WO2009070464A1 - Automated configuration of a wireless location system - Google Patents
Automated configuration of a wireless location system Download PDFInfo
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- WO2009070464A1 WO2009070464A1 PCT/US2008/083813 US2008083813W WO2009070464A1 WO 2009070464 A1 WO2009070464 A1 WO 2009070464A1 US 2008083813 W US2008083813 W US 2008083813W WO 2009070464 A1 WO2009070464 A1 WO 2009070464A1
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Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S5/00—Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations
- G01S5/02—Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations using radio waves
- G01S5/0205—Details
- G01S5/021—Calibration, monitoring or correction
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S5/00—Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations
- G01S5/02—Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations using radio waves
- G01S5/0205—Details
- G01S5/0221—Receivers
- G01S5/02213—Receivers arranged in a network for determining the position of a transmitter
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S5/00—Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations
- G01S5/02—Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations using radio waves
- G01S5/0205—Details
- G01S5/0236—Assistance data, e.g. base station almanac
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S5/00—Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations
- G01S5/02—Position-fixing by co-ordinating two or more direction or position line determinations; Position-fixing by co-ordinating two or more distance determinations using radio waves
- G01S5/0284—Relative positioning
- G01S5/0289—Relative positioning of multiple transceivers, e.g. in ad hoc networks
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W48/00—Access restriction; Network selection; Access point selection
- H04W48/08—Access restriction or access information delivery, e.g. discovery data delivery
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W48/00—Access restriction; Network selection; Access point selection
- H04W48/16—Discovering, processing access restriction or access information
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W64/00—Locating users or terminals or network equipment for network management purposes, e.g. mobility management
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W88/00—Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
- H04W88/08—Access point devices
Definitions
- the present disclosure relates generally to methods and apparatus for locating wireless devices, also called mobile stations (MS), such as those used in analog or digital cellular systems, personal communications systems (PCS), enhanced specialized mobile radios (ESMRs), and other types of wireless communications systems. More particularly, but not exclusively, the present disclosure relates to a method for use in automatically providing configuration data in a wireless location system (WLS). Such a method can reduce the cost and complexity of deploying and maintaining a WLS.
- MS mobile stations
- PCS personal communications systems
- ESMRs enhanced specialized mobile radios
- the present disclosure relates to methods and systems that improve the operational efficiency of a WLS, e.g., by maintaining a database containing configuration data as well as historical data identifying the location measurement units (LMUs) as well as the location technology that were utilized in locating a MS in a specific cell or sector.
- LMUs location measurement units
- U-TDOA uplink time difference of arrival
- FCC Federal Communications Commission
- Enhanced 9-1-1 Phase II mandate requires that network-based systems, such as U-TDOA systems, be deployed to yield a precision that generates a one-hundred meter (100m or 328.1 feet) accuracy for 67% of emergency services callers and a three-hundred meter (300m or 984,25 feet) accuracy for 95% of emergency services callers.
- Overlay network-based wireless location systems have been widely deployed in support of location-based services including emergency services location.
- Table 1 identifies top-level information on the wireless communications system and all individual Base Stations, Node-B or Access point sites. The information requested in each field should be provided by the wireless network provider or operator for every Base Station, Node-B or Access Point site in the to-be deployed market. Once collected, this information forms the basis of the Serving Mobile Location Center (SMLC) database as well as part of the accuracy prediction modeling.
- SMLC Serving Mobile Location Center
- Table 2 identifies an entry for each cell or sector in each base station site identified in the market. If multiple sectors are used at a site, data should be provided, as a separate record, for each sector. If multiple air interface technologies are used at a site, data should be provided, as a separate record, for each air interface and each sector using that technology. Table 2 is presented here with the assumption of 3-sectors per cell site or less. Additional sectors will result in additional columns.
- the uplink radio receiver system originally called the Signal Collection System (SCS)
- SCS Signal Collection System
- LMU Location Measurement Unit
- PDE Position Determining Entity
- TIA Telecommunications Industry Association
- AMPS/TDMA/CDMA AMPS/TDMA/CDMA term
- CGI Cell Global Identifier
- CI Cell Identity
- AP Access Point
- BS Base Station
- Certain wireless communications network terms are used interchangeably depending on whether they refer to the usage (e.g. "Beacon”), the standardized term (e.g. "BCCH”) or the identifier associated with the antenna (e.g. CGI).
