DE102011016905A1 - Method for determining location of terminal in mobile radio network, involves determining values for timing advance for terminal from three cells on basis of base stations - Google Patents

Abstract

The method involves determining the values for timing advance for a terminal from three cells (110,120,130) on the basis of base stations. The path lengths of signals are determined between the terminal and the base stations on the basis of the determined values for the timing advance. The determined path lengths of signals are converted in distances between the terminal and the base stations. Estimation for the location of the terminal is determined from the intersection points of three distance circles around the base stations. Independent claims are also included for the following: (1) a telecommunication system, which has a network unit; (2) a base station for use in a cell of a telecommunication system; and (3) a network unit, which receives information of received value for timing advance over a validity time period.

Description

Technical field of the invention

The invention relates to devices, methods and software products for determining the location of terminals in mobile networks.

background

BS:

Basisstation

UE:

User Equipment/Endgerät

DL:

Downlink/Abwärtsstrecke

UL:

Uplink/Aufwärtsstrecke

TA:

Timing Advance/Sendeversatz

GPS:

Global Positioning System

LTE:

Long-Term Evolution

RACH:

Random Access Channel

IP:

Internet Protocol

The following list contains the abbreviations used and their meanings within this description.

BS:

base station

UE:

User Equipment / Terminal

DL:

Downlink / downlink

UL:

Uplink / uplink

TA:

Timing Advance

GPS:

Global Positioning System

LTE:

Long-Term Evolution

RACH:

Random Access Channel

IP:

Internet Protocol

Embodiments of the present invention, by determining the location of UE, allow to avoid test drives with special measuring equipment or to reduce the number of such test drives.

Embodiments of the present invention allow the location of UE to be determined upon transmission of an emergency call.

• • Eine befriedigende Signalqualität der Funkverbindungen insbesondere an den Zellrändern, so dass UE sicher zwischen benachbarten Zellen wechseln können.
• • Einen ausreichenden Datendurchsatz in den Zellen, um Daten- und Sprachdienste in der gewünschten Qualität unterstützen zu können.
• • Einen sicheren Empfang der Kontrollkanäle im Bereich einer Zelle.

Through test drives, the operator of a mobile network receives measurement data, from which he can derive measures for the further development and configuration of his network or for the optimization of his network. Such test drives are z. B. for commissioning a new base station performed to determine suitable locations and to check the achieved cell coverage. But even in the normal operation of a mobile network regular test drives are required to detect necessary adjustments in an area of the mobile network. These adjustments are to ensure in a mobile network:

• A satisfactory signal quality of the radio links, in particular at the cell edges, so that UEs can safely switch between neighboring cells.
• • Sufficient data throughput in the cells to support data and voice services of the desired quality.
• • Safe reception of the control channels in the area of a cell.

The required data can be recorded by test drives using special measuring equipment. For a sufficient description of the reception conditions, however, a very large amount of such data is needed in a cell. In particular, these data must be available in a sufficient spatial resolution. Furthermore, the data should preferably be collected in an area of a cell if there is detected an unexpected or undesirable behavior.

• • Welche Messungen durchzuführen sind.
• • Welche Ereignisse eine der Messungen auslösen.
• • Welche Ereignisse eine Übertragung der ermittelten Messdaten zur Netzwerkeinheit auslösen, die die Auswertung der Messdaten vornimmt.

It has therefore been proposed to have measured data recorded by suitably configured UEs. For the acquisition of the measurement data, certain UEs can be selected from a central network unit. For these selected UEs, you can specify:

• • Which measurements are to be performed.
• • Which events trigger one of the measurements.
• • Which events trigger a transmission of the determined measured data to the network unit, which carries out the evaluation of the measured data.

Such inclusion of the measurement data by UE presupposes that it is possible to determine the location of an UE in the network with sufficient accuracy. The location information of the UE is used by the central network unit for the selection of the UEs to perform measurements. In particular, the location information of the UE is needed for the evaluation of the measurement data.

For the determination of the location of an UE satellite-based methods are known, the z. B. based on the evaluation of the GPS signal. However, most of the AEs do not support such procedures.

In addition, methods are known in which an UE determines its location by measurements of the received signals of adjacent cells. However, these methods require a temporal synchronization of the data transmissions of neighboring cells or at least assume that the time offsets of these data transmissions between neighboring cells are known.

invention

The determination of the location of an UE in the present invention is based on the determination of the TA for the UE in at least three adjacent cells.

The TA indicates to a UE the offset of the transmit window which, when transmitting data in the UL, causes the data to arrive at the BS within the intended receive window. Thus, the TA considers the signal propagation times in the data transmission between a UE and a BS. The signal transit time between a UE and a BS again, a measure of the distance between the UE and the BS.

