminal is provided with range information so that the search window can be set appropriately. [119] If multiple repeaters are used in the coverage area, multiple PNs may also be used to identify each repeater individually. Each repeater may be assigned a respective identifier PN. The repeater may also be assigned two or more identifiers PN. For example, if two identifiers PN are available, a first identifier PN may be assigned to the first repeater, a second identifier PN may be assigned to the second repeater, and a combination of the first and second identifiers PN This may be assigned to the third repeater. Numerous combinations of offsets of such identifier PN can also be generated and used. [120] In a typical CDMA system, each base station can be associated with a respective neighbor list, which includes nearby base stations that are candidates for handoff. The terminal may be provided with a neighbor list associated with the base station with which the terminal communicates. The terminal may refer to the neighbor list as it continues to retrieve to store a signal instance (or multipath component) to determine if a handoff is required. [121] For the neighbor list IPN scheme, the PN sequence of the neighbor list (i.e. neighbor list PNs) used by the base station is also used for relay identification. Various considerations can be made in the selection of the neighbor list PN to be used for the IPN, the transmission of the IPN, and the use of INP measurements. Such consideration ensures that the measurement of the IPN is distinguishable from the measurement of the neighbor list PN used for the IPN. If such considerations are handled appropriately, the use of the neighbor list PN is similar to the use of a dedicated IPN, as described above. [122] Some selection criteria can be used to determine which neighbor list PNs can be used for the IPN. In one criterion, a neighbor list PN that is relayed cannot be used for an IPN. If no such constraint is added, the terminal may receive the same PN as (1) the donor PN relayed from one repeater and (2) the IPN from another repeater. Since the terminal reports a single measurement for each PN corresponding to the fastest arriving route, it may be ambiguous which reported PN came from one or the other repeater. In another criterion, if a given donor base station is associated with one or more repeaters, only the PN of the neighbor list for those base stations that cannot be detected at any of the associated repeaters may be used as the IPN for such repeaters. Such constraints can be ensured by, for example, obtaining PN search results from a unit located at each repeater and used to remotely configure and generate an IPN. [123] IPNs must be transmitted at specific power levels so that such IPNs can be reliably detected at the terminal while minimizing the impact on communication and system performance. As one consideration, the IPN should be transmitted at a sufficiently low power level, so that it will not be added to the terminal's candidate list. As a specific example, the IPN may be transmitted at 15 dB lower than the power of the relayed donor PN. For a lightly loaded cell with a relayed pilot E c / I O of −5 dB, the IPN may be transmitted at a power corresponding to E c / E O of −20 dB. [124] For an IS-95A network with a low threshold (T_ADD) to add a new base station to the candidate list, the IPN may be sent at a low power level. Extra margin can reduce the likelihood that the IPN measurement will rise due to noise (since the pilot power can be estimated by a short integration period) and exceed the T_ADD value. For IS-95B with a "dynamic" additional threshold value, the large difference in the pilot power of the relayed donor PN and the IPN should make it less likely that the IPN will be added to the candidate list. [125] In some cases, the terminal may be in a handoff range between (1) the repeater transmitting the donor PN and IPN and (2) the neighbor base station where the PN is used as the IPN by the repeater. The PN from the neighbor base station is referred to as a "neighbor PN" (NPN). [126] In this case, the terminal attempts (non-coherent) combining of the transmission from the donor base station and the transmission from the neighbor base station to improve the demodulation performance. In this case, the UE observes the IPN as another multipath component of the neighboring base station and compares the non-existent traffic channel associated with the IPN (because only the IPN is transmitted from the repeater) with the traffic channel of the neighboring base station. Try to combine. [127] This combined effect of the non-existent traffic channel associated with the IPN with that of the neighboring base station is very weak for the following reason. First, if the above-described IPN selection criteria are adhered to, the possibility of the terminal handing off between the repeater and this neighboring base station is very small. Secondly, the probability of the IPN being chosen for binding is very small. To be selected for combining, the IPN pilot power needs to exceed the in-lock threshold. However, the IPN pilot power is relatively weak (eg, 15 dB or less of repeated donor PN pilot power). Therefore, the IPN passes the in-lock threshold only when the repeated donor PN is received at the strong level by the terminal. Third, even though these contributions from the IPN are combined, they are very small. Since only the pilot channel is transmitted by the repeater for the IPN and no traffic channels are transmitted, only the detected noise for the non-existent traffic channel is combined. However, this noise is attenuated to a large extent. For the maximum combining ratio (used at the lake receiver), the traffic channel from each finger is weighted by the pilot power received by the finger prior to combining. Since the IPN pilot