- TDMA/FDMA time and frequency division multiplexed radio communications systems
- TDMA time and frequency division multiplexed
- GSM Global System for Mobile Communications
- OFDM orthogonal frequency division multiplexed
- CDMA IS-95, IS-2000
- UTMS Universal Mobile Telecommunications System
- GSM Global System for Mobile Communications
- the embodiments described herein are configured to employ downlink receiver and GPS systems of a WLS to reduce the errors and effort attendant to compilation of configuration data collected from the operator's network and global navigation satellite systems as well as the self-discovery of communications link support. This can in turn yield lower cost of deployment and operation for the WLS operator.
- Automated configuration and reconfiguration make use of subsystems already developed and deployed in U-TDOA, AoA 5 or in hybrid U-TDO A/AoA, U-TDOD/A-GPS or U- TDOA/AoA/ A-GPS hybrid wireless location systems.
- a goal of automated configuration of a WLS is to lower the cost of system deployment.
- the same capabilities used to lower deployment costs may also be used to automate and thus lower the cost of reconfiguration of the WLS whenever the underlying operator radio system is reconfigured.
- the LMU (formerly called the SCS) possesses three subsystems allowing for collection of data used in the automation process.
- the overlay LMU is typically co-located with the radio communications network's transceivers and re-uses the existing radio front end, saving on the cost of antennas, cabling, amplifiers and filters.
- the LMU can be sited in a standalone fashion if deployed with a radio front-end.
- the LMU may also be incorporated into the wireless network's base station as a dedicated or shared receiver and processing unit.
- the LMU possesses a GPS receiver subsystem used for determination of a common time reference by the geographically dispersed U-TDOA and AoA LMU receivers.
- the GPS receiver subsystem will not only determine time, but also provide the automation application with the precise position of the GPS antenna. Since the LMU installation, and most importantly the LMU's uplink (mobile device-to-LMU) receive antenna is proximate to the GPS antenna, manually entered coordinates of the LMU and receive antenna can be verified by the automation application. This GPS antenna may be shared with the hosting base station if GPS timing is also used by the base station.
- the LMU may be configured with a communications subsystem with multiple output ports. These ports may include a Tl/El switched circuit data port, an Ethernet (IEEE 802.11) asynchronous packet data port, and a V.35 synchronous serial modem port. These ports may be connected to external converters or switching hardware to interface into a further variety of wired or wireless backhaul options.
- the automation application may be configured to automatically detect the port in use as well as transmission characteristics, which enables the system to automate configuration of the LMU-SMLC backhaul connection.
- the LMU is deployed with a downlink antenna subsystem to enable downlink beacon discovery. See U.S. Application Serial No. 11/736,902, filed April 18, 2007, "Sparsed U-TDOA Wireless Location Networks," which is hereby incorporated by reference in its entirety.
- the WLS can be configured for:
- the WLS can include an SMLC database containing configuration data as well as historical data identifying the LMUs as well as the location technology that were utilized in locating a MS in a specific cell or sector. Such historical information can be used to efficiently identify the specific LMUs and location technology to use in handling new location requests.
- the operation of a WLS may be improved by recording the results from wireless location calculations for multiple location technologies for location attempts within a specific cell or sector and then using this historical database to select the optimal technology that best suits the required quality of service for future location requests for that specific cell or sector.
- Figure 1 depicts certain subsystems of a Wireless Location System.
- Figure 2 illustrates the collection of terrestrial radio information from a wireless communications network.
- Figure 3 illustrates the collection of broadcast terrestrial and satellite information from a mobile device, wireless communications network and the GNSS constellation.
- Figure 4 illustrates a method for detecting and locating new beacons, new LMUs and wireless communications network reconfigurations.
- Figure 5 illustrates a method for determining the validity of manually entered geographic information.