The TA is z. B. in an LTE network when establishing a connection between a UE and the eNB (base station in a mobile network for LTE) determined. The UE first sends a random access preamble. These preambles are constructed so that the eNB can determine the TA for the UE from the received data. The eNB transmits the determined value to the UE as part of the random access response. Such a RACH procedure with determination of the TA is carried out, in particular, when a UE with an existing connection (connected mode) is handed over between two neighboring cells (handover).

• – Bestimmen der Werte für den Timing Advance für das Endgerät in Bezug auf die Basisstationen von mindestens drei Zellen;
• – Bestimmen der Weglängen der Signale zwischen dem Endgerät und den genannten Basisstationen, basierend auf den für das Endgerät in Bezug auf die genannten Basisstationen ermittelten Werten für den Timing Advance;
• – Umrechnen der ermittelten Weglängen der Signale in Abstände zwischen dem Endgerät und den genannten Basisstationen; und
• – Ermitteln einer Schätzung für den Ort des Endgeräts aus den Schnittpunkten von mindestens drei Abstandskreisen um die genannten Basisstationen.

The present invention comprises a method for determining the location of a terminal in a mobile radio network, comprising the steps:

• - determining the values for the timing advance for the terminal with respect to the base stations of at least three cells;
• Determining the path lengths of the signals between the terminal and the said base stations based on the values for the timing advance determined for the terminal with respect to the said base stations;
• - converting the determined path lengths of the signals into distances between the terminal and said base stations; and
• - determining an estimate for the location of the terminal from the intersections of at least three distance circles around said base stations.

• – einer ersten Netzwerkeinheit;
• – einer ersten Zelle mit einer ersten Basisstation in einem Mobilfunknetz;
• – eine oder mehrere zweite Zellen mit jeweils einer zweiten Basisstation in einem Mobilfunknetz;
• – einer dritten Zelle mit einer dritten Basisstation in einem Mobilfunknetz;
• – einem Netzwerk, das die erste Netzwerkeinheit, die zweite Netzwerkeinheit und die mindestens drei Basisstationen miteinander verbindet, wobei das Telekommunikationssystem so konfigurierbar ist, dass in ihm das beschriebene Verfahren zur Ortsbestimmung für ein Endgerät ausführbar ist.

The present invention further comprises a telecommunication system consisting of:

• A first network entity;
• - A first cell with a first base station in a mobile network;
• - One or more second cells, each with a second base station in a mobile network;
• - A third cell with a third base station in a mobile network;
• A network interconnecting the first network unit, the second network unit and the at least three base stations, wherein the telecommunication system is configurable such that the described method for locating a terminal is executable therein.

The present invention further comprises the first network entity of said telecommunications system, wherein the first network entity is configurable to establish cellular level measurement configurations for an area of the cellular network and transmit those cell level measurement configurations to the base stations via an interface and the network of said telecommunications system ,

• – eine Messkonfiguration auf Zellebene über ein Interface mit dem Netzwerk des Telekommunikationssystems empfängt;
• – aus der Messkonfiguration auf Zellebene eine Messkonfiguration für ein Endgerät bestimmt;
• – diese für das Endgerät spezifische Messkonfiguration über eine Luftschnittstelle zu diesem Endgerät überträgt;
• – von diesem Endgerät gesendete Messdaten empfängt;
• – auf Grund der vorliegenden Messdaten und Messkonfigurationen entscheidet, ob für dieses Endgerät eine Ortsbestimmung durchgeführt wird, und
• – im Fall der Ortsbestimmung das Endgerät an eine zweite Zelle übergibt und für das Endgerät Informationen über den Abstand zwischen dem Endgerät und der ersten Basisstation an die zweite Netzwerkeinheit des Telekommunikationssytems übermittelt, wobei diese Informationen basieren auf dem ermittelten Timing Advance für dieses Endgerät in Bezug auf die erste Basisstation.

The present invention further comprises a first base station in a first cell of said telecommunications system, the first base station being configurable to:

• Receiving a cell-level measurement configuration via an interface with the telecommunications system network;
• - determines a measurement configuration for a terminal from the cell-level measurement configuration;
• - transmits this terminal-specific measurement configuration over an air interface to that terminal;
• Receives measurement data sent by this terminal;
• - decides on the basis of the present measurement data and measurement configurations, whether a location is performed for this terminal, and
• - In the case of localization, the terminal transmits to a second cell and transmitted to the terminal information about the distance between the terminal and the first base station to the second network unit of the Telekommunikationsssytems, this information is based on the determined timing advance for this terminal in relation to the first base station.