power is relatively weak (eg, less than I5 dB of the maximum power of the fingers), noise from the IPN is weighted to a small value. Fourth, the IPN will only be combined if there are redundant fingers used to track the relatively weak multipath component of the IPN. [128] If the IPNs for the repeaters are selected from neighbor list PNs, it is necessary to determine whether the signals (or PNs) are received directly from the base stations or via the repeaters. In an embodiment, this determination is subject to geometric constraints. [129] FIG. 6A is a diagram showing geometric constraints on TDOA measurements. FIG. In Figure 6A, the terminal receives pilots from two base stations, and the two received pilots are used to derive one TDOA measurement. The TDOA measurement indicates the difference in arrival times of the two received pilots, and the arrival time of the signal is proportional to the distance passed by the signal. Distances between the terminal and the two base stations are represented by r1 and r2, and distances between the two base stations are represented by d12. 6A, it can be seen that the distances r1, r2, d12 form a triangle. The following constraints may be formed: [130] -d12≤ (r1-r2) ≤d12 equation (9) [131] Geometric tests can be devised based on the geometric constraints expressed in equation (9). [132] Equation (9) assumes that no receiver timing and measurement error exists, so that the absolute value of each TDOA measurement (i.e. | r1-r2 |) is above an upper bound bounded by the distance d12 between two base stations. It is displayed. Thus, geometric limitations on TDOA measurements are used to determine (1) the excess delay for the TDOA measurement and / or (2) whether the pilots are delayed by the repeaters. [133] The IPN for each repeater is delayed for repeated donor signals by an amount greater than adding some margin to the distance between the donor and neighboring base stations. This can be expressed as follows; [134] ripn-rrdpn> ddn + dmar, or ripn> rrpn + ddn + dmar, equation (10) [135] Where ripn is an IPN measurement from the repeater; [136] rrpn is the RDPN measurement from the repeater; [137] ddn is the IPN and is the distance between the neighbor base station and the donor base station whose PN is used; [138] dmar is the margin. [139] Geometric restrictions on TDOA measurements are used to determine whether the signal received at the terminal is a signal from a repeater. Non-repeated donor PN (DPN), non-repeated neighbor PN (NPN), repeated donor PN (RDPN), and IPN, or a combination of these PNs are detected by the terminal as described in the following scenario. [140] 6B is a diagram illustrating a scenario where the terminal is under the repeater coverage area. In this scenario, the terminal receives the RDPN and IPN from the repeater, not the DPN or NPN. Then, the terminal reports the RDPN and IPN to the PDE performing the geometric test. Since these PNs are sent from the same source, the TDOA measurements between the RDPN and the IPN must be accurate. As shown in equation (10), if the IPN is delayed by at least ddn + dmar for the RDPN, then the geometric test for the RDPN and IPN measurements shows that the distance between the IPN measurement and the RDPN measurements is at least margin (i.e. ripn-rrdpn>). ddn + dmar), which is greater than the distance between the donor and neighboring base stations. This geometric test failure can be used as an indication that an IPN was received from a repeater rather than from a neighbor base station whose PN is used as an IPN. [141] 6C is a diagram illustrating a scenario in which a terminal exists under a joint coverage area of a repeater, a donor base station, and a neighbor base station. In this scenario, the terminal receives the RDPN and IPN from the repeater, the direct DPN from the donor base station, and the direct NPN from the neighbor base station. The terminal then reports the earliest multipath component arriving for each individual PN, which is the DPN and NPN received over the non-repeating paths. DPN and NPN can then be used by the PDE in the normal way. [142] 6D is a diagram illustrating a scenario in which a terminal exists under a joint coverage area of a repeater and a donor base station. In this scenario, the terminal receives the RDPN and IPN from the repeater and the direct DPN from the donor base station. The terminal then reports the DPN and IPN, which are the earliest arriving multipath components for these PNs. If the DPN is delayed by drep by the repeater to generate an RDPN, then the TDOA measurement for DPN and IPN is ripn-rrdpn> ddn + dmar + drep. The geometric test then fails, and this failure is used as an indication that the IPN was received via the repeater. [143] 6E is a diagram illustrating a scenario in which a terminal exists in a joint coverage area of a repeater and a neighbor base station. In this scenario, the terminal receives the RDPN from the repeater and the NPN directly from the neighboring base station. The terminal may or may not receive an IPN from the repeater. And report the NPN to the screw terminal, where NPN is the earliest multipath component arriving for these PNs and RDPNs. TDOA measurements for RDPN and NPN are rdpn-rnpn or rdpn + drep-rnpn. [144] If the repeater delay drep is large enough, the geometric test fails and this failure is used to discard measurements obtained from the repeater. However, if the delay of the NPN is large enough or the repeater delay is not large enough, the TDOA measurement does not violate the geometric test. In such a case, other techniques may be used to distinguish between (1) reception of an IPN via a repeater and (2) direct NPN reception from a neighboring base station via an excess delay on the NPN. For example, more than one IPN can be used for this determination. The probability that such an event will