EP4281797A1

EP4281797A1 - Delay compensation for a geolocation measurement with uplink reference signals

Info

Publication number: EP4281797A1
Application number: EP22705075.4A
Authority: EP
Inventors: Philippe Chanclou
Original assignee: Orange SA
Current assignee: Orange SA
Priority date: 2021-01-22
Filing date: 2022-01-21
Publication date: 2023-11-29
Also published as: WO2022157461A1; FR3119243A1

Abstract

The invention relates to a method for receiving an uplink reference signal (PRS1, PRS2) sent by a mobile terminal (1) to a network entity (DU) through a radio unit (RU) connected to an antenna, and used to geolocate the mobile terminal (1), the method being implemented by the network entity (DU) and comprising: - recording, by way of time of arrival of the reference signal, a time obtained by adding a delay, called the waiting delay, to the time at which the reference signal was sent by the radio unit (RU), the waiting delay being larger in value than a transmit path time of a signal called the comparison signal (S1, S2), between the radio unit (RU) and the network entity (DU), and - sending a message to a geolocation server (Geoloc), comprising information relating to the recorded time of arrival.

Description

DESCRIPTION

Delay compensation for a geolocation measurement with rising reference signals

1. Field of the invention

The present invention relates to the field of geolocation of mobile terminals, for example, geolocation by means of a triangularization technique via antennas close to a mobile terminal.

2. State of the prior art

It finds applications in particular in the calculation of the distance between a transmitter and a mobile terminal by estimating arrival times or differences in arrival times.

For example, these estimates can be made by the transmission by the mobile equipment of location signals according to the method called Uplink Time Difference of Arrival (U-TDOA). Localization is done in two steps. First, the time differences are estimated. The mobile equipment transmits an uplink signal which arrives at different times at each of the base stations consisting of a radio unit ("Radio Unit" or RU in English), a distributed unit ("Digital Unit" or DU in English) and a centralized unit (CU) of the radio access network (“Radio access network” or RAN in English). A central server retrieves these different signals from the base stations and determines the difference in arrival time between the signals. These time differences are estimated by subtracting the times of arrival (TOA) from each of the base stations.

Whether in the case of measurement carried out by sending reference signals by the DUs to the mobile terminal, i.e. downlink, or in the case of measurement carried out by sending reference signals by the mobile terminal to the DUs, that is to say by uplink as previously described, to make it possible to precisely estimate the geolocation by means of the times of arrivals or the differences in times of arrivals, it is necessary to know the travel time reference signals between the antennas and the mobile terminal.

These reference signal transmission travel times between the antennas (or Rlls which are located close to the antennas, which is not necessarily the case for DUs) and the mobile terminal can be deduced from the travel time between the terminal mobile and the DU, i.e. the time taken by the reference signal transmitted by the UE to travel the path mobile terminal/DUs, since it is considered that the time taken by the reference signals to travel the path RU/DU is negligible. Indeed, current geolocation techniques were designed at a time when the functions performed by equipment of the DU and RU type were grouped together in a single equipment or at least co-located close to the antenna.

However, equipment of the DU type and of the RU type tend to be more and more distant from each other over distances which can vary from a few meters to several tens of kilometers. The travel time between these devices is no longer negligible and falsifies the geolocation measurements.

One of the aims of the invention is to remedy these drawbacks of the state of the art.

3. Disclosure of Invention

The invention improves the situation with the aid of a method for receiving an uplink reference signal sent by a mobile terminal to a network entity through a radio unit connected to an antenna, used for geolocation of the mobile terminal, the method being implemented by the network entity and comprising:

- the recording, as the instant of arrival of the reference signal, of an instant obtained by adding a so-called time delay to the instant of transmission of the reference signal by the radio unit, the delay time being of a value greater than a transmission path time of a so-called comparison signal, between the radio unit and the network entity, and

- sending a message to a geolocation server, comprising information relating to the recorded arrival time.