- Figure 6 is used to explain a method of static and dynamic cooperator selection and the improvement available when the methods described herein are implemented.
- Figure 7 provides a block diagrammatic view of a WLS in which configuration data and historical location records are maintained in a central, interactive database.
- WPNs Wireless Network Providers
- network operators may install new cell sites, decommission old cell sites, install new antennas, add new sectors, reset timing clocks, re-allocate radio frequencies and adjust channel allocations within the wireless communications system.
- the WLS which may be a hybrid system using known location techniques such as cell-ID, Enhanced Cell-ID, U-TDOA, AoA, control plane A-GPS, and user plane A-GPS, is used within the carrier network either as an overlay or actively integrated into the wireless operator/carrier's network.
- the WLS may require extensive provisioning of network and radio parameters to function correctly. These parameters were originally manually entered items obtained by site and system surveys.
- the OSS system is used by the wireless provider's network (WPN) for maintaining network inventory, provisioning services, configuring network components, and managing faults within the wireless communications network.
- WPN wireless provider's network
- the OSS may not be able to provide all required parameters and manual entry as well as on-site surveys may still be required to provision the WLS.
- the WLS uses receiver and transceiver subsystems already used for other purposes within the WLS to either verify or automatically provision specific network and radio parameters.
- the formerly static configuration files maintained on the SMLC are replaced by a dynamic database in which detected network settings, radio parameters and location records are maintained.
- the same receiver and transceiver subsystems are used to monitor the WCS for changes to the radio and network parameters.
- both configuration data and historical location records are maintained by the WLS in a central, interactive SMLC database.
- the SMLC includes a configuration application (software) and an expert system for location tasking.
- the SMLC processor is configured, via the expert system application, to record LMU use during a location event for mobile stations in a specific cell or sector and then to use only those LMUs that produced useful information in subsequent locations for mobile stations within that specific cell or sector.
- the SMLC processor is further configured to record a historical database of results from location calculations involving multiple location technologies for MSs within a specific cell or sector, and then to use the historical database to select the technology or combination of technologies that best suits a requested quality of service for future location requests for MSs within that specific cell or sector.
- FIG. 1 schematically depicts an exemplary deployment of an overlay WLS comprising an LMU 100; GPS receiver antenna 101; downlink receiver antenna 102; grounding 103 and input protection 104 needed to safely interface the LMU 100 to the exterior mounted antennae 101, 102; SMLC 105 and SMLC database 106; and radio frequency cabling 107.
- the LMU 100 is connected to the SMLC 105 via a wired or wireless connection 108, which carries TCP/IP packet-based communications.
- the SMLC 105 hosts the SMLC Database 106, which contains the network cell identifiers, network antenna identifiers, network antenna locations, LMU (cell) locations, and LMU identifiers.
- FIG. 2 depicts the manner in which terrestrial radio information from a wireless communications network may be collected by the LMU 100.
- broadcast information 200, 201, 202, 203, 204 from cell sites 205, 206, 207 (or access points) is provided to the SMLC 105 via the LMU's 100 downlink receiver subsystem.
- This broadcast information can be obtained from the broadcast or "beacon" transmissions of the cell sites.
- the beacons are received by LMU 100 using the LMU's downlink receiver subsystem.
- Figure 3 shows broadcast signals or beacons 300, 301, 302 generated by the wireless communications network sites 303, 304, 305 available to the LMU 100 via the downlink receiver antenna 102, as well as a satellite constellation 306, 307, 308, 309, generated broadcast signals 310, 311, 312, 313, available to the LMU 100 via the GPS receiver antenna 101.
- Figure 3 also shows the radio signal 315 generated on the reverse control channel or reverse traffic channel (as defined by the radio communications protocol used) by a mobile device 314, in this case a wireless telephone.
- the LMU 100 is connected to the downlink receiver antenna 102 and GPS receiver antenna 101 by radio frequency grade cabling 107 and connected to the wireless communications system antenna 305 by separate radio frequency grade cabling 316.
- the LMU is in turn connected to the SMLC 105 by a wired or wireless packet data connection 108.
- WLS antennae and LMUs may be installed at neighboring antenna sites 303 and non- neighboring antenna sites 304.