• – Als Teil der Übergabe des Endgeräts von der ersten Zelle oder von einer anderen zweiten Zelle an diese zweite Zelle den Timing Advance des Endgeräts in Bezug auf diese zweite Basisstation bestimmt;
• – basierend auf dem Timing Advance zwischen dem Endgerät und dieser zweiten Basisstation Informationen über den Abstand zwischen dem Endgerät und der zweiten Basisstation an die zweite Netzwerkeinheit des Telekommunikationssystems übermittelt, und
• – das Endgerät an die dritte Zelle oder eine andere zweite Zelle übergibt.

The present invention further comprises a second base station in a second cell of said telecommunication system, said second base station being configurable to:

• - As part of the handover of the terminal from the first cell or from another second cell to this second cell determines the timing advance of the terminal with respect to this second base station;
• Based on the timing advance between the terminal and this second base station Information about the distance between the terminal and the second base station transmitted to the second network unit of the telecommunication system, and
• - Pass the terminal to the third cell or another second cell.

• – Als Teil der Übergabe des Endgeräts von der zweiten Zelle an die dritte Zelle den Timing Advance des Endgeräts in Bezug auf die dritte Basisstation bestimmt.
• – Basierend auf dem Timing Advance zwischen dem Endgerät und der dritten Basisstation Informationen über den Abstand zwischen dem Endgerät und der dritten Basisstation an die zweite Netzwerkeinheit übermittelt, und
• – das Endgerät an die erste Zelle übergibt.

The present invention further comprises the third base station in the third cell of said telecommunications system, the third base station being configurable to:

• - As part of the handover of the terminal from the second cell to the third cell determines the timing advance of the terminal with respect to the third base station.
• - Based on the timing advance between the terminal and the third base station transmitted information about the distance between the terminal and the third base station to the second network unit, and
• - Pass the terminal to the first cell.

• – Über das genannte Netzwerk des Telekommunikationssystem Informationen von den Basisstationen über den Abstand der Basisstationen von einem Endgerät empfängt;
• – diese Informationen speichert;
• – basierend auf diesen Informationen und den Ortskoordinaten der Basisstationen die Abstandskreise des Endgeräts um die Basisstationen ermittelt; und
• – basierend auf den Schnittpunkten der Abstandskreise den Ort des Endgeräts schätzt.

The present invention further comprises a second network entity of said telecommunications system, wherein the second network entity is configurable to:

• Via said network of the telecommunication system receiving information from the base stations about the distance of the base stations from a terminal;
• - store this information;
• - Based on this information and the location coordinates of the base stations determines the distance circles of the terminal to the base stations; and
• - Estimates the location of the terminal based on the intersections of the distance circles.

The present invention further comprises a further development of said telecommunication system, in which all information required for determining the position of a terminal is handed over to the handover of the terminal between the issuing and receiving cells as part of the information that is present when handing over a terminal between the issuing terminal be exchanged the receiving cell.

Brief description of the drawings

The inventive idea and possible embodiments of the present invention are set forth in the detailed description below. This description makes reference to the drawings referred to here:

Figure 1 shows the section of a communication system with three cells of a mobile network.

FIG. 2 shows the sequence of a method for determining the location of an UE in a mobile radio network according to the present invention.

Figure 3 shows an embodiment of a first network unit according to the present invention.

Figure 4 shows an embodiment of a second network unit according to the present invention.

Figure 5 shows an embodiment of a BS according to the present invention.

Detailed description of the invention

Figure 1 shows the section of a communication system according to an embodiment of the invention. A UE 100 maintains a connection with the BS 111 in the cell 110 over the air interface 112 , Next to it are two more cells 120 and 130 with her BS 121 respectively. 131 shown. All BS are over a network 140 with a first network units 141 and a second network entity 142 connected. The network 140 can be run as an IP-based network.

Figure 2 describes the sequence of a method for the section of the communication system shown in Figure 1 according to an embodiment of the invention. The method is in the form described z. B. applicable in a LTE mobile network. The method serves to configure UE-based measurements in the illustrated area of the mobile radio network and, if necessary, to determine the location of the UE.

• • Vorliegenden Meldungen über aufgetretene Fehlerereignisse in einer Zelle oder einem Bereich des Mobilfunknetzes. Diese Meldungen können z. B. festgestellte Verbindungsabbrüche betreffen.
• • Vorliegenden Meldungen, die den Datendurchsatz und die Qualität der Datendienste in einer Zelle oder einem Bereich des Mobilfunknetzes charakterisieren. Diese Meldungen können z. B. erkannte Überlastprobleme betreffen.
• • Vorgaben für eine regelmäßig durchzuführende Überwachung des Datenverkehrs in einer Zelle oder einem Bereich des Mobilfunknetzes. Diese Vorgaben können z. B. die Erfassung der Aufenthaltsorte der UE, der von den UE angeforderten Datendienste oder der von den UE beobachteten Signalqualität betreffen.
• • Vorliegende Notfallmeldungen, die die Feststellung des Aufenthaltsortes eines UE erfordern.