Unlike the prior art, this is not the actual time of arrival of the signal from reference which is recorded, but a fictitious moment of arrival calculated to compensate for inaccuracies due to the non-air part of the reference signal path. Thus, whatever the effective travel time of a signal between the radio unit and the network entity, which is of a duration which depends on the distance traveled and on time-varying transmission conditions, it is possible to deduce the travel time of this signal between the mobile terminal and the antenna of the radio unit, i.e. the travel time through the air (also called flight time), simply by knowing the timeout value and the total fictitious journey time between the mobile terminal and the network entity. It is in fact the travel times in the air of the reference signals, also called time of flight, between several antennas and a mobile terminal, which make it possible to calculate its position with respect to these antennas with precision. Advantageously, thanks to the proposed method, the portion of the travel time downstream of an antenna is extended by a fictitious value equal to the time delay, and is therefore constant whatever the distance traveled and the transmission conditions. By subtracting the timeout delay from the fictitious total travel time between the terminal and the network entity, the flight time is obtained. It only remains for the network entity to transmit to a geolocation server either this flight time, or the difference between two of these flight times if the entity receives two reference signals having passed through two units different radios. Thus, the proposed method compensates for the transmission delays which are due to the non-aerial part of the paths of the reference signals used to determine the geolocation of a terminal.

The comparison signal can be any signal between the radio unit and the network entity, including being the reference signal itself.

According to one aspect of the proposed method, it comprises measuring a value of the transmission path time of the comparison signal.

Thanks to this aspect, the network entity can verify that the delay is indeed greater than the travel time of a comparison signal, and trigger a procedure for updating the value of the delay if this is not the case. .

According to one aspect of the proposed method, the comparison signal is the reference signal. Thanks to this aspect, no specific signal, other than the reference signal itself, is necessary for the proposed method.

According to one aspect of the proposed method, the comparison signal is a signal distinct from the reference signal.

Thanks to this aspect, the measurement of the travel time of a comparison signal can be performed by the network entity prior to the processing of the reference signal, and independently of the latter.

According to one aspect of the proposed method, it comprises the transmission, to the radio unit, of a request for transmission of the comparison signal.

Thanks to this aspect, the network entity, or another entity further upstream, can receive a comparison signal which enables it to determine a value of the delay which is greater than the travel time of a comparison signal.

According to one aspect of the proposed method, it comprises the reception of a message comprising the value of the time delay.

In this mode, the network entity applies a time delay imposed on it to the reference signal, and does not need to determine it itself. The value of the timeout delay can for example be supplied to the network entity by a centralized unit further upstream in the network.

According to one aspect of the proposed method, it comprises the determination of the value of the time delay as a function of the measured value of the travel time of the comparison signal, and where the message intended for a geolocation server comprises the determined value of the timeout period.

In this mode, the network entity determines itself the delay which it applies to the reference signal. The network entity must then transmit the value of the time delay to the entity responsible for geolocation, so that it can correct the information which reaches it relating to the travel times of reference signals. According to one aspect of the proposed method, the message intended for a geolocation server comprises the recorded arrival time.

Thanks to this aspect, the geolocation server receives information known in the standard under the name TOA (Time Of Arrival) by all the network entities. The network entity does not calculate the differences between TOAs of reference signals, but sends to the geolocation server the fictitious times of arrival of these reference signals, and possibly the value or values of the time delays, so that the geolocation server can calculate the times of flight of all the reference signals.

The different aspects of the method for receiving an uplink reference signal which have just been described can be implemented independently of each other or in combination with each other.

The invention also relates to a device for receiving an uplink reference signal transmitted by a mobile terminal to a network entity through a radio unit connected to an antenna, used for geolocation of the mobile terminal, the device being included in the network entity and comprising a receiver, a transmitter, a processor and a memory coupled to the processor with instructions intended to be executed by the processor for:

This device, capable of implementing in all its embodiments the method for receiving an uplink reference signal which has just been described, is intended to be put implemented in a network entity of a base station of a cellular network, for example of the Digital Unit (DU) type.

The invention also relates to a computer program comprising instructions which, when these instructions are executed by a processor, lead the latter to implement the steps of the method for receiving an uplink reference signal, which comes from be described.

The invention also relates to an information medium readable by a network entity of a base station of a cellular network, and comprising instructions from a computer program as mentioned above.

The above mentioned program may use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code, such as in partially compiled form, or in n any other desirable shape.

The information carrier mentioned above can be any entity or device capable of storing the program. For example, a medium may comprise a storage means, such as a ROM, for example a CD ROM or a microelectronic circuit ROM, or even a magnetic recording means.

