KR101162997B1 - Identification of a mobile station at a serving mobile location center - Google Patents

Abstract

A method and apparatus are described that can transmit the identity of a mobile station 110 to a stand-alone Serving Mobile Location Center (SMLC). In a preferred embodiment, a unique mobile station identifier, such as an International Mobile Subscriber Identity (IMSI) or the like, is contained within an extension container that is an ancillary information element defined by the Radio Resource LCS Protocol (RRLP). Mobile station 110 configured to encode the MS ID .. The extension container is included as a factor in an LCS message such as a Measure Position Response message or a protocol error message. It is configured to decode the extension container, retrieve the MS ID, and store the MS ID associated with the unique positioning session identifier.

Preferably, the mobile station 110 may have a structure having a test mode parameter. As an example, the encoding of the MS ID in the extension container is activated in the test mobile station 110 only when the test mode parameter is set to on.

Description

IDENTIFICATION OF A MOBILE STATION AT A SERVING MOBILE LOCATION CENTER}

The present invention relates to location services for mobile devices, and more particularly, to a method and apparatus for communicating the identity of a mobile station to a stand-alone Serving Mobile Location Center (SMLC).

Location services for mobile telephones and wireless digital communication devices (hereinafter referred to collectively as mobile stations or MSs) are an increasingly important business field for wireless communication providers. Location service information may be used to provide various location services to mobile station users. For example, a public safety agency may use mobile station location information to pinpoint the geographical location of a wireless device. Optionally, the mobile station user can use the location information to locate the nearest automatic teller machine (ATM) and use the funds through the ATM. As another example, location information may help the traveler step by step in the direction of the desired destination during the journey.

Technologies that enable a large number of system users to share wireless communication systems, such as Global System for Mobile Communications (GSM) technology, continue to increase the demands of mobile computing, including the need for location services. Plays an important role in meeting As is known, GSM utilizes a combination of time division multiple access (TDMA) and frequency division multiple access (FDMA) techniques to allow multiple users to communicate simultaneously. GSM systems also frequently use General Packet Radio Service (GPRS) technology to transmit data and provide location services.

Standards and functional specifications have been established for determining the position of a mobile station in a wireless communication system (when applying the geographic coordinates of the mobile station, position and location are used herein as the same term). The ^{"3 rd Generation Partnership Project, Technical Specification} Group, Services and System Aspects, Location Services (LCS), (Functional description) -Stage 2 (Release 1999) published a preferred References September 2002 relating to GSM and LCS, (3GPP TS 03.71 V8.7.0). This reference is hereinafter referred to as 3GPP TS 03.71 V8.7.0.

Two examples of the first reference book on GSM and LCS is the ^{"3 rd Generation Partnership Project, Technical Specification} Group GSM / EDGE Radio Access Network, Location Services (LCS), Mobile Station (MS) , published in July 2002 -Serving Mobile Location Center (SMLC) Radio Resource CS Protocol (RRLP) (Release 1999), ”(3GPP TS 04.31 V8.10.0). This reference is hereinafter referred to as 3GPP TS 04.31 V8.10.0.

For the first three references relating to GSM and LCS is "3, published in July ^{2000 rd Generation Partnership Project, Technical Specification} Group Core Network, Mobile Application Part (MAP) specification (3GPP TS 29.002 version 3.h.0 Release 99), ”. This reference is hereinafter referred to as 3GPP TS 29.009 V3.h.0.

Wireless communications networks, such as the Public Land Mobile Communication Network (PLMN) in GSM, can provide assistance data to mobile stations to enable location measurement and improve measurement performance. One example of an MS-assisted positioning method is to use a Global Positioning System (GPS), hereinafter referred to as assisted GPS or AGPS. According to AGPS technology, the mobile station obtains measurements from GPS satellites using auxiliary data provided by the network. Measurements related to a given location request in a GSM system are sent to a Serving Mobile Location Center (hereinafter SMLC). The SMLC manages the overall coordination and scheduling of resources required for performing the positioning of the mobile station.