- the receiver and transceiver subsystems used by the WLS - including the GPS receiver, backhaul communications and downlink receiver subsystems - and the dynamic SMLC database are described in greater detail below.
- the GPS receiver subsystem shown in Figure 3 relies on transmissions from global satellite constellations (in this example, the United States Air Force NAVSTAR system) to calculate the precise time-of-day and the receiver's location. Further details about this can be found in U.S. Patent No. 6,351,235, "Method and System for Synchronizing Receiver Systems of A Wireless Location System," Feb. 26, 2002, although the reference signals are produced with less than 0.001 degrees RMS of phase noise when integrated from 10 Hz to 15 kHz.
- the GPS receiver On initial activation, the GPS receiver will self-locate. Once the LMU has discovered and initialized communications with the SMLC, an automated configuration application will communicate the GPS produced location to the SMLC. The SMLC will check this discovered location versus any manually input LMU location data for the LMU site. If manually entered LMU location data exists for the LMU site, then the SMLC will compute the distance between the entered and calculated LMU locations. If the manually entered LMU location differs from the GPS calculated position, then an error is indicated. This error condition may provoke the SMLC to automatically replace the manually entered LMU location with the GPS calculated position or cause an error message requesting manual intervention. [0034] The automatic replacement of erroneous LMU location data may be predicated by the site definition. If an LMU site is defined as a tower or monopole site, then the distance between the GPS antenna and the LMU receiver antenna can be assumed to be minimal and reliance on the GPS antenna self-discovered position not impacting to the calculated location.
- GPS timing receivers typically operate in a fixed position mode to provide the highest timing accuracy.
- GPS timing receivers such as those used by the WLS, are capable of self-determining location as well as providing timing.
- the GPS timing receiver can perform an operation called "GPS Self Survey".
- GPS receiver subsystem self- determines an accurate position (latitude, longitude and altitude) using conventional GPS TDOA techniques.
- GPS timing receivers are designed to support holdover timing to continue to provide accurate timing even during times when the GPS constellation is blocked. (For example, most GPS-based timing devices include a holdover oscillator that operates in parallel to the GPS system.
- holdover oscillators may not be as accurate as the atomic clocks on the GPS satellites and thus may require periodic "tuning" so that the frequency of the holdover oscillator matches the frequency of the atomic clocks in the GPS satellites.)
- the self-survey operation takes advantage of the holdover capability to provide a background GPS Self Survey - i.e., the GPS receiver subsystem is able to deliver an accurate time signal to the LMU during the holdover period while the GPS receiver self-determines position for verification of entered location data.
- the timing receiver can be placed in a commanded holdover mode for a limited period of time to perform a short self survey.
- Multiple short self surveys can be performed and averaged together to improve the accuracy of the known position.
- the distribution of each short self survey is such as to maximize the overall view of the constellation in the total averaged self survey result.
- the standard deviation of the self survey data provides a confidence factor of the accuracy of the surveyed position.
- An example would be to place the GPS receiver into holdover for 15-minute time periods multiple times over one or more days and calculate an average and standard deviation of these survey results to provide a location and confidence factor on that location while continuing to provide accurate location throughout.
- the calculated position can be delivered to the SMLC for verification or replacement of the entered data.
- the LMU supports a backhaul communications subsystem for rapid interconnection to existing base stations without the need for signal or protocol conversion.
- the LMU uses TCP/IP over the provided transport for communications with the SMLC.
- the LMU can discover its backhaul and establish communications with the SMLC automatically.
- Techniques can be used to minimize the manual configuration required to physically connect (backhaul) an LMU to a WLS.
- An exemplary technique is useful both for new installations as well as "backhaul re-home" scenarios.
- this technique can be used to minimize configuration synchronization problems, wherein an LMU is physically moved before an updated configuration has been completed, or visa versa.
- This technique can be applied regardless of the physical backhaul connecting a WLS to an LMU, be it Tl /El, IP, ATM, Ethernet, or any other conventional or non- conventional physical interconnect.