In step S1, the first network unit sets 141 determines the configuration for the UE-based measurements in a network area and transmits the configuration information for the UE-based measurements to the BS 111 . 121 and 131 , The network unit 141 can set this measurement configuration at cell level based on:

• • Present messages about occurred error events in a cell or area of the mobile network. These messages can z. B. detected disconnections concern.
• • Present messages that characterize the data throughput and quality of the data services in a cell or area of the mobile network. These messages can z. B. recognized overload problems.
• • Requirements for regular monitoring of traffic in a cell or area of the mobile network. These specifications can z. B. the detection of the whereabouts of the UE, the UE requested data services or the observed signal quality of the UE.
• • Present emergency messages that require determination of the whereabouts of an AEs.

In step S2, the BS activates 111 in the cell 110 that from the first network entity 141 received measurement configuration for the cell 110 ie the BS 111 determines from the measurement configuration at the cell level measurement configurations for the UEs that are in the cell 110 Maintain connections and transmit the instructions for these UE-specific measurement configurations to the UE. It may depend on the application, whether the selection of the UE for UE-specific measurement configurations already in the measurement configuration at the cell level of the first network unit 141 is given or whether the BS 111 decides on the selection of the UE for UE-specific measurement configurations on the basis of the measurement configuration at cell level. The BS 111 transmits a UE-specific measurement configuration via the air interface 112 to the UE 100 ,

In step S3, the BS decides 111 whether a determination of the place of the UE 100 is required to obtain the measurement data according to the measurement configuration specified at cell level. The BS 111 can evaluate measurement data that you have previously received from the UE 100 over the air interface 112 were reported before the BS 111 the location of the UE 100 abuts.

If a location determination is not required, the UE performs 100 the measurements according to the obtained UE-specific measurement configuration in step S4 and transmits the determined measurement data via the air interface 112 to the BS 111 ,

Is a location for the UE 100 required, so reports the first BS 111 in step S5, the current TA for the UE 100 over the network 140 to the second network unit 142 , The notification of the TA for the UE 100 contains an indication for identifying the UE and may include a time stamp indicating when the reported TA was determined. Further, in step S5, the UE 100 from the first cell 110 to a second cell 120 handover. For this purpose, the steps of the usual handover procedure can be run through. The first BS 111 can the second cell 120 as the destination of the handover based on the present neighborhood information. The neighborhood information allows a BS to identify neighboring cells and their BS and to configure measurements in which e.g. For example, the UE 100 the received signal strengths of adjacent cells reports. The measurement data thus obtained for the UE 100 in turn form the basis for a supplement or extension in the BS 111 present neighborhood information. The connection setup in the second cell 120 over the air interface 121 between the UE 100 and the second BS 121 requires the execution of the RACH procedure, which is the determination of the TA for the UE 100 in relation to the second BS 121 includes.

In step S6, the second BS notifies 121 the determined TA for the UE 100 over the network 140 to the second network unit 142 , The notification of the TA for the UE 100 contains an indication for identifying the UE and may include a time stamp indicating when the reported TA was determined. Furthermore, in step S6, the UE 100 from the second cell to a third cell 130 handover. For this purpose, the steps of the usual handover procedure can be run through. The second BS 121 can the third cell 130 as the destination of the handover based on obtained measurement data in which the UE 100 the received signal strengths of adjacent cells reports. The connection establishment in the third cell 130 over the air interface 131 between the UE 100 and the third BS 131 requires the execution of the RACH procedure, which is the determination of the TA for the UE 100 in relation to the third BS 131 includes.

In step S7, the third BS notifies 131 the determined TA for the UE 100 over the network 140 to the second network unit 142 , The notification of the TA for the UE 100 contains an indication for identifying the UE and may include a time stamp indicating when the reported TA was determined. Furthermore, in step S7, the UE 100 back to the first cell 110 handover. For this purpose, the steps of the usual handover procedure can be run through.

The procedure in Figure 2 can be extended to more than three cells if step S6 is run through several times, i. H. the UE is first passed to one or more other second cells before being passed to the third cell.

The sequence of cells between which the UE 100 can be passed in the second network unit 142 determined when the first BS ( 111 ) the present neighborhood information regarding UE 100 over the network 140 to the second network unit 142 transmitted. The network unit 142 On the basis of this information, it is possible to select the cells between which the UE 100 is passed in succession. Usually these will be the cells for which the UE 100 has reported the best received signal strengths. After that, the network unit 142 Prepare the BS in the affected cells by placing the BS in the respective cell across the network 140 at least tells to which cell the UE 100 is to be handed over and how the UE 100 can be identified. In this way, the UE 100 be passed between the different cells without having in each cell measurements of signal strengths of adjacent cells for the UE 100 required are. The purpose or cause of the transfer of the UE 100 can be detected in the receiving cell by identifying the UE 100 be recognized.