Development and validation of LCSs in wireless communication systems require extensive operational testing. One problem that arises when testing an LCS in a standalone SMLC, a GSM system with an SMLC that is not integrated into a Base Station Center (BSC), is that the identity of the test mobile station does not conform to the GSM standard for LCS positioning sessions. It is not delivered to the SMLC. The identity of the mobile station is determined by using a unique mobile station identifier (hereinafter referred to as MS ID), such as an International Mobile Subscriber Identity (MSI) number. The MS ID is typically used for a Subscriber Identity Module (SIM) or other equivalent component within a mobile station. However, during the positioning session, the BSC sends only one logical reference data to the SMLC to distinguish it from other positioning sessions. Although this is an efficient method for normal operation, testing is very difficult because the information recovery procedure must be performed to associate a session specific to a particular mobile station.

Possible ways of dealing with the above-mentioned problem of mobile station identity testing include incorporating an SMLC into the BSC or modifying the BSC such that mobile station identity information is passed to the SMLC in a nonstandard way. However, the methods described above are undesirable because they are cumbersome and difficult to change the BSC as described above.

Accordingly, there is a need for an effective method and apparatus for transmitting the identity of a mobile station to a standalone SMLC during an LCS positioning session to facilitate operational testing.

Apparatus and methods for providing the geographic location of a wireless mobile station, in particular methods and apparatus for transmitting the identity of a mobile station to a standalone Serving Mobile Location Center (SMLC), are in one example a Radio Resource Location Service Protocol (RRLP). Mobile station configured to encode a unique mobile station identifier (MS ID), such as an International Mobile Subscriber Identity (IMSI) number, etc., in an extension container, which is an optional information element defined by (LCS) Protocol). . The extension container is included as a component in a location service message such as a Measure Position Response message or a Protocol Error message. The SMLC is configured to decode an extension container, retrieve an MS ID, and store an MS ID associated with a unique positioning session identifier.

Preferably, the mobile station is configured according to a test mode parameter. The test mode parameter is set to a test mode on (short on) and a test mode off (short on off), and the default value is "off". At the mobile station, the structure of the test mode parameter can be controlled via dedicated commands using the phone and serial link or through the user interface of the mobile station. In one embodiment, the encoding of the MS ID in the extension container is activated in the test mobile station only when the test mode parameter is set to on.

1 is a functional block diagram of a preferred wireless communication system used for providing wireless communication including location services.

2 is a functional block diagram of another preferred wireless communication system used for providing wireless communication including location services, showing additional system elements.

3 is a functional block diagram illustrating the flow of messages between a mobile station in a test mode and a Serving Mobile Location Center (SMLC).

4 is a flow chart illustrating the process of the preferred method.

1 illustrates a simplified generic wireless communication system 100 suitable for testing location services. As shown in FIG. 1, the mobile station 100 communicates with one or more Base Transceiver Stations (BTSs) 122, 124 via wireless links 152, 154. Each BTS provides a coverage area (or service) for a geographic area, commonly referred to as a cell. For example, although two BTSs are described, because they depend on the positioning structure used, location services will be provided to the mobile station 110 using only one BTS or using three or more BTSs. As described in the integrated 3GPP TS 03.71 V8.7.0 document, the positioning mechanism includes uplink Uplink Time of Arrival (TOA), Enhanced Observed Time Difference (E-OTD) and AGPS. Both the TOA and the E-OTD require signal exchange between the mobile station 110 and the plurality of BTSs.

As described so far, the mobile station 110 includes, without limitation, a wireless telephone, a PDA with wireless communication capability, a laptop with wireless communication capability, and other mobile digital devices for personal communication via a wireless connection.

BTSs 122 and 124 are coupled to operate for data communication with a base station controller (BSC) 126. The BTSs 122 and 124 and the BSC 126 are components of a base station system (BSS) 120. As shown in FIG. 1, the BSC 126 is connected to the SMLC 130. The SMLC controls the location service by managing the resources required to perform the positioning of the mobile station. As an alternative architecture, the SMLC may be coupled to operate via other components (not shown) in the wireless communication system.