- a newly connected, reconnected, reset (or other form of interrupted service) LMU will probe for a WLS by sending a short identification beacon repeatedly across all physical connections.
- the identification beacon effectively identifies that an LMU is seeking to connect itself to a WLS.
- the WLS can be pre-configured with a list of LMUs, the identities of the listed LMUs, as well as a surveyed geographic location of each LMU.
- the "Wireless Location System - LMU Access Point" (WLS-LAP) will initiate a protocol negotiation over the physical interface that carried the identification beacon.
- a minimum (factory installed) protocol version will be selected, allowing an unconfigured LMU to still negotiate with the WLS-LAP.
- a higher protocol version can be re-negotiated as supported by the LMU and the WLS-LAP.
- the LMU Upon completing negotiation, the LMU will provide its auto-discovered geographic position (Lat, Lon) to the WLS-LAP.
- the LMU can auto-discover its geographic position through use of, but not limited to, an onboard GPS receiver, as described above.
- the WLS-LAP will interrogate the configured list of LMUs and select the entry having a geographic position nearest the position reported by the "beaconing" LMU.
- the WLS-LAP will then provide the LMU with the LMU' s configured identity, so that the LMU can identify itself to the rest of the WLS.
- the LMU will continue to probe across its remaining physical connections until a WLS-LAP is found which will claim "ownership" for the "beaconing" LMU. It will also, periodically revisit any physical connections for which a WLS-LAP had previously been discovered.
- a variation of the technique described above can be accomplished by having the WLS-LAP perform the "identification beacon".
- an LMU upon receiving an "identification beacon" on one or more of its physical interfaces, will initiate protocol negotiation. This variation of the technique will then proceed as described above.
- the downlink receive antenna subsystem allows the LMU to detect and demodulate the beacon broadcasts from surrounding cells and sectors.
- the downlink receive antenna subsystem was used to receive and demodulate the beacon of the resident cell and sectors.
- the beacons of non-resident cells and sectors in proximity to the LMU may be used to determine the CGI, BSIC, and frame timing offsets.
- the downlink receive antenna subsystem will be used not only to receive and demodulate the beacons of neighboring and geographically proximate cells and sectors, but also for TDOA location (i.e, downlink-TDOA) of each CGI detected by the LMU.
- TDOA location i.e, downlink-TDOA
- all detectable beacons are identified via CGI and the list of CGIs are uploaded to the SMLC.
- the WLS performs D-TDOA location calculations. These are optimally performed during WLS system idle time, although immediate or periodic scheduling is possible.
- the produced table of CGI values and CGI locations can be used either to provision the SMLC or verify the accuracy of manually entered antenna site setting and location information.
- the produced table of CGI values and CGI locations can also be verified against GPS antenna locations provided by the GPS receiver subsystem's self-survey.
- Periodic or ad hoc scanning of the detectable CGI's by the downlink receiver subsystem can be used to detect changes in the wireless communication system's configuration or additions of new beacons from the build-out of additional base stations or sectorization of an existing base station. Such canning can be configured to automatically occur during periods of low WLS/TLP usage.
- the information on/in the beacon is shown in Tables 3 and 4 for GSM and UMTS, respectively.
- the GSM system uses the broadcast control channel (BCCH), a downlink (BTS to MS) channel, to convey the beacon function on a per CGI basis.
- the UMTS network uses the Broadcast Channel, a downlink UMTS transport channel that is used to broadcast cell and system information on a per C/ basis.
- the beacon discovery process will either occur periodically after installation or at the operator's discretion.
- the beacon discovery results are then checked at the SMLC against the stored historical information generated from site and system surveys. If a beacon is lost (originating cell is decommissioned) or a new beacon occurs (new cell site erected), the automated configuration process will be used with no or minimal operator intervention to reconfigure the WLS.
- WPN wireless provider's network
- the technique described herein allows for a significant reduction in the amount of manual configuration and frequent synchronization of that data, which was previously required to keep a WLS "healthy".
- location techniques such as, but not limited to, U-TDOA need a precise mapping of cell identifiers (e.g. CGI in GSM networks) to cell tower (e.g. BTS in GSM networks) positions in order to be able to estimate the position of a wireless device which is accessing the WPN.