Parallel to the handover of the UE 100 in step S7 to the cell 110 In step S8, the evaluation of the reported TA in the second network unit 142 be executed. For the determination of the place of the UE 100 Measurements of the TA must be available for at least three cells. The product of TA and the speed of light indicates, for each cell, the path length of a signal, ie the length of the path that a signal passes between the BS in it Cell and the UE 100 travels. Figure 1 shows an example of the conditions for the case that in the entire considered area of the mobile network dominant direct paths to the BS 111 . 121 exist. Then all points with the same path length of the signals lie on circles around the BS, and the path length of the signals equals the distance between the UE and the BS for which this path length was determined. Figure 1 shows these distance circles 113 (around BS 111 ) 123 (around BS 121 ) and 133 (around BS 131 ) for the UE 100 , From the radii of these distance circles and the location coordinates of the BS 111 . 121 and 131 can the network unit 142 the common point of intersection 150 the distance circles 113 . 123 and 133 as an estimate for the location of the UE 100 determine. The determination of the point of intersection can also take account of correction factors for the radii of the distance circles, and for the radii of the distance circles 113 . 123 and 133 the corrected path lengths of the signals are used as estimates of the distances between the terminal and the base stations. The correction factors account for reflections in the transmission of the signals when there is no dominant direct path between a UE and a BS. The path length of the signal between this UE and the BS is then longer than the distance between the UE and the BS. Due to different reflections, in the case of missing dominant direct paths, the points of equal path length for signals in a cell are not on a circle, and the correction factors take into account the actual shape of the curve on which the points of equal path length lie in converting the determined path length to a distance between UE and BS. These correction factors may be predetermined by the operator for a cell or areas of the cell based on previous measurements.

Alternatively or additionally, an estimate of the current correction factor is possible. In such an estimation, measurement data of the UE can be received via the received signal strengths of BS of the neighboring cells, the location coordinates of these BS and in particular the path lengths of the signals determined for the UE in the neighboring cells. The estimation of the correction factors therefore becomes advantageous in the network unit 142 performed.

In one embodiment, the network entity 142 arrange the reported values for the TO according to the time stamps contained in the messages. Later TAs can then be weighted higher in the subsequent evaluation than those that were collected earlier. This weighting depending on the time information may be used when the steps S5, S6 and S7 are several times for the UE 100 were passed through. The weighting leads to a filtering of the path lengths of the signals determined for a TA. In one embodiment, the operator may specify a configurable time window, and for the location of the UE 100 only those values of the TA are considered, which were determined within the given time window.

In one embodiment, the network entity 142 For the filtering in addition to the time information consider further reliability information. Thus, in determining the TA, the BS may also determine an estimate of the signal-to-noise ratio during the RACH procedure and this information along with the TA to the network entity 142 transfer. A high signal-to-noise ratio for a TA value then leads to a higher weighting of the distance determined therebetween between a BS and a UE during the filtering in the network unit 142 ,

The procedure shown in Figure 2 can be extended to more than three cells. If the TA is determined in more than three cells, measurement inaccuracies will lead to the result that no common intersection of all distance circles can be found. As an estimate of the place for the UE 100 Then the center of gravity or the weighted center of gravity of the intersections of each three distance circles can be used. When calculating a weighted center of gravity, the individual weights take into account reliability information of the individual measurements for a reliability statement about the individual intersections of three distance circles each.

The result of the location for the UE 100 can the network unit 142 over the network 140 to the network unit 141 to transfer. The network unit 141 can use this information in a new step S1 to determine the next measurement configuration for the area of the mobile radio network.

In one embodiment, the BS 111 . 121 and 131 the final result of the location for the UE 100 over the network 140 from the network unit 141 or 142 Interrogate. The network unit 141 or 142 In addition to the location information, it can also return a time value which indicates the validity time of the location information.

In one embodiment, a single network entity handles the tasks of the network entities 141 and 142 ,

In another embodiment, the functions of the second network entity become 142 executed in a BS. These functions are preferred for the UE 100 in the first BS, since it has the necessary neighborhood information to select the cells between which the UE 100 is passed in succession. In a further development of this embodiment the values determined for the TA, the associated reliability information and the cells to be passed through in the further transfers are transferred with all other information required for the desired location determination as part of the information exchanged between the issuing and the receiving cell upon handover of a terminal become. Alternatively, the required neighborhood information for the terminal between the issuing and receiving cells may also be exchanged, and the BS in the receiving cell, based on this information about the terminal detectable cells and the received signal strengths of the detected cell, selects the target cell for the next handover out. In this way, the neighborhood information can be updated by new measurements in one of the passed cells. Such an update of the neighborhood information may e.g. B. be performed periodically, when each time information is passed, which identifies the age of the passed neighborhood information. In addition to the neighborhood information, a list of information may be provided which allows the BS of the receiving cell to identify the last cells passed. Based on this list and the neighborhood information, the BS in the receiving cell can decide whether a determination of the TA for determining the location of the UE is possible in another cell not included in this list. By means of this exchanged information, it is then possible to determine the location of the UE 100 in each BS of the current cell, provided that there are sufficient current / reliable measurements of the TA for at least three cells. Preferably, in this development, upon transfer of the UE between the issuing and the receiving cell, information is passed which indicates that the transfer takes place within a method for determining the location of the UE.

Performing the RACH procedure in a cell requires a data exchange of the UE 100 with the BS of this cell independent of the data transmissions in neighboring cells. Therefore, the TA for the UE 100 with respect to the BS of this cell without knowing the times of the data transmissions in the neighboring cells. The determination of the place of the UE 100 according to steps S5, S6, S7 and S8 therefore does not require synchronization or known time offsets of the data transfers in the cells 110 . 120 and 130 ,

A location determination according to steps S5, S6, S7 and S8 can be carried out regularly for the UE or selected UE of a section of the mobile radio network. This location information can be stored together with the measurement data determined by the UE or for the UE. These measurement data can z. B. include the measured received signal strength in the UL and / or DL and / or another measure of the current signal quality in the UL or / and DL. By linking the current measurement data with the location information for the UE, an image is generated for the area of the mobile radio network which indicates the signal quality as a function of the location of a UE. The evaluation of the measurement data and its linking to the location information of the UE can be performed in a central network unit (eg the network units 141 or 142 ) respectively. However, the corresponding evaluation and linking can initially also be carried out at the cell level in the BS. Subsequently, in the central network unit, the results determined in the BS are combined with a possible further cross-cell evaluation.

The determination of the location of a UE after receiving an emergency call for this UE can be understood as an element of a measurement configuration within the method illustrated in FIG. The presence of an emergency call for the UE 100 then performs a determination of the location for the UE in step S3 100 according to steps S5, S6, S7 and S8, if for the UE 100 no current location information is known.

Figure 3 shows a basic embodiment of the first network unit 141 consisting of a processor 301 , an interface 302 to the network 140 , a store 303 and a bus system 305 for data exchange between the components. The memory 303 contains the program to be executed and information about the configuration and status of the mobile network. This information may be available for different areas of the mobile network and / or for individual cells. In addition, the memory can 303 Information about the configuration, the state and in particular the location of UE in the mobile network included. By running the program from memory 303 can the processor 301 be configured so that it determines a new measurement configuration for at least a part of the network and the relevant parts of this measurement configuration via the interface based on the present configuration and state information according to step S1 302 transmits as measurement configuration at the cell level to the respective BS. Furthermore, the network unit 141 configured to receive messages with measurement data or status information from the second network unit 142 or a BS over the interface 302 received and in the processor 301 can evaluate. The results of this evaluation can be the processor 301 In the storage room 303 lay down.

Figure 5 shows a basic embodiment of a BS 111 . 121 and 131 consisting of a processor 501 , an interface 502 to the network 140 , a store 503 , a transceiver unit 504 for sending / receiving data via the air interface and a bus system 505 for data exchange between the components. The memory 503 contains the program to be executed and information about the configuration and the state of your own cell. In addition, the memory contains information about the configuration and state of the UE in the cell. In particular, the memory may include measurement data received from UE in the cell via the air interface and the transceiver 504 were reported. By running the program from memory 503 in the processor 501 The BS can be configured to allow the BS to perform a new cell-level measurement configuration via the interface 502 receives and activated according to step S2. The processor 501 determined on the basis of the memory 503 present configuration and state information and based on the received measurement configuration at the cell level, the UE-specific measurement configurations and causes the transmission of these UE-specific measurement configurations to the UE via the transceiver 504 , Further, the BS is configured to acquire measurement data of the UE via the transceiver according to step S4 504 receives and in the processor 501 evaluates. The results of this evaluation can be the processor 501 In the storage room 503 lay down. Furthermore, the BS is configured to perform a RACH procedure over the transceiver 504 and can determine and monitor the TA for an UE. Furthermore, the BS is configured to determine, according to step S3, whether a determination of the location is required for a UE. The corresponding evaluation is in the processor 501 executed. For a location, the processor causes 501 then the transmission of the TA for the UE via the interface 502 to the network unit 142 , The processor 501 can then additionally the transmission of time information and / or other reliability information via the interface 502 and the network unit 142 cause. Furthermore, the processor performs 501 for the location of an UE, a handover procedure for the UE with the BS of the selected target cell.