Such a storage means can for example be a hard disk, a flash memory, etc. On the other hand, an information medium can be a transmissible medium such as an electrical or optical signal, which can be conveyed via an electrical or optical cable, by radio or by other means. A program according to the invention can in particular be downloaded from an Internet-type network.

Alternatively, an information medium may be an integrated circuit in which a program is incorporated, the circuit being adapted to execute or to be used in the execution of the method in question.

4. Presentation of figures Other advantages and characteristics of the invention will appear more clearly on reading the following description of a particular embodiment of the invention, given by way of a simple illustrative and non-limiting example, and the appended drawings, among which :

[Fig 1] Figure 1 schematically presents a network entity, a radio unit and a mobile terminal according to one embodiment of the invention,

[Fig 2] Figure 2 shows an example of implementation of the method for receiving an uplink reference signal, according to one embodiment of the invention,

[Fig 3] Figure 3 shows an example of the structure of a device for receiving an uplink reference signal, according to one aspect of the invention.

5. Detailed description of at least one embodiment of the invention

By transmission conditions, it is understood both the conditions internal to the network (prioritization, resource allocation, routing path, buffering, channel coding, etc.) and the conditions external to the network (schedule, variation of temperature, significant traffic fluctuation, electromagnetic interference, etc.). These transmission conditions impact the signal transmission time more or less significantly.

Signals used to estimate the position of a terminal are understood to mean the signals used to determine travel times between two points of the network, for example, between a mobile terminal whose position is to be determined and a network entity via a radio antenna or even a radio unit whose position is known (for example, a signal which is intended to allow measurement of a transmission path time between the network entity and the mobile terminal via the radio unit ) or even between the network entity and the radio unit (for example, a signal which is intended to allow a measurement of a transmission path time on a part of a communication network between the network entity and radio unit). These signals can be reference signals. Thus, when the entity of the network is the one which emits the signals and the mobile terminal the one which receives them, that is to say when the link is used downward, then the signals used may be positioning reference signals (PRS). These PRS sequences are particularly advantageous insofar as they have good autocorrelation properties and low cross-correlation, thus making it possible to precisely extract the PRS in order to measure its time of arrival.

By radio unit is meant the radio transceiver which processes or produces the electrical signal transmitted to the antenna or received from the antenna and which corresponds to the radio signal transmitted or received by the antenna. The radio unit is the term used in the 5G standard but this unit can also be called remote radio head or "remote radio head" in English (RRH) or even remote radio unit or "radio remote unit" in English ( RRU). This radio unit is separate from the network entity.

By mobile terminal receiving radio signals from the radio unit it is understood that the terminal can at least partially decode the signals it receives from the radio unit. The mobile terminal can be connected to the base station corresponding to the radio unit.

The network entity (or network entity) can be a distributed unit (this is the term used in the 5G standard) also called a digital unit or a base band unit (“base band unit” in English, BBU). This can be included in a base station or co-located with a centralized unit (CU). The network entity is connected to the radio unit by optical and/or microwave links, over distances varying from a few meters to several tens of kilometers. The network entity allows the processing of digital data to and from the radio unit which receives and transmits this data in radio form.

The measurement of the transmission path time of a signal between the radio unit and the entity of the network can be carried out by any known technique, in one direction or the other. When the network entity and the radio unit are synchronized, which is the case in the 5G standard, then a measurement of the transmission path time can be carried out by sending a signal comprising information relating to the moment of its transmission and the receiver can then compare the time of arrival with the time of transmission of the signal. In the latter case, the measurement of the transmission path time between the network entity and the radio unit can then be performed by the network entity when the radio unit sends the second signal or by the radio unit when the network entity sends the second signal. In the latter case, the radio unit can transmit this measurement to the network entity if necessary (each time the network entity uses this measurement and it has not calculated it itself, it obtained via the radio unit).

Figure 1 schematically presents a network entity, a radio unit and a mobile terminal according to one embodiment of the invention.

In the example of figure 1 the mobile terminal 1 of a user 2 is in the radio coverage of two radio antennas 3.0 and 4.0.