- the technique leverages the capabilities of the WLS to eliminate the error prone and manual configuration of cell identifiers (CID) to physical cell positions (PCP) or wireless access points (WAP).
- CID cell identifiers
- PCP physical cell positions
- WAP wireless access points
- this signaling typically referred to as a beacon, is delivered via a broadcast control channel (BCCH).
- BCCH broadcast control channel
- CGI cell identifier
- the WLS can be tasked to locate the source of the beacon and compare the location result to an internal configuration of cell tower positions. Once a match is found, a table can be dynamically constructed which maps CGIs to cell tower positions. It should be noted, however, that these techniques are not restricted to GSM networks.
- Newly Commissioned Base Station/ Access Point Site New WAP sites will be discovered once they begin broadcasting their "beacon" and a downlink receiver scan is performed. Once the new beacon is discovered, a TDOA location is generated using LMUs in geographic proximity to the newly discovered beacon. Once a location is obtained, it and the network parameters and radio information obtained from the beacon are uploaded to the SMLC hosted database.
- Decommissioned Site CID-to-WAP entries in the dynamically generated table can be removed when the signaling can no longer be detected, after a suitable waiting period. Operator notification and intervention will normally be required to differentiate a permanently decommissioned and a temporarily out-of-service site. In either case, the WLS can reconfigure its own database to avoid the missing site.
- CID Re-home Collisions within the detected to databased CID-to-WAP mapping can be indicative of CID re-homing.
- Re-homing refers to a remapping of a CID to the physical network and is indicative that a reconfiguration has been initiated by the wireless network operator.
- map entries can be updated to reflect the CID re-homes.
- periodic re- location of "beacons” will detect re-home scenarios that also involve decommissioning of a previous site.
- a re-home is especially destructive to the operations of the WLS since serving cell information (the CID) obtained from the network in the location request or via an autonomous trigger no longer matches the databased information. This mismatch can cause the WLS to incorrectly task the LMUs and can result in a low quality or no location.
- OAM operations and maintenance
- the SMLC also stores, or is coupled to, a database of location records (e.g., the SMLC database 106).
- This database can be used to predict the quality-of-service for a location application based on the mobile device or network supplied cell-ID and proximity information (such as CGI+TA in GSM or CI+RTT in UMTS) prior to signal collection and/or location calculation.
- This same database can be used as described herein to hold the radio and network parameters generated by manual entry, downloading from the OSS, or developed from the GPS and/or downlink receiver subsystems.
- a location quality-of-service indicator can be generated from historical location data.
- QoSI location quality-of-service indicator
- an evaluation of the required quality of service can be used with the historical data for the current cell or sector and used to select the optimal location technology from the available set.
- the optimal technology depends on the predicted location accuracy, availability, latency, precision, and/or yield that meets the required quality of service.
- U-TDOA e.g., performs better in certain environments than does AGPS, and visa versa. This is particularly true for a WLS that spans a large geographical area; although, geography is not the only component to consider, in fact, the time of day, location system health, and other factors can significantly contribute to the quality of service. In the most challenging of environments, it may not be possible, a priori, to determine what the best positioning method, for a given location, will be at any given time of day. This is even further complicated when other factors, such as weather and satellite visibility, must be considered.
- An alternative approach is to use historical data about the quality of performance of all location methods in a geographic area.
- the historical data could also include, but should not be limited to, information about the time of day, weather conditions, satellite visibility, serving cell information, availability of coops, and other temporal and spatial parameters that were present at the time the location was performed.
- the WLS when newly deployed, the WLS would attempt multiple positioning methods at every location attempt, to both provide the best quality of service and to build up a database of location method performance.
- this collection of data is serving as training data for the system.
- the WLS can select the historically most reliable positioning method based upon the parameters (such as, but not limited to, the approximate location and time of day) available at the time of the location request.
- an expert system can be applied to the available training data. This approach allows the system to conserve resources, and as such to provide the best quality of service not only for a single location attempt but for the WLS as a whole.
- This technique could also be extended to select the optimal "positioning parameter set" for a given location method.