Figure 4 shows a basic embodiment of the second network unit 142 consisting of a processor 401 , an interface 402 to the network 140 , a store 403 and a bus system 405 for data exchange between the components. The memory 403 contains the program to be executed and the values of the TA for the various UEs and cells. In addition, the memory can 403 Contain time information for the determined TA and other reliability information. By running the program from memory 403 can the processor 401 be configured to determine the location of the UE according to step S8 based on the TA present for a UE and associated time information and reliability information. Furthermore, the processor 401 be configured to receive the determined location coordinates for the UE via the interface 402 along with time information on the validity of the determined location coordinates to the first network element 141 transfers.

• • Alle beschriebenen Verfahrensschritte können von einer software-gesteuerten Hardware oder einer anwendungsspezifischen Hardware ausgeführt werden, ohne die Funktion oder die beabsichtigte Wirkung der Verfahrensschritte zu verändern.
• • Die beschriebenen Ausführungsformen der Netzwerkeinheiten oder BS enthalten lediglich die für das Verständnis der Erfindung wesentlichen Komponenten.
• • Die beschriebenen Ausführungsformen und Verfahren dienen lediglich der Veranschaulichung. Die Offenbarung dieser Erfindung soll keinesfalls auf diese Ausführungsformen und Verfahren beschränkt sein. Vielmehr soll die Offenbarung alle Veränderungen und Abweichungen an bzw. von den beschriebenen Verfahrensschritten und Ausführungsformen umfassen, sofern diese ihrem Wesen nach innerhalb des Gültigkeitsbereichs der nachfolgenden Ansprüche liegen.

For the understanding and scope of the present invention, note:

• • All described process steps can be performed by software-controlled hardware or application-specific hardware without changing the function or the intended effect of the process steps.
• The described embodiments of the network units or BS contain only the components essential to the understanding of the invention.
• The described embodiments and methods are merely illustrative. The disclosure of this invention is not intended to be limited to these embodiments and methods. Rather, the disclosure is intended to include all changes and variations in and from the described method steps and embodiments, insofar as they are intrinsically within the scope of the following claims.

Claims (29)