The mobile station 110 receives signals, such as GPS signals, from the one or more satellites 172, 174 via the communication links 156, 158. For example, although two satellites have been described, only one satellite, or more typically, multiple satellites are used when providing location services to mobile stations in a wireless communication system. Satellite data may also be received by another receiver (not shown) in the communication service provider network 140. Those skilled in the art will appreciate that a GPS location system for a wireless system generally includes components such as a static GPS receiver and / or a wide area reference network that receives satellite signals and provides reference data to the SMLC. The BSC 126 is connected to the communication service provider network 140 to transmit and receive data such as audio / video / text communication and programming data, location requests, and the like. An example of a telecommunications service provider network is a Public Land Mobile Communication System Network (PLMN) operating under GSM.

2 is shown in functional block form and illustrates another communication system 200 capable of providing location services. For simplicity, only one GPS satellite 272 and its associated broadcast signal link 252 are shown.

As shown in Fig. 2, the mobile station 210 includes a CPU 212; Memory 214; User interface 213; Subscriber Identity Module (SIM) 215; And a transceiver 216. The term CPU, alone or in combination with other devices such as memory, includes any processor device capable of controlling a device containing a CPU such as SMLC 230, mobile station 210, or a portion thereof. do. For example, a CPU includes a microprocessor, an embedded controller, an application specific integrated circuit (ASIC), a digital signal processor (DSP), a state machine, dedicated discrete hardware, and the like. The systems, apparatus, and methods described below are not limited to the particular hardware components described, nor are any particular hardware components selected to implement the CPU 212.

The transceiver 216 is capable of transmitting and receiving data, such as audio / video / text communication and programming data, between the mobile station 210 and a remote location such as a BTS 224, 226 or a GPS satellite-satellite 272. Let's do it. Antenna 218 is electrically connected to the transceiver 216. The basic operation of mobile station 210 for voice and data transmission is well known in the art and will not be described in detail below.

As shown in FIG. 2, the system 200 includes an SMLC 230 with a memory 234 and a CPU 232. The CPU 232 controls the operation of the SMLC 230 according to the programmed instructions and the data stored in the memory 234. The memories 214 and 234 may include read only memory (ROM) devices, random access memory (RAM) devices, and nonvolatile RAM devices. The memory 234 stores and supplies instructions and data for the CPU 232. The memory 214 stores and supplies instructions and data for the CPU 212. The components of the SMLC are connected to each other by an internal bus system 236. The components of the mobile station 210 are connected to each other by an internal bus system 219.

The SIM 215, which will be described in more detail later, may be a unique MS such as an International Mobile Subscriber Identity (IMSI), a Mobile Subscriber Integrated Service Directory Number (MSISDN), or another MS ID. Contains an ID. The IMSI and MSISDN are identifiers unique to the mobile station, and either may be used. The MS ID is retrieved by the CPU 212, encoded according to the programmed instructions and data stored in the memory 214, incorporated into an RRLP Measure Position Response message or protocol error message, and FIG. It is sent to the SMLC 230 via the communication link and system components shown in FIG.

The user interface 213 may be used to control the setting of test mode parameters, described below. In a preferred embodiment, the user interface comprises a GUI and an input device such as a touch screen, a pointing device or a keypad. In another embodiment, the test mode parameter may be controlled using a dedicated command received via a connection (eg, a serial connection, not shown) with a local device (not shown), such as a laptop computer or PDA, Here the local device is connected to operate with the CPU 219.