- two factors that impact the quality of U-TDOA locations are the number of cooperators used (observation points) and the length of time the data is integrated.
- a historical database training data
- this training data can be applied to an expert system so that the "best" positioning parameter set, for the best positioning method, which balances the consumption of system resources, can be employed.
- This supplementary technique can be applied to all positioning methods, and hybrid positioning methods.
- Another example where this supplementary technique can be applied is when a WLS is employing the use of CML (combining multiple locations) of a single positioning method. For example, multiple, time sequenced, U-TDOA locations are performed for a single location request. This is typically done to account for multi-path, fading, and other environmental effects that could result in an N 4 * 1 location attempt having better results than the 1 st attempt.
- the historical data can predict how many locations, per location attempt, will result in the best performance while still conserving system resources, by applying the data to an expert system that will take parameters such as, but not limited to, approximate location and time of day into account.
- This SMLC hosted Location Server function can also be used by the WLS to select the correct location technique based on the historical data and the quality-of-service demanded for a specific location request. While some configuration data will be entered via the WLS' s operations maintenance administration and provisioning (OAMP) component (the SCOUTTM tool), other information, such as cell site location, antenna locations, antenna downtilt, frequency bands, and radio channel configurations, may be obtained via the radio network operator's Operations Support System (OSS). Configuration data may be exported from the OSS, processed, and then imported into the SCOUTTM tool. All configuration data collected and processed is uploaded to the SMLC for use or for transmission to the SMLC's supported LMU population. Propagation models of the wireless communications network and geometric dilution of precision information for cooperating LMUs may be calculated by the SCOUTTM tool and uploaded to the SMLC for use or for transmission to the SMLC's supported LMU population. Discovering New Beacons
- FIG 4 is a flowchart of a procedure employed by the WLS for discovering new beacons, which may be due to changes made by a wireless network provider to the wireless communications network (WCN).
- the procedure assumes either a scheduled, periodic or a manual ad hoc initiated scan of the WCN downlink broadcasts using the downlink receiver subsystem, including the downlink receiver, cabling and LMU software.
- the downlink receiver subsystem scans a prescribed range of frequencies to detect beacon signals. Once a beacon is found, it is demodulated to obtain broadcast site and antenna identifiers.
- the frequency, channel, and discovered network information is delivered to the SMLC.
- the SMLC examines the newly generated beacon information versus its databased information.
- Newly discovered beacons or mismatches between detected beacons' historical information generate a request from the SMLC to the LMUs in the proximity to the detecting LMU to perform a downlink TDOA signal collection on the beacon signal.
- the SMLC can be configured either to alert the WLS operator or replace the mis-match location-to-beacon information in the SMLC database.
- this procedure can be used to populate the beacon table for the new LMU or new SMLC.
- FIG. 5 is a flowchart of a procedure for GPS self-survey and update.
- a properly deployed GPS antenna will be able to detect and demodulate broadcasts from four or more satellites allowing the GPS receiver to supply the LMU with both a stable time reference and location of the GPS receiver.
- each LMU generates its own GPS location (location of the GPS antenna), which is uploaded to the SMLC on a scheduled, periodic, or ad hoc basis.
- the SMLC compares the GPS-generated location of each LMU versus its databased, manually- entered data on the LMU location.
- the SMLC alarms If the GPS location versus the manually-entered location differ above a threshold (this threshold differs on a per market and BTS/BS/AP coverage size (macro, micro, pico)) value, then the SMLC alarms.
- the operator upon receiving the alarm, can manually enter a new LMU uplink receiver antenna location and permanently override the alarm for that LMU or may elect to use the calculated GPS position for the LMU uplink receiver antenna location. Whatever the operator decision, the new value will be entered into the SMLC database and then used in future U- TDOA and/or AoA location calculations.
- Figure 6a depicts the first stage of a two-stage co-operator selection method.
- a location request to the WLS results in a population of LMUs 601 in geographic proximity to the LMU-equipped serving cell 600 being tasked to collect signal quality information.
- LMUs not within the programmed range or static neighbor set 602 are not polled.
- the collected signal quality information from the polled LMUs 601 is used in the dynamic co-operator selection stage shown in Figure 6b, were a subset 603 of the original polled population of LMUs 601 are selected to provide timing information to the SMLC for location generation based on the collected signal quality data. Further information about such a method can be found in U.S. Patent Nos. 6,483,460, Nov. 19, 2002, "Baseline Selection Method for Use in a Wireless Location System”; and 6,400,320Bl 5 June 4, 2006, "Antenna Selection Method for Use in a Wireless Location System”.
- Figure 6c depicts an improved 2-stage co-operator selection routine.
- the addition of a historical database for network and LMU information may also be used to store historical location quality and co-operator information.
- the initial stage 1 selection of LMU population is no longer static, but rather a subset of LMUs 604 is selected for the stage 1 signal quality collection based on the historical signal quality, location quality and the geometry (in an effort to reduce the geometric dilution of precision inherent in TDOA and AoA location) of the receiving LMUs.
- the new stage 1 LMU population can be much reduced or significantly different in geography and topology from the static set of polled LMUs used in the example of Figs. 6a-b.
- FIG. 7 provides a block diagrammatic view of a WLS in which configuration data and historical location records are maintained in a central, interactive database.
- the WLS comprises a network of LMUs 10OA, 100B 3 IOOC ... 10ON; an SMLC 105 operatively coupled to the network of LMUs, the SMLC including a programmable processor (not shown); and an SMLC database 106 containing location records and configuration data concerning a plurality of BTSs of a wireless communications system.
- the SMLC 105 may include a configuration application (software) 105A and an expert system for location tasking 105B.
- the SMLC processor is configured, via the expert system application 105B, to record LMU use during a location event for mobile stations in a specific cell or sector and then to use only those LMUs that produced useful information in subsequent locations for mobile stations within that specific cell or sector.
- the SMLC processor is further configured to record a historical database of results from location calculations involving multiple location technologies for MSs within a specific cell or sector, and then to use the historical database to select the technology or combination of technologies that best suits a requested quality of service for future location requests for MSs within that specific cell or sector.
- the location records contained in the SMLC database may include information concerning the following facts relating to previous location events: serving cell, cooperators used, technology used, calculated uncertainty, time of day, weather, satellite visibility, serving cell, and availability of cooperators.
- the configuration data contained in the SMLC database may include information concerning the following facts relating to the WLS configuration: cell site identifiers, broadcast channels, radio frequencies, antenna identifiers, antenna locations, site location, and LMU identifiers.
- the present invention is not limited to the presently preferred embodiments disclosed herein.
- the foregoing disclosure of a presently preferred embodiment of a Wireless Location System uses explanatory terms, such as Location Measurement Unit (LMU), Serving Mobile Location Center (SMLC), and the like, which should not be construed so as to limit the scope of protection of the following claims, or to otherwise imply that the inventive aspects of the Wireless Location System are limited to the particular methods and apparatus disclosed.
- LMU Location Measurement Unit
- SMLC Serving Mobile Location Center
- many of the inventive aspects disclosed herein may be applied in location systems that are not based on TDOA techniques.
- the invention is not limited to systems employing LMUs constructed and deployed as described above. The LMUs and SMLC, etc.
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- Engineering & Computer Science (AREA)
- General Physics & Mathematics (AREA)
- Radar, Positioning & Navigation (AREA)
- Remote Sensing (AREA)
- Position Fixing By Use Of Radio Waves (AREA)
- Mobile Radio Communication Systems (AREA)
- Radio Relay Systems (AREA)
Abstract
Description
Claims
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US20090143018A1 (en) | 2009-06-04 |
KR101495388B1 (en) | 2015-02-24 |
JP2011508472A (en) | 2011-03-10 |
GB2468258A (en) | 2010-09-01 |
EP2220887A4 (en) | 2011-04-20 |
CA2700429A1 (en) | 2009-06-04 |
CN101822085B (en) | 2013-11-06 |
JP5467048B2 (en) | 2014-04-09 |
AU2008329888A1 (en) | 2009-06-04 |
BRPI0819270A2 (en) | 2015-05-19 |
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