A method for determining the location of a terminal in a mobile network comprising the steps of: - determining the values for the timing advance for the terminal with respect to the base stations of at least three cells; Determining the path lengths of the signals between the terminal and the said base stations based on the values for the timing advance determined for the terminal with respect to the said base stations; - converting the determined path lengths of the signals into distances between the terminal and said base stations; and - determining an estimate for the location of the terminal from the intersections of at least three distance circles around said base stations. A method according to claim 1, wherein the timing advance for the terminal relative to the base station of a cell is determined as part of a RACH procedure. A method according to claim 2, wherein the RACH procedure is triggered by a handover of the terminal into that cell. A method according to claim 1, wherein the conversion of the path length of the signal in a cell a correction factor is used at a distance between the terminal and the base station of the cell, taking into account reflections of the signal. A method according to claim 4, which takes into account in the estimation of the correction factor: - Measurement data of the terminal on the received signal strengths of base stations of neighboring cells, The location coordinates of this BS, The path lengths of the signals determined for the UE in the neighboring cells. A method according to claim 1, wherein for the determination of the intersections of the circles a distance between the terminal and a base station is used which is the result of a filtering taking into account several determinations of the path length of the signal between the terminal and the base station. A method according to claim 6, wherein time information is taken into account for the filtering of the multiple determinations of the path length, wherein a determination of the path length is weighted the higher the more up-to-date the measurement data used for the determination of the path length. A method according to claim 7, wherein only the path lengths based on measurement data obtained within a predetermined time window are taken into account for the filtering. A method according to claim 1, including determining the timing advance for more than three cells, wherein a weighted center of gravity of the intersections for each of the three circles is calculated as an estimate of the location of the terminal. A method according to any one of claims 1 to 9 carried out for determining the location of a terminal after an emergency call for this terminal. A telecommunication system comprising: - a first network entity; - A first cell with a first base station in a mobile network; - One or more second cells, each with a second base station in a mobile network; - A third cell with a third base station in a mobile network; A second network unit; - a network ( 140 ), which interconnects the first network unit, the second network unit and the at least three base stations, wherein the telecommunication system is configurable such that in it the method for location determination for a terminal according to claim 1 is executable. The first network entity of the telecommunication system of claim 11, wherein the first network entity is configurable to define cell-level measurement configurations for an area of the mobile network and to provide these cell-level measurement configurations via an interface and the network ( 140 ) can transmit to the base stations. A first base station ( 111 ) in a first cell of the telecommunications system of claim 11, wherein the first base station is configurable to: - a cell level measurement configuration via an interface to the network ( 140 ) receives; - determines a measurement configuration for a terminal from the cell-level measurement configuration; - transmits this terminal-specific measurement configuration over an air interface to that terminal; Receives measurement data sent by this terminal; Decides on the basis of the present measurement data and measurement configurations, whether a location determination is performed for this terminal, and - in the case of localization, the terminal to a second cell and for the terminal information about the distance between the terminal and the first base station to the second Network information transmitted, this information is based on the determined timing advance for this terminal with respect to the first base station. A second base station ( 121 ) in a second cell of the telecommunication system according to claim 11, said second base station being configurable to: - as part of the handover of the terminal from the first cell or from another second cell to said second cell, the timing advance of the terminal destined for this second base station; Based on the timing advance between the terminal and this second base station, transmits information about the distance between the terminal and the second base station to the second network unit, and - transfers the terminal to the third cell or another second cell. The third base station ( 131 ) in a third cell of the telecommunication system according to claim 11, wherein the third base station is configurable to: - determine, as part of the handover of the terminal from the second cell to the third cell, the timing advance of the terminal with respect to the third base station. Based on the timing advance between the terminal and the third base station information about the distance between the terminal and the the third base station is transmitted to the second network unit, and - transfers the terminal to the first cell. The second network entity of the telecommunication system of claim 11, wherein the second network entity is configurable to: - over the network ( 140 Receiving information from the base stations about the distance of the base stations from a terminal; - store this information; - Based on this information and the location coordinates of the base stations determines the distance circles of the terminal to the base stations; and - estimates the location of the terminal based on the intersections of the distance circles. The second network entity of claim 16, receiving said information from the base stations about the distance of the base stations from a terminal: - Timing Advance of the terminal relative to the base station or The path length corresponding to the timing advance of a signal or An estimate of the distance between the base station and the terminal based on the timing advance or the path length; The second network unit according to claim 17, additionally receiving said information from the base stations about the distance of the base stations from a terminal: Information about the validity time of the received value for the timing advance or the path length or distance estimation based thereon, and - information about the reliability of the received value for the timing advance or the path length or distance estimation based thereon; The second network unit of claim 18, which determines from the received information about the distance of the base stations from a terminal a filtered distance value for the distance of the terminal from a base station, wherein the received values for the timing advance or the path length or the estimated distance are weighted higher the more timely and reliable the corresponding timing advance has been determined. The second network unit according to claim 19, which takes into account only the received values for the filtering, for which the corresponding timing advance is based on measurement data obtained within a predetermined time window. The second network unit according to one of claims 16 to 20, which determines a correction factor for the conversion of the timing advance of a signal into a distance between a base station and the terminal, wherein the calculation of this correction factor takes into account: The determined path lengths for the terminal in the neighboring cells, The location coordinates of the base stations in the neighboring cells and - Measurement data of the terminal on the received signal strengths from the base stations of neighboring cells. The second network entity of claim 16 is configurable to - receives neighborhood information regarding a terminal from a base station; - determines based on this neighborhood information a sequence of cells between which the terminal is to be handed over one after the other; and - Preparing the affected cells by telling the base stations of the respective cells, to which cell the terminal is to be handed over and how the terminal can be identified. The telecommunications system of any one of claims 11 to 22, comprising a network entity comprising the functions of the first and second network entities. The telecommunication system of any of claims 11 to 22, wherein the functions of the second network entity are performed in a base station. The telecommunications system of claim 24, wherein the first base station performs the functions of the second network unit. The telecommunication system according to claim 24, wherein all the information required for location determination of a terminal is handed over when handing over the terminal between the issuing and the receiving cell as part of the information which is transferred upon handover of a terminal between the issuing cell and the receiving cell , The telecommunication system according to claim 24, wherein neighbor information regarding a terminal is handed over between the base station of the transferring cell and the base station of the receiving cell, and the base station of the receiving cell based on this information the target cell for at least the next transfer of the Determines the terminal. The telecommunication system of claim 27, wherein a list of information is passed in the base station of the accepting cell last identified an identification of the last passed cells, and the base station in the receiving cell based on this list and the neighborhood information decides whether a determination of the timing advance for location of the terminal in another, not included in this list cell is possible. The telecommunication system according to claim 26, wherein in the transfer of the terminal between the issuing and the receiving cell information is passed indicating that the transfer takes place within a method for determining the location of the terminal.

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