As shown in FIG. 2, communication system 200 includes BSS 220, and BSS 200 includes a number of BTSs, such as BSC 222, BTS 224, 225, and the like. The BTS enables the transmission and reception of data (audio / video / text and programming data) between the BSC 222 and remote locations such as mobile station 210 or GPS satellites-satellite 272. Antennas 228 and 229 are each electrically connected to BTSs 224 and 226 through known methods, respectively. Mobile station 210 communicates with the BTS via a wireless link—wireless link 272. An additional radio link (not shown) is used to transmit signals between the mobile station 210 and the BTS 224 or another BTS (not shown). The basic operation of the BSC 222 and the BTSs 224 and 226 is well known in the art and will not be described in detail below. The BSC 222 is connected to the communication service provider network 240. The BSC 222 transmits and receives data such as audio / video / text communication and programming data, location requests, or location data from the service provider network 240.

In addition, the BSS 220 is connected to the SMLC 230 to transmit and receive data related to the location service (LCS). Examples of the above-described data are described in detail below.

RRLP LCS message exchanged between mobile station and SMLC

3 illustrates the flow of RRLP messages that may be exchanged between the test mobile station 310 and the SMLC 330 during the location request procedure. This procedure is described in more detail in reference 3GPP TS 04.31 V8.10.0.

RRLP assistance data message 342, RRLP protocol error message 346, and RRLP assistance data confirmation message 348 are RRLP downlink pseudo-segmentation (RRLP downlink) according to known techniques as described in 3GPP TS 04.31 V8.10.0. When pseudo-segmentation is used, it causes the SMLC to transmit assistance data to the mobile station in connection with the position measurement and / or mobile station position calculation. If pseudo-segmentation is not used, the location request procedure omits the messages 342, 346, and 348. In addition, the RRLP assistance data message 342, the RRLP protocol error message 346, and the RRLP assistance data confirmation message 348 may cause the SMLC to transmit assistance data requested by the mobile station. In this case, the messages 352, 354, 356 are omitted.

Using RRLP assistance data message 342, or RRLP measurement location request message 352, the SMLC sends an assistance data component to the mobile station. This component contains auxiliary data for positioning and / or positioning.

The mobile station uses the RRLP protocol error message 346 to send an RRLP message containing the protocol error component to the SLMC. This message is sent only when the mobile station has a difficulty in receiving a complete and understandable auxiliary data component (the situation in which the message may occur is indicated by a dashed line in FIG. 3). The protocol error message 346 includes additional information elements referred to as extension containers. As described in more detail below, the extension container of protocol error message 346 will be suitable for transmitting the MS ID (eg, IMSI or MSISDN) of the mobile station to SMLC. This message is sent when there is a protocol error. As a result, as described below, the next message may be used for mobile station identity transmission.

When the mobile receives the complete assistance data component, it sends an RRLP assistance data acknowledgment message 348 to the SMLC.

The SMLC uses the RRLP measurement location request message 352 to send the measurement location request component to the mobile station. These components include Quality of Service (hereinafter referred to as QoS), other commands, and possibly auxiliary data.

The mobile station uses the RRLP protocol error message 354 to send an RRLP message containing the protocol error component to the SMLC. This message is sent only when the test mobile station has a difficulty in receiving a complete and understandable measurement location request component. The protocol error message 354 also includes an additional extension container suitable for transmitting the MS ID (eg, IMSI or MSISDN) of the mobile station to the SMLC. However, these messages are sent only when an error occurs. As a result, the next message described below will be used to convey the mobile station identity.

The mobile station attempts to report the requested position measurement using the RRLP measurement position response message 356. Examples of position measurements may include position prediction, AGPS measurements, or measurement error. When the mobile station includes a position measurement, a position prediction, or an error indication (measurement / position prediction not possible), the mobile station sends the result value to the SMLC in the measurement position response component.

In addition, the RRLP measurement location response message 356 includes an additional extension container that may be suitable for sending the MS ID (eg, IMSI or MSISDN) of the MS to the SMLC. If the positioning process is not terminated in advance due to an error, an extension container of this message may be executed to send the MS ID to the SMLC. If the procedure ends before this message, one of the protocol error messages 346 and 354 may be used instead.