The mobile terminal 1 receives the signals produced by the radio units (RU) 3.1 and 4.1 and transmitted respectively by the antennas 3.0 and 4.0. The 3.1 and 4.1 radio units are each connected to a 5.0 network entity. The links 3.2 and 4.2 between the network entity and the radio units 3.1 and 4.1 can be optical or even electrical links. The 5.0 network entity in the 5G standard is a distributed unit (DU). This network entity 5.0 sends signals to the radio units 3.1 and 4.1 which the radio units 3.1 and 4.1 convert into electrical signals inducing radio signals via the antennas 3.0 and 4.0, and vice versa. The 3.1 radio unit and the 5.0 network entity can be co-located, the link between the radio unit and the 5.0 network entity is then short, for example a few meters. The network entity 5.0 can also be located at a distance from the radio unit 4.1, for example several kilometers or tens of kilometers.

In the example of figure 1, a single network entity 5.0 is represented for the two radio units 3.1 and 4.1. However, each radio unit 3.1 and 4.1 can be served by a separate network entity, which is not shown in the figure, but the implementation of the invention in this case does not imply any particular modification with respect to the implementation depicted in Figure 1.

In the example of Figure 1 a centralized unit (CU) 6 is also connected to the network entity 5.0. In the 5G standard, the separation of the functions of a base station means that it can consist of a centralized unit CU connected to one or more network entities DU, each DU being connected to one or more radio units RU. The geolocation of the mobile terminal 1 is done, among other things, by a measurement relating to the signal transmission journey time, for example reference signals such as the PRS, between the network entity 5.0 and the mobile terminal 1.

The mobile terminal 1 sends a PRS, denoted PRS1, to the network entity 5.0 via the radio unit 3.1 and another PRS, denoted PRS2, to the network entity 5.0 via the radio unit 4.1. More precisely, the mobile terminal 1 emits a PRS signal in radio waves, which is picked up both by the antenna 3.0 of the radio unit 3.1 and by the antenna 4.0 of the radio unit 4.1, after flight times a priori different. Each radio unit then transmits the signal it has received to the network entity 5.0.

The network entity 5.0 then measures the TOA (Time Of Arrival) of each of the PRS signals received. However, the TOA (Time Of Arrival) obtained do not take into account the transmission path time of the signals PRS1 and PRS2 on the links 3.2 and 4.2, these not having the same transmission characteristics. The transmission path times of the PRS1 and PRS2 signals on the links 3.2 and 4.2, that is to say between the radio units 3.1 and 4.1 respectively and the network entity 5.0, are denoted t3 and t4 respectively. The measurement of times t3 and t4 can be made using dedicated signals S1 and S2 in the control plane, called comparison signals. Alternatively, this measurement can also be made directly on the PRS1 and PRS2 signals by the network entity 5.0 when it receives them. In this case, the reference signals PRS1 and PRS2 also serve as comparison signals.

According to the prior art, the geolocation of the mobile terminal 1 is estimated based on a direct measurement of the difference in the transmission path times of PRS1 and PRS2, i.e. U-TDOA. But this geolocation method is imprecise because it does not take into account the difference between times t3 and t4 in the calculation of U-TDOA.

The transmission of PRS1 and PRS2 to determine the U-TDOA are triggered by a request to the geolocation server 7 (Geoloc) requesting the positioning of the mobile terminal 1. This may be requested by an application of the mobile terminal 1 or by a request external to the terminal, for example by an authority distinct from the operator, to geolocate a person, that is to say the user 2 of the mobile terminal 1 .

The server 7 sends a request to the centralized unit 6 which controls the network entity 5.0 in order to obtain the data necessary for a geolocation of the mobile terminal 1. The centralized unit 6 then sends a command message to the network entity 5.0 to trigger the transmission of PRS1 and PRS2.

According to one aspect of the invention, the radio units 3.1 and 4.1 delay the PRS1 and PRS2 when they receive them, before transmitting them to the mobile terminal 1 . The time delay t34* applied is the same for all the radio units, and is calculated with respect to the instant of transmission of the reference signals PRS1 and PRS2 by the network entity. Thus, the times t3 and t4 being constant and all having the value of the time delay t34*, no longer need to be measured. However, it may be necessary to occasionally check that the value of the time delay t34* remains much greater than those of the times t3 and t4, by means of specific measurements that the network entity can perform. On the other hand, the geolocation server 7 can perform precise geolocation without knowing the times t3 and t4 or their difference.