occur can be kept small by selecting the appropriate neighbor list PNs for use as IPNs. [145] The scenario shown in FIG. 6E does not generally occur for indoor repeaters, but may occur for outdoor repeaters. This scenario may occur regardless of whether dedicated PNs or neighbor PNs are used for IPNs. [146] In the foregoing, it is assumed that IPNs are delayed in the positive direction with respect to RDPNs. This is not a requirement. The IPNs may be delayed in the negative direction by a larger dip than the distance ddn between the donor and neighboring base stations plus the repeater delay drep and some dmar. This is expressed as follows: [147] dipn≥ddn + drep + dmar equation (11) [148] In the embodiment of the presented method and apparatus, it should be noted that if it is determined that a signal is to be delivered via a repeater, the signal is not used in positioning. This provides a simple and low cost way of ensuring that the delay added to the signal travel time from the base station to the terminal does not cause errors in the positioning. In other words, since the propagation delay between the time the signal is transmitted from the base station and the time the signal is received by the terminal does not accurately reflect the distance between the base station and the terminal, this delay should not be used in positioning. If the repeater identification through which the signal passed and additional information about the location of this repeater is available, that information can be used to determine the location of the terminal. However, it should be noted that there may be sufficient information from other signals not passing through the repeaters to enable positioning of the terminal without using information from the signals passing through the repeater. In either case, recognizing that a signal has passed through a repeater and that an additional delay has been added to the signal by the repeater does not use timing information for that signal or allows such delays to be considered by adjusting the timing information appropriately. Do it. [149] When the PDE provides the PDE with a code of signals received by the terminal so that the signals can be determined whether or not the signals have been sent from the repeater, the PDE makes a decision whether to use such a signal and is sent by the repeater (from the base station to the terminal). May choose to ignore any signals that are not directly received by it. In an alternative embodiment, where the positioning is made at the terminal or relative measurements are made that the terminal needs information (such as the relative phase of the received signals) to derive information to be sent to an external device such as a base station or a PDE, The terminal selects to ignore the information on the signals received from the repeater. [150] 7 is a block diagram of a terminal 106x that may implement various aspects and embodiments of the presented method and apparatus. In the forward link, signals from GPS satellites, base stations, and / or repeaters are received by antenna 712, routed through multiplexer 714, and provided to RF receiver unit 722. RF receiver unit 722 conditions (eg, filters, amplifies, and downconverts) the received signal and digitizes the received signal to provide samples. Demodulator 724 then receives and processes (eg, despread, decover, and pilot demodulate) the samples to provide reconstructed samples. Demodulator 724 may run a rake receiver capable of processing multiple instances of the received signal and combine the recovered symbols for multiple multiple paths. Receiver data processor 726 then decodes the recovered symbols, examines the received frames, and provides output data. [151] For location determination, the RF receiver unit 722 is operated to provide the controller 730 with arrival times for the most strongly received multipaths or for multipaths with signal strength above a certain threshold. Samples from the RF receiver unit 722 may be provided to a signal quality meter 728 that measures the quality of the received signals. This signal quality can be evaluated using various known techniques such as US Pat. Nos. 5,056,109 and 5,265,119. For location determination, demodulator 724 is operated to provide PN sequences recovered from base stations and identifier PNs recovered from repeaters, if present. [152] The GPS receiver 740 receives and searches for GPS signals based on a search window provided by the controller 730. The GPS receiver 740 then provides the time measurements for the GPS satellites to the controller 730. In some embodiments, GPS receiver 740 is not included in terminal 106x. The techniques presented herein can be used for positioning methods that do not use a GPS receiver. [153] The controller 730 receives measurements for base stations and / or GPS satellites, PN sequences for base stations, identifier PNs for repeaters, measured signal quality of received signals, or a combination thereof. . In an embodiment, the measurements and the identifier PNs are provided to the TX data processor 742 for transmission to the PDE using this information to determine the location of the terminal 106x. Controller 730 further provides a signal instructing units in terminal 106x to perform appropriate signal processing. For example, the controller 730 may provide a demodulator 724 with a first signal that directs the PN to search for a particular range of chip offsets, and by the GPS receiver 740 to retrieve signals from GPS satellites. Provide a second signal or the like indicating the search windows to be used. [154] Demodulator 724 retrieves strong instances of pilot references from base stations (which may be repeated) and the identifier PN (eg, if detected). This is accomplished by correlating the received samples with a locally generated PN sequence at various offsets. High