Extended Container Details

The RRLP extension container is derived from the Mobile Application Part (MAP) extension data type (described in detail in the incorporated 3GPP TS 29.002 V3.h.0 citations). As a result, the specification of the extension container follows the description rule of Mobile Application Part (MAP) Abstract Syntax Notation One (ASN.1). For actual encoding / decoding, packed encoding rules (hereinafter referred to as PER) are applied (e.g., bitmaps for additional parameters, extension indicators when omission is used, etc.). As described below, the MAP compliant encoding includes object identifiers already registered or not yet registered.

One example of ASN-1 encoding of an extension container is given in the pseudo-code below.

According to one embodiment, the mobile station identity will be encoded into an extType variable. Incidental PCS-Extensions are not included in this embodiment. The OI should not be confused with the IMSI or other MS ID to be used to identify the test mobile station. The content of the OI, or OI value, lags behind the length indicator giving the octal number of the OI value.

As explained in the integrated citation, the ASN-1 OI clarifies the identification of entities registered in the worldwide tree. The nature of OIs is known to those skilled in the wireless communication art and therefore is not described here in detail. OI is registered through the appropriate organization or registrar. Examples of existing OI registrations that are similar to OI registrations that would be suitable for embodiments include ASN-1 BASIC-PER, UNALIGNED variant: (joint-iso-itu-t asnl (1) packed-encoding (3) basic (0) unaligned ( 1)} Assigned for "Packed encoding of a single ASN.1 type (basic unaligned)". The appropriate OI may be represented in well-known PER hexadecimal form and may be used for the "extId" entry of the ASN-1 encoding as an example of the extension container shown above. In this example, the OI is represented by a decimal number "1, 3, 0, 1", where the decimal number is a PER hexadecimal sequence "00x03, 0x2b, 00, 01", where 0x03 is a variable length of 3 octets. 0x2b represents a value 43 = 40 * 1 + 3).

In one embodiment, the "extType" variable is a component that contains private extension data that can be used to send an IMSI or other MS ID to the test mobile station. The variable is ASN-1 open, having a length determining element prior to the field list. In the present example, the length of the private extension may be chosen not to exceed 128 octets. Accordingly, the length determining factor is encoded within one octet or eight bits. In one embodiment, the field list for the "extType" variable has the following form.

In the example above, the following applies: The ellipses "..." indicate that the extension can be added. In exceptional cases, if the test mobile station cannot provide the mobile station's IMSI, the IMSI field will be filled with zeros. "TestExtension Revision" is an integer variable with a value between 0 and 63, and can be expressed in 6-bit hexadecimal. The IMSI variable is an octet string with a fixed size of eight octets.

Table 1 shows an example of extended container encoding as described above.

field value Field length Explanation Start ExtensionContainer   Extension indicator preamble 0 1 bit Extensible components, but no extension   Optional Parameter bitmap 10 2 bit "PrivateExtensionList" exists, "pcsExtensions" does not exist   Number of private extensions 1 to 10 4 bit Range of encoded values: (10-1) and 9 is 100b (4-bit binary encoding) Start PrivateExtension (# 1) First (and last) private extension   Optional Parameter bitmap One 1 bit indicates whether the optional "extType" parameter exists (a value of 1 indicates that it exists) Start extID OI containing length field and value field Object Identifier Length 8 bit The length is encoded in one octet.
For this example, the number of octets in the OI value is 3, and the result length is encoded by PER hexadecimal 00x03.   Object Identifier Value In this example, the OI value and (1,3,0,1) are encoded by the PER hexadecimal sequence 0x2b 00 01 (0x2b is 43 = 40 * 1 + 3). Start extType   Length determinant 0b7b6 ... b1 8 bit In this embodiment, the binary encoding of the length determination is 0000 0010b (binary value). Start value of extType This is an open bit field.   Extension marker 0 1 bit No expansion yet.   Testextvision 0 6 bit Check the revision number of the test extension. The initial value is 0. This way, new parameters do not have to be added as an extension (using an extension preamble). The addition of new parameters may depend on the test extension revision.   IMSI value 8 octets 15 BCD Number-If the IMSI is less than 15 numbers, the additional number is encoded as 1111b (binary).   Padding 0 One If not added, the total length of the private extension bit field is 15 bits. Thus, one bit addition is required to reach the 2-octet boundary.

SMLC Test mobile station identification and Operation example

In a preferred embodiment, the test mobile station, in the expansion container of the measurement location response message 356 or in the expansion container of the protocol error message 346, 354 (FIG. 3), has an MS ID (e.g., IMSI or MSISDN) associated with the test mobile station. Is designed to encode. As mentioned above, a measurement position response message is sent to the SMLC to signal a positioning, AGPS measurement, or measurement value error. A protocol error message is sent by the test mobile station to the SMLC to signal a protocol error. The SMLC is designed to decode the extension container, retrieve an MS ID, and store an MS ID associated with a unique positioning session identifier belonging to multiple location session identifiers maintained by the SMLC.

When trying to decode the private extension, the SMLC first tries to decode the OI. If the received OI is not recognized, the SMLC attempts to omit the OI to omit all private extension containers or to decode the length of the open variable. If the extension container prevents proper decoding of the RRLP, the SMLC will send an RRLP protocol error message to the mobile station and may terminate the positioning session with the BSC.

Each time the SMLC detects that the length determination of the OI or the "extType" length determination is encoded with a value indicating that the length is greater than 16K, the SMLC sends a protocol error message to the mobile station. The SMLC terminates the positioning session with the BSC.

Preferably, the mobile station will be designed with test mode parameters. The test mode parameter may be set to "test mode on" (abbreviated "on") and "test mode off" (abbreviated "off"), the default value being "off". At the mobile station, the structure is performed using a serial link to the phone or via dedicated instructions via the mobile station user interface (UI). The encoding of the MS ID in the message extension container is activated in the test mobile station only when the test mode parameter is set to "on". In one embodiment, the encoding of the MS ID in the extension container is activated in the test mobile station only when the test mode parameter is set to "on".

4 is a flow chart illustrating a process in the example method. In step 402, the mobile station receives a message from the SMLC. Examples of the message may include an RRLP assistance data message or an RRLP measurement location request message. The method proceeds to step 404.

Optionally, the mobile station may also have a test mode parameter. If the mobile station is programmed to encode the MS ID and does not have a test mode parameter, step 404 will be omitted and the method proceeds directly to step 406. If the test mode parameter is included in the mobile station and its setting is " on ", then it also proceeds to step 406. If the mobile station is not programmed to send an MS ID, or if the test mode parameter is set to "off", the method proceeds to step 408.

In step 406, the mobile station encodes the MS ID associated with it in the extension container of the appropriate response message, such as measurement location response message 356 (FIG. 3), protocol error messages 346, 354, and the like. Suitable messages may include any message with an extension container. Other messages that may be sent without owning an extension container, such as an auxiliary data confirmation message, are not used to encode the MS ID and are not referenced by the procedures shown in FIG. The method proceeds to step 408.

In step 408 the mobile station sends an appropriate response message to the SMLC and proceeds to step 410.

In step 410 the SMLC processes the appropriate response message and proceeds to step 412.

In step 412, if the SMLC is properly designed to retrieve the MS ID from the expansion container, the method proceeds to step 414. If the SMLC fails to retrieve the MS ID, the method proceeds to step 416. If no MS ID has been received (eg, the test mode parameter is set to "off"), the method proceeds to step 416.

In step 414, the SMLC stores the MS ID associated with the unique positioning session identifier for as many references as required by the test descriptor, and then continues normal processing functionality.

At step 416, the SMLC may respond by sending an RRLP protocol error message to the mobile station and ending the location determination session with the BSC before continuing with normal processing functionality. Alternatively, if the mobile station did not transmit the MS ID (eg, the test mode is “off”), the SMLC will continue normal processing function at step 416. According to another possibility, the SMLC may send an RRLP protocol error message to the mobile station without terminating the positioning session with the BSC before performing the normal processing function. The possible responses by SMLC are discussed in more detail below.

There are a variety of advantageous new features. For example, the implementation of private extensions only affects the operation of the mobile station and SMLC. This does not affect the operation of other network components such as BSS, BSC or MSC (not shown). The mobile station identification method and apparatus does not affect other components since the RRLP message passes transparently by the BSC and only the size of the RRLP message is a factor for BSC processing of the message.

Another advantageous feature relates to the interoperability between the test mobile station and the "naive" SMLC (ie, SMLC is not designed to operate in test mode as described herein). For example, although roaming is an indeterminate environment for the operation of a test mobile station, there are a variety of possibilities if SMLC cannot decode the extension container, such as occurs with roaming situations. 1) When a non-experimental SMLC detects the presence of an optional extension container, the SMLC may not attempt to decode the message and may send a protocol error message in response. 2) When the expansion container is placed at the end of the message, the non-experimental SMLC attempts to decode the message but can stop the decoding upon arrival of the expansion container, thus processing part of the decoded message before arrival of the expansion container. have. 3) The non-experimental SMLC can decode the extension container, but may decide to discard the private extension because it does not recognize the OI for the private extension. In the case of 2) and 3) above, the positioning capability is maintained. However, in the case of 1) above, the test mobile station will not have positioning capability unless the test mode parameter is implemented and set to "off".

Another advantageous feature relates to the size of the RRLP measurement location response message. The addition of private extensions increases the size of the RRLP payload, particularly for RRLP measurement location response messages, which may be an issue in terms of partitioning. However, if the message size remains below 252 octets, no uplink segmentation is required. The preferred embodiment described above limits the increase in RRLP message size to 128 or more octets (120 octets is a typical number for reporting one set, such as one set of GPS measurements associated with 16 satellites). Reduce the likelihood that all of the RRLP messages will exceed 252 octets.

Those skilled in the communications and computer arts will recognize that computer readable media can be used in accordance with the teachings of the present invention that explicitly embody the methods of the foregoing embodiments. Such a medium may include without limitation RAM, ROM, EPROM, EEPROM, floppy disk, hard disk, CD-ROM, and the like. In addition, the present disclosure includes any method steps for the foregoing embodiment of digital logic on integrated circuits—FPGA, PLA, or other integrated circuits that may be fabricated or modified by computer program instructions. .

Mobile stations 110 and 210 in accordance with the present invention include, without limitation, wireless telephones, PDAs capable of wireless communications, laptops with wireless communications capabilities, and other mobile digital devices that perform personal communications over wireless connections.

A number of examples have been described. Nevertheless, it will be understood that the methods described herein may be performed in software, hardware, or a combination of software and hardware. As another example, it will be readily understood that the functions described by becoming part of one module are generally performed equivalently within the other module. As another example, the processes and actions described or shown in a particular sequence may be performed through other sequences, except for those embodiments described in the claims-including the specified sequence of steps. Could be.

Claims (20)