FIG. 2 represents an example of implementation of the method for receiving an uplink reference signal, according to one embodiment of the invention.

During a step St1 , network entity 5.0 is configured, i.e. one or more values of time delay t34* is recorded in its memory. Different values can indeed be used for each of the radio units 3.1 and 4.1.

During a step St2, the server 7 receives a geolocation request from the mobile terminal 1, for example, a request sent by a supervision entity further upstream in the network, or by an application in the mobile terminal 1.

During a step St3, the server 7 sends a TOA measurement request to the centralized unit 6. During a step St4, the centralized unit 6 sends a message through a control channel to the network entity 5.0 to trigger the PRS travel time measurement protocol. The central unit can also send this message to other network entities to which other radio units, not shown, are connected.

During a step St5, the network entity 5.0 which received the message, commands the mobile terminal 1 to transmit the reference signals PRS1 and PRS2, PRS1 being sent to the network entity 5.0 via the radio unit 3.1 and PRS2 being sent to the mobile terminal 1 via the radio unit 4.1. The reference signals are timestamped at the time of their transmission by the mobile terminal 1 .

The network entity 5.0 also commands each of the radio units 3.1 and 4.1 to transmit, in the control plane, the comparison signals S1 and S2 to the network entity 5.0. The comparison signals are timestamped at the time of their transmission by the radio units 3.1 and 4.1, respectively. In a variant, the reference signals serve as comparison signals and it is not necessary for the signals S1 and S2 to be sent. In the following, for simplicity, the mention of these comparison signals can equally mean signals distinct from the reference signals, or identical.

The reference signals PRS1, PRS2, and the comparison signals S1 and S2 can be transmitted periodically.

If the network entity 5.0 detects that the travel time of a comparison signal is greater than its timeout delay t34* stored during step St 1 , then, during a step St5' not shown in the figure 2, the network entity 5.0 triggers a timer review procedure, so that the value of the timer delay is revised upwards.

The method then stops, or returns to step St 1 .

During a step St6, the radio units 3.1 and 4.1 receive the signals PRS1 and PRS2 emitted by the mobile terminal 1, assign them a timestamp of passage and retransmit them without delay to the network entity 5.0. The travel times between, on the one hand, the radio unit 3.1 and the radio unit 4.1 and, on the other hand, the network entity 5.0, are denoted t3 and t4 respectively. During a step St7, the network entity 5.0 receives, at a priori different instants, the signals PRS1 and PRS2 emitted by the mobile terminal 1, through the radio units 3.1 and 4.1 respectively, after a priori flight times different.

During a step St8, the network entity 5.0 modifies the instant of reception of a reference signal received (PRS1 or PRS2) by adding the time delay t34* to the timestamp of passage of the reference signal through the radio unit, and saves the result as TOA of the reference signal.

It will be understood that thanks to this operation the duration of the non-aerial part of a path of a reference signal PRS has been corrected to be equal to the time delay t34*.

During a step St10, the network entity 5.0 sends to the server 7 the TOAs of the reference signals PRS1 and PRS2. Thus, the server 7 can determine U-TDOA, the difference between the travel times of these reference signals.

During a step St11, the network entity 5.0 sends to the server 7 the time delay(s) t34* corresponding to the TOAs, possibly at the request of the server 7. Thus, the server 7 can determine the flight times of the reference signals PRS1 and PRS2, based on TOA and t34*. The server 7 can also correct the U-TDOA, when the time delays t34* are not of identical value for all the reference signals. The server 7 can then determine a precise position of the mobile terminal 1 on the basis of the times of flight (in the air) of the signals PRS1 and PRS2, and possibly on the basis of other time of flight measurements obtained separately from other network entity(ies) and other radio units connected to other antennas.

There is a maximum time limit between a network entity and a radio unit. In effect the network entity continuously calculates a parameter called “timing advance” with each of the radio units to synchronize the information sent and received. This time calculation must stay below a limit to maintain efficient communication (typically <1 ms). The time delay t34* must therefore be set to keep a margin of time in the total propagation time between network entity and mobile terminal. However, it is not advisable to set t34* arbitrarily at 500ps to cover all cases. For example, the time delay t34* between the radio unit 3.1 and the network entity 5.0 can be fixed at a value 10% greater than the time t3.