correlation results indicate a high likelihood that a PN has been received at that offset. [155] If appropriate, various ways can be implemented to ensure that demodulator 724 retrieves the identifier PN from the repeaters. In one scheme, the identifiers PNs are included in the neighbor list of PN sequences to be retrieved. In general, this neighbor list maintained for each active terminal includes strong pilot references detected by the terminal. In another way, the neighbor list for each active terminal is sent by the PDE. In this case, the PDE may be provided with information about base stations in the system, information about related repeaters, and identifier PNs for the repeaters. And NASA, PDE ensures that the appropriate identifiers PNs are included in the neighbor list for each active terminal. In another manner, the PDE may automatically transmit a list of PNs to be searched including the identifier PN to the terminal. This list is sent for location related calls. In another manner, the list of identifier PNs can be broadcast to terminals in a broadcast channel. In another method, the PDE may send identifier PNs to the terminal upon request, for example if it is known that there are repeaters and there are not enough GPS measurements to perform positioning. [156] On the reverse link, data is processed (e.g., formatted, encoded) by the transmit (TX) data processor 742, and further processed (e.g., covered, spread) by a modulator (MOD) 744. Conditioned by RF TX unit 746 (eg, converted to analog signals, amplified, filtered, modulated, etc.) to generate a reverse modulated signal. This information from controller 730 (eg, identifier PN) is multiplexed with the data processed by modulator 744. The reverse modulated signal is then routed through duplexer 714 and transmitted via antenna 712 to base stations and / or repeaters. [157] 8 is a block diagram of an embodiment of a PDE 130 that may support various aspects of the methods and apparatus presented herein. PDE 130 interfaces with BSC 120 and exchanges information related to positioning. [158] In the reverse link, the reverse modulated signal data for the terminal is delivered to the repeater, transmitted to the base station, routed to the BSC, and provided to the PDE. Within the PDE, the reverse modulated signal from the terminal is processed by the transceiver 814 to provide samples, which are further processed by the RX data processor 822 to recover the data sent by the terminal. Such data may include any combination of measurements reported by the terminal, identifier PN, and the like. The data processor 822 then provides the data received to the controller 810. [159] The controller 810 may also add additional data from the data storage unit 830 (eg, information about whether the base station has been repeated, information about the center of the coverless area, and information about the delay associated with each repeater). Receive and measure the position of the terminal based on the data from the terminal and the additional data from the storage unit 830. Storage unit 830 may be used to store tables for base stations, associated repeaters (if present), and identifier PN and location measurements (eg, center of coverage area) for each repeater. [160] In some embodiments, controller 810 determines the identifier PN included in the neighbor list for the terminals in all sectors. Alternatively, in the case where the identifiers PNs are not included in the neighbor list, the PN identifier is provided by the controller 810 to the terminal. This identifier PN is then provided to the TX data processor 812, which properly formats the data and sends it to the transceiver 814. The transceiver 814 further conditions the data and transmits the data to the terminal via the BSC, base station, and (possibly) repeater. [161] The techniques presented herein may be advantageously used for location determination in indoor applications where signals from other base stations and / or GPS satellites are not received and the coverage area of the repeaters is generally small. The techniques presented herein can also be used for outdoor applications. In an embodiment, the outdoor repeater may be calibrated to determine the delay associated with the repeater. The identifier signal transmitted by the outdoor repeater is used to identify on which repeater the repeated forward modulated signal was received by the terminal. The measurements for the terminal in coverage of this repeater are then adjusted accordingly to obtain more accurate measurements. For example, the round trip delay (RTD) from the repeater position can be adjusted according to the delay associated with the repeater. The time offset at the terminal is updated to reflect the repeater's delay, thereby providing a more accurate time reference for the GPS measurements. The techniques presented here may be used even when duplicated PNs are observed by the terminals. [162] As mentioned above, the coverage area of the repeater for indoor applications is generally small. If the center of the repeater coverage area is provided as a position measure for a terminal within the repeater's coverage area, the error is in many cases (but not in most cases) small and can meet the E-911 regulations defined by the FCC. In one embodiment, the entity (PDE or terminal) responsible for performing the location measurement may also be provided with a size measurement of the repeater coverage area. In this case, the entity may report a confidence in the accuracy of the position measurement (eg whether it satisfies the E-9111 rule). [163] For clarity, the identification code of each repeater is described as being implemented through a PN sequence at a particular (PN INC) offset. The identification code for the repeater can also be implemented in a variety of other ways. For example, the identification code may be via any PN sequence (not necessarily the same as the spreading PN sequence in a CDMA system), gold code, any low data rate code that can be modulated for the repeating signal, and the like. Can be implemented. The identification code for the repeater may or may not be aligned at system time, as observed at the terminal. [164] For clarity, various aspects and embodiments have been described for an IS-95 CDMA system. The techniques presented herein may be used for other types of CDMA systems and other non-CDMA systems. For example, the use of identification codes (eg, identifier PNs) for repeater identification may be used for W-CDMA systems, cdma2000 systems, and the like. Identification codes for repeater identification can also be used in GSM systems. In a GSM system, an identification code may be sent on a "dummy" channel (with or without a given offset) on different frequencies instead of the same frequency used for the forward modulated signal. Different channels on different frequencies may be used for each repeater in a sector or geographic area, or the repeaters may be distinguished by data or channel offsets transmitted on a given channel. [165] The identification code may be transmitted using any spread spectrum communications technique or other communications techniques within the CDMA channel. In the above embodiments, the identification code for the repeater is transmitted by the repeater simultaneously with the forward modulated signal. In some other embodiments, the identification code for the repeater may be sent on a “local” system, such as, for example, a wireless system operating simultaneously. A system such as this wireless system may be a wireless LAN IEEE-802.11 system. [166] Other schemes can be used to identify repeaters in a wireless communication system. In one scheme, if the system and the terminal can report a multipath profile, multipath profile identification is generated, for example, based on the forward modulated signal and used for repeater identification. CDMA terminals can generally handle multiple instances of a received signal resulting from reflections on the signal path. Such multipaths are generally demodulated and combined by the terminal to provide symbols to be decoded. If a multipath profile can be reported, each repeater is associated with a specific multipath profile instead of the identifier signal. [167] Multipath profiles for each repeater can be generated in a variety of ways. In one embodiment, the forward modulated signal is delayed (and possibly attenuated) by a number of specific values, and these multiple delayed signals are combined and transmitted to the terminals. The number of multipaths and the amount of delay for each multipath is chosen so that a unique multipath profile is generated and a unique multipath profile can be used to identify each repeater. In another embodiment, the identifier PN may be delayed by a number of specific chip offsets, and the delayed PN sequences may be combined to provide a multipath profile. In this embodiment, the PN sequence of the serving base station may be used (instead of the identifier PN) to generate a multipath profile. [168] Repeater identification can be sent on an auxiliary low rate CDMA channel, which is aligned with the CDMA channels from the serving base station. The identification code for the repeater can then be sent as data on the low rate channel. [169] In addition to the above advantages associated with the use of the identifier signal presented here, another advantage is that position measurement is possible without blocking voice calls. According to the IS-801 standard, pilot measurements are sent to the PDE when the terminal sends a support request from the GPS to determine the terminal location. If the PDE recognizes the identifier PN in the list of PN sequences reported by the channel, the GPS measurement does not need to be performed because the terminal is in the repeater's coverage area and the terminal may not be able to receive GPS signals. It may be. In addition, the position measurement of the terminal can be determined only with the required accuracy according to the identifier PN (e.g., the position of the terminal can be measured as the center of the repeater's coverage area). In this case, the identifier PN is included in the neighbor list of all base stations using repeaters so that the terminal can retrieve the identifier PN. Alternatively, if the PDE has a reason to suspect that the signal received by the terminal was sent by the repeater, a list of identifier PNs may be sent to the terminal prior to transmitting the GPS assistance information. [170] Some elements of a repeater (eg, PN generator, controller, and upconverter) used to implement the techniques presented herein include a digital signal processor (DAP), application specific integrated circuit (ASIC), processor, microprocessor, controller, microcontroller. It may be implemented via a controller, field programmable gate array (FPGA), programmable logic device, electrical unit, or any combination designed to perform the functions presented herein. Aspects of the methods and apparatus presented herein may be implemented by hardware, software, or a combination thereof. For example, processing for forming a neighbor list for each active terminal, terminal position measurement, and the like are performed according to the program code stored in the memory and executed by the processor (controller 810 of FIG. 8). [171] The above-described embodiments have been described in order to enable those skilled in the art to more easily implement the present invention. Therefore, those skilled in the art will appreciate that the present invention is not limited to the above-described embodiments and that various modifications are possible based on the technical spirit of the present invention.
权利要求:
Claims (67) [1" claim-type="Currently amended] A method of determining the location of a device in a wireless communication system, Receiving from the transmission source a first signal having transmission data contained therein and a second signal having an identification code assigned to the transmission source included therein; Processing the second signal to recover the identification code; And Determining a location measurement of the device based on the restored identification code. [2" claim-type="Currently amended] The method of claim 1, And wherein said transmission source is a repeater of a wireless communication system. [3" claim-type="Currently amended] The method of claim 1, And said second signal is a spread spectrum signal. [4" claim-type="Currently amended] The method of claim 3, Wherein said spread spectrum signal conforms to a CDMA standard. [5" claim-type="Currently amended] The method of claim 4, wherein Wherein said spread spectrum signal conforms to IS-95 CDMA standard. [6" claim-type="Currently amended] The method of claim 1, And the identification code comprises a pseudo-noise (PN) sequence at a particular offset. [7" claim-type="Currently amended] The method of claim 1, And wherein said identification code comprises a plurality of pseudo-noise (PN) sequences. [8" claim-type="Currently amended] The method of claim 7, wherein Wherein the plurality of PN sequences are at a particular offset. [9" claim-type="Currently amended] The method of claim 1, The identification code comprises a delayed and attenuated version of the first signal. [10" claim-type="Currently amended] The method of claim 1, The identification code includes a plurality of delayed and attenuated versions of the first signal, wherein the identification code represents a particular multipath profile. [11" claim-type="Currently amended] The method of claim 1, And the identification code comprises a signal transmitted at a different frequency than the first signal. [12" claim-type="Currently amended] The method of claim 1, And the identification code comprises a signal transmitted at a different transmission frequency and a specific transmission offset than the first signal. [13" claim-type="Currently amended] The method of claim 1, And the identification code comprises one or more gold code sequences. [14" claim-type="Currently amended] The method of claim 13, A method of positioning each gold code sequence at a particular offset. [15" claim-type="Currently amended] The method of claim 1, Adjusting the set of positioning measurements in accordance with the reconstructed identification code. [16" claim-type="Currently amended] The method of claim 1, The location measurement of the device is a specific location within the coverage area of the transmission source. [17" claim-type="Currently amended] The method of claim 16, The location measurement of the device is approximately center of the coverage area of the transmission source. [18" claim-type="Currently amended] The method of claim 1, The wireless communication system is a CDMA system. [19" claim-type="Currently amended] The method of claim 1, The wireless communication system is a TDMA system. [20" claim-type="Currently amended] The method of claim 2, And said second signal is a spread spectrum signal. [21" claim-type="Currently amended] The method of claim 2, And wherein said identification code is a pseudo-noise (PN) sequence at a particular offset. [22" claim-type="Currently amended] The method of claim 2, The position measurement of the device is a specific position within the coverage area of the repeater. [23" claim-type="Currently amended] A method for generating a signal suitable for use for positioning a device in a wireless communication system, Receiving from the transmission source a first signal having transmission data contained therein; Generating at the transmission source a second signal having an identification code contained therein and assigned to the transmission source; Combining the first and second signals to generate a combined signal; And Transmitting the combined signal from the transmission source. [24" claim-type="Currently amended] The method of claim 23, wherein Processing the first signal to recover a timing reference; Wherein the second signal is generated according to the reconstructed timing reference. [25" claim-type="Currently amended] The method of claim 24, Processing the first signal to recover a frequency reference of a carrier signal of the first signal, Wherein the second signal is further generated in accordance with the reconstructed frequency reference. [26" claim-type="Currently amended] The method of claim 23, wherein And the transmission source is a repeater in a communication system. [27" claim-type="Currently amended] The method of claim 26, Further conditioning the combined signals in the repeater unit, Wherein the conditioned signal from the repeater unit is transmitted from the repeater. [28" claim-type="Currently amended] The method of claim 26, Further conditioning the first signal in a repeater unit, Wherein the second signal is combined with the conditioned first signal in a repeater unit. [29" claim-type="Currently amended] The method of claim 23, wherein And wherein said identification code is a pseudo-noise (PN) sequence at a particular offset. [30" claim-type="Currently amended] The method of claim 29, The offset of the PN sequence used as the identification code is one of a plurality of possible offsets and is reserved for transmission source identification. [31" claim-type="Currently amended] The method of claim 29, And the timing of the PN sequence used for the identification code is approximately aligned with the timing of the PN sequence used to spread the transmitted data of the first signal. [32" claim-type="Currently amended] The method of claim 23, wherein And a carrier frequency of the second signal is similar to a carrier frequency of the first signal. [33" claim-type="Currently amended] The method of claim 23, And the second signal is a spread spectrum signal. [34" claim-type="Currently amended] The method of claim 23, wherein And the amplitude of the second signal is set to a specific level less than or equal to the amplitude level of the first signal. [35" claim-type="Currently amended] The method of claim 23, wherein And said wireless communication system is a CDMA system. [36" claim-type="Currently amended] A method for generating a signal suitable for use in measuring a terminal position in a wireless communication system, Receiving and processing at a transmission source a first signal having transmission data contained therein; Generating a second signal having an identification code contained therein and assigned to the transmission source; Transmitting the first signal from the transmission source; And Transmitting the second signal to a plurality of terminals in the communication system. [37" claim-type="Currently amended] The method of claim 36, And the second signal comprises a plurality of signals at different offsets and exhibits a particular multipath profile. [38" claim-type="Currently amended] The method of claim 36, And the second signal comprises a plurality of pseudo-noise (PN) sequences at a plurality of offsets and indicates a plurality of multipath profiles. [39" claim-type="Currently amended] A method of determining a terminal location in a wireless communication system, Receiving, at the terminal, an indication of a specific identification code assigned to the transmission source; Receiving from the transmission source a first signal having transmitted data included in the loan and a second signal having an identification code included therein; And Processing the second signal to recover the identification code, Wherein the recovered identification code is used to identify a transmission source and the terminal location is measured based on a location measurement associated with the identification code. [40" claim-type="Currently amended] The method of claim 39, And the list of identification codes is included in a neighbor list of codes to be retrieved. [41" claim-type="Currently amended] The method of claim 39, The list of identification codes is transmitted to the terminal in response to the call associated with the position measurement. [42" claim-type="Currently amended] The method of claim 39, The list of identification codes is broadcasted to the terminal via a broadcast channel location determination method. [43" claim-type="Currently amended] The method of claim 39, The list of identification codes is sent to the terminal upon request by the terminal. [44" claim-type="Currently amended] A first unit operative to receive, condition, and retransmit signals on the forward and reverse links of the communication system; And A second unit connected to the first unit, The second unit A first module operative to receive and process a first signal on a forward link having transmitted data contained therein; A second module operative to generate a second signal contained therein and having an identification code assigned to the transmission unit; And And a third module operative to combine the first and second signals to provide a combined signal for transmission from the transmitting unit. [45" claim-type="Currently amended] The method of claim 44, The first module is further operative to process the first signal to recover a timing reference, wherein the second signal is generated in accordance with the restored timing reference. [46" claim-type="Currently amended] The method of claim 45, A first module is further operative to process the first signal to recover a frequency reference for the carrier signal of the first signal, wherein the second signal is further generated in accordance with the recovered frequency reference. Transmission unit. [47" claim-type="Currently amended] A receiver capable of receiving a repeater that was not transmitted by the repeater and signals transmitted by the repeater; And a processor capable of determining whether received signals have been sent by the repeater and further ensuring that signals received from the repeater are not used to determine the location of the communication terminal. [48" claim-type="Currently amended] A method for ensuring that signals transmitted through a repeater of a communication system are not used to achieve position determination, Receiving signals not transmitted by the repeater and signals transmitted by the repeater; Determining whether the received signals were sent by the repeater; And Ensuring that signals received from the repeater are not used to determine the location of the communication terminal. [49" claim-type="Currently amended] The method of claim 48, And determining whether received signals have been sent by the repeater by detecting the identification code inserted in the signals by the repeater. [50" claim-type="Currently amended] A method for ensuring that signals transmitted through a repeater of a communication system are not used to achieve position determination, Receiving signals transmitted by the repeater and signals transmitted by the repeater; Transmitting information about the received signals comprising an identification code that determines whether the received signals have been sent by the repeater; And Ensuring that information associated with signals received from the repeater is not used for positioning of the communication terminal. [51" claim-type="Currently amended] A method of determining the location of a device in a wireless communication system, Receiving from the first transmission source a first signal having transmitted data contained therein and a second signal having a first identification code contained therein and assigned to the first transmission source, wherein the first identification The code is selected from a list of identification codes used for adjacent transmission sources; Processing the second signal to recover the first identification code; And Determining a position measurement of the device based on the restored first identification code. [52" claim-type="Currently amended] The method of claim 51, The determination of whether the first identification code has been received from the first transmission source or from another transmission source is made based on a geometric constraint. [53" claim-type="Currently amended] 53. The method of claim 52, wherein the geometric constraints relate to arrival time difference (TDOA) measurements. [54" claim-type="Currently amended] The method of claim 51, Only identification codes in the list that are not repeated by other transmission sources are available for use as the first identification code for the first transmission source. [55" claim-type="Currently amended] The method of claim 51, And the first identification code comprises a plurality of identification codes in a list. [56" claim-type="Currently amended] The method of claim 55, And a plurality of identification codes for the first identification code are associated with different offsets. [57" claim-type="Currently amended] The method of claim 51, The neighboring transmission sources are neighbor base stations and the identification codes in the list are PN sequences assigned to neighbor base stations. [58" claim-type="Currently amended] The method of claim 51, An identification code assigned to the first transmission source is delayed with respect to the first signal by a specific delay amount. [59" claim-type="Currently amended] The method of claim 58, The delay amount is selected to determine whether the first identification code has been received from the first transmission source or from another transmission source. [60" claim-type="Currently amended] A receiver operative to receive from a first transmission source a first signal having transmitted data contained therein and a second signal having a first identification code contained therein and assigned to the first transmission source, the receiver comprising: The first identification code is a receiver selected from a list of identification codes used for adjacent transmission sources; And And a processor operative to process the second signal to recover the first identification code, wherein a position measurement of the terminal is determined based on the restored first identification code. [61" claim-type="Currently amended] The method of claim 60, The determination of whether the first identification code is received from a first transmission source or from another transmission source is determined based on geometric constraints. [62" claim-type="Currently amended] A method of determining the location of a device in a wireless communication system, Receiving a signal from a transmission source having transmitted data contained therein; Processing the signal to recover the identification code; And Determining a position measurement of the device based on the recovered identification code. [63" claim-type="Currently amended] The method of claim 62, And the signal is modulated by an identification code. [64" claim-type="Currently amended] The method of claim 62, And wherein said identification code is a PN sequence used for transmission source identification. [65" claim-type="Currently amended] The method of claim 62, An identification code is a sequence of PNs used by other transmission sources to spread data spectrally. [66" claim-type="Currently amended] A first unit operative to receive and process a first signal having transmitted data contained therein and to generate a second signal having an identification code contained therein and assigned to the transmitting unit; And A second unit connected with the first unit and operative to receive the first signal and modulate the first signal to the second signal to provide a modulated signal for transmission from the transmitting unit, wherein the identification The code is a transmission unit in a wireless communication system used for positioning. [67" claim-type="Currently amended] A receiver operative to receive a first signal having transmitted data contained therein from a transmission source, wherein the first signal is further modulated with a second signal contained therein and having an identification code assigned to the transmission source. And the receiver further comprises a receiver operative to process the first signal to recover the second signal; And And a processor operative to process the second signal to recover the identification code, wherein a position measurement of the terminal is determined based on the restored identification code.
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同族专利:
公开号 | 公开日 RU2308810C2|2007-10-20| CN101600250B|2011-07-27| MXPA03009756A|2004-06-30| CN101600250A|2009-12-09| JP2004532576A|2004-10-21| AT466471T|2010-05-15| US7139580B2|2006-11-21| IL158539D0|2004-05-12| US20030008669A1|2003-01-09| RU2003133988A|2005-05-10| CN1565138A|2005-01-12| NO20034734D0|2003-10-23| DE60236148D1|2010-06-10| NO329575B1|2010-11-15| AU2002305231B2|2008-04-17| JP4373096B2|2009-11-25| EP1382217B1|2010-04-28| CA2445021A1|2002-10-31| KR100899465B1|2009-05-27| WO2002087275A2|2002-10-31| CN100548076C|2009-10-07| HK1070523A1|2010-07-09| BR0209142A|2005-01-18| EP1382217A2|2004-01-21| NO20034734L|2003-12-04| IL158539A|2010-04-29| WO2002087275A3|2002-12-19| AU2002305231C1|2009-01-29|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题
法律状态:
2001-04-24|Priority to US28627401P 2001-04-24|Priority to US60/286,274 2001-06-18|Priority to US29931501P 2001-06-18|Priority to US60/299,315 2001-07-12|Priority to US09/904,330 2001-07-12|Priority to US09/904,330 2001-08-20|Priority to US09/933,629 2001-08-20|Priority to US09/933,629 2002-04-24|Application filed by 콸콤 인코포레이티드 2002-04-24|Priority to PCT/US2002/013104 2003-11-19|Publication of KR20030088511A 2009-05-27|Application granted 2009-05-27|Publication of KR100899465B1
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申请号 | 申请日 | 专利标题 US28627401P| true| 2001-04-24|2001-04-24| US60/286,274|2001-04-24| US29931501P| true| 2001-06-18|2001-06-18| US60/299,315|2001-06-18| US09/904,330|2001-07-12| US09/904,330|US20030008663A1|2001-04-24|2001-07-12|Method and apparatus for estimating the postion of a terminal based on identification codes for transmission sources| US09/933,629|US20030008664A1|2001-04-24|2001-08-20|Method and apparatus for estimating the postion of a terminal based on identification codes for transmission sources| US09/933,629|2001-08-20| PCT/US2002/013104|WO2002087275A2|2001-04-24|2002-04-24|Method and apparatus for estimating the position of a terminal based on identification codes for transmission sources| 相关专利
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