A location service test method for use in a wireless communication system, a) receiving a first location service message at a mobile station (MS); b) encoding a unique mobile station identifier in an extension container of a second location service message; c) in response to the first location service message, transmitting the second location service message to a serving mobile location center (SMLC); The SMLC has a number of positioning session identifiers. ; d) retrieving the unique mobile station identifier by decoding the extension container; And e) storing said unique mobile station identifier associated with and corresponding to a unique positioning session identifier belonging to said plurality of positioning session identifiers; How to test location services. The method of claim 1, The first location service message, Radio resource location service protocol (RRLP) radio data message, How to test location services. The method of claim 1, Wherein the first location service message is an RRLP measurement position request message, How to test location services. The method of claim 1, The unique mobile station identifier is, International Mobile Subscriber Identity (IMSI), How to test location services. The method of claim 1, The unique mobile station identifier is, Mobile Subscriber Integrated Services Directory Number (MSISDN), How to test location services. The method of claim 1, Encoding the unique mobile station identifier, Setting a test mode parameter to control the encoding of the unique mobile station identifier, How to test location services. The method of claim 1, The second location service message, RRLP protocol error message, How to test location services. The method of claim 1, The second location service message, RRLP measurement position response message, How to test location services. A system for testing location services in a wireless communication system, a) mobile station (MS) capable of performing location service functions; The mobile station is:   i) a transceiver configured to receive a first location service message and to transmit a second location service message; And   ii) an MS CPU operably connected with the transceiver, the MS CPU receiving a first location service message, the MS CPU encoding a mobile station identifier that uniquely identifies the mobile station, and Inserts the unique mobile station identifier into an extension container of the second location service message; b) a base station system (BSS) comprising a base station transceiver system (BTS) configured to send the first location service message to the mobile station and configured to receive the second location service message from the mobile station; And c) Serving Mobile Location Center (SMLC) that controls the location services for a wireless communication system. The SMLC has a plurality of positioning session identifiers. Including; The SMLC is,   i) an SMLC CPU operatively connected to the BSS? The SMLC CPU outputs the first location service message and sends the first location service message to the BSS, receives the second location service message from the BSS, and receives the extension container of the second location service message. Retrieve the unique mobile station identifier by decoding; ; And   ii) Memory connected to the SMLC CPU? The memory stores the unique mobile station identifier associated with and corresponding to a unique positioning session identifier among the plurality of positioning session identifiers; Including, Location service testing system. 10. The method of claim 9, The mobile station CPU, A test mode parameter, encoding the mobile station identifier, and inserting the unique mobile station identifier into an extension container in response to the setting of the test mode parameter, Location service testing system. The method of claim 10, The mobile station comprising: A user interface coupled to the mobile station CPU for controlling the setting of the test mode parameter; Location service testing system. 10. The method of claim 9, The second location service message, Radio resource location service protocol (RRLP) measurement position response message, Location service testing system. 10. The method of claim 9, The second location service message, Radio Resource LCS Protocol (RRLP) protocol error message, Location service testing system. 10. The method of claim 9, The first location service message, Radio Resource LCS Protocol (RRLP) auxiliary data message, Location service testing system. 10. The method of claim 9, The first location service message, Radio Resource LCS Protocol (RRLP) measurement position request message, Location service testing system. 10. The method of claim 9, The mobile station comprising: A Subscriber Identity Module (SIM) for storing the unique mobile station identifier, Location service testing system. 10. The method of claim 9, The unique mobile station identifier is, International Mobile Subscriber Identity (IMSI), Location service testing system. 10. The method of claim 9, The unique mobile station identifier is, Mobile Subscriber Integrated Services Directory Number (MSISDN), Location service testing system. A system for testing location services in a wireless communication system, a) means for receiving a first location service message; b) means for encoding a unique mobile station identifier in an extension container of a second location service message; c) means for sending the second location service message to a Serving Mobile Location Center (SMLC) that holds a plurality of positioning session identifiers in response to the first location service message; d) means for retrieving the unique mobile station identifier by decoding the extension container of the second location service message; And e) means for storing said unique mobile station identifier associated with and corresponding to a unique positioning session identifier among said plurality of positioning session identifiers; Location service testing system. A computer-readable medium containing a computer program executable on a general purpose computing device, comprising: The computer program may perform a location service test in a wireless communication system including a plurality of mobile stations and a plurality of base stations, The computer program is: a) a first set of instructions for receiving a first location service message at a mobile station (MS); b) a second set of instructions for encoding a unique mobile station identifier in an extension container of a second location service message; c) a third set of instructions for sending the second location service message to a Serving Mobile Location Center (SMLC) in response to the first location service message; The SMLC has a number of location session identifiers. ; d) a fourth set of instructions for retrieving said unique mobile station identifier by decoding said extension container; And e) a fifth set of instructions associated with and corresponding to a unique positioning session identifier belonging to the plurality of positioning session identifiers; Computer-readable media.

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