FIG. 3 presents an example of the structure of a device for receiving an uplink reference signal, according to one aspect of the invention.

The reception device 100 implements the method for receiving an uplink reference signal, various embodiments of which have just been described.

Such a device 100 can be implemented in a network entity DU.

For example, the device 100 comprises a receiver 101, a transmitter 102, a processing unit 130, equipped for example with a microprocessor pP, and controlled by a computer program 110, stored in a memory 120 and implementing the method of receiving an uplink reference signal according to the invention. On initialization, the code instructions of the computer program 110 are for example loaded into a RAM memory, before being executed by the processor of the processing unit 130.

Such a memory 120, such a processor of the processing unit 130, such a receiver 101 and such a transmitter 102 are capable of, and configured for:

• the recording, as the instant of arrival of a reference signal, of an instant obtained by adding a so-called time delay to the instant of transmission of the reference signal by a radio unit RU , the time delay being of a value greater than a transmission path time of a so-called comparison signal, between the radio unit RU and a network entity DU comprising the device 100, and

• sending a message to a Geoloc geolocation server, comprising information relating to the recorded arrival time.

Advantageously, they are also suitable for, and configured for:

• measuring a value of the transmission path time of the comparison signal,

• the transmission, intended for the radio unit RU, of a request for transmission of the comparison signal,

• receipt of a message including the timeout value, and

• the determination of the value of the time delay according to the measured value of the travel time of the comparison signal.

The entities described and included in the device described in relation to FIG. 3 can be hardware or software. Figure 3 illustrates only one particular way, among several possible, of carrying out the algorithm detailed above, in relation to Figures 1 and 2. Indeed, the technique of the invention is carried out indifferently on a reprogrammable computing machine (a PC computer, a DSP processor or a microcontroller) executing a program comprising a sequence of instructions, or on a dedicated calculation machine (for example a set of logic gates such as an FPGA or an ASIC, or any other hardware module) .

In the case where the invention is implemented on a reprogrammable calculating machine, the corresponding program (that is to say the sequence of instructions) can be stored in a removable storage medium (such as for example a USB key , a floppy disk, a CD-ROM or a DVD-ROM) or not, this storage medium being partially or totally readable by a computer or a processor.

Claims

1. Method for receiving an uplink reference signal (PRS1, PRS2) transmitted by a mobile terminal (1) to a network entity (DU) through a radio unit (RU) connected to an antenna, used for a geolocation of the mobile terminal (1), the method being implemented by the network entity (DU) and comprising:

- the recording, as the instant of arrival of the reference signal, of an instant obtained by adding a so-called time delay to the instant of transmission of the reference signal by the radio unit (RU ), the time delay being of a value greater than a transmission path time of a so-called comparison signal (S1, S2), between the radio unit (RU) and the network entity (DU), and

- sending a message to a geolocation server (Geoloc), comprising information relating to the recorded arrival time.

2. Method according to claim 1, comprising measuring a value of the transmission path time of the comparison signal (S1, S2).

3. Method according to one of the preceding claims, wherein the comparison signal (S1, S2) is the reference signal (PRS1, PRS2).

4. Method according to one of claims 1 to 2, wherein the comparison signal (S1, S2) is a signal distinct from the reference signal (PRS1, PRS2).

5. Method according to one of claims 2 to 4, comprising the transmission, to the radio unit (RU), of a request for transmission of the comparison signal (S1, S2).

6. Method according to one of the preceding claims, comprising receiving a message comprising the value of the timeout period.

7. Method according to claim 2, comprising determining the value of the delay delay according to the measured value of the travel time of the comparison signal (S1, S2), and where the message intended for a geolocation server (Geoloc) comprises the determined value of the delay time.

8. Method according to one of the preceding claims, where the message intended for a geolocation server (Geoloc) comprises the recorded arrival time.

9. Device for receiving an uplink reference signal (PRS1, PRS2) transmitted by a mobile terminal (1) to a network entity (DU) through a radio unit (RU) connected to an antenna, used for a geolocation of the mobile terminal (1), the device being included in the network entity and comprising a receiver (101), a transmitter (102), a processor (130) and a memory (120) coupled to the processor with instructions intended to be executed by the processor to:

- the recording, as the instant of arrival of the reference signal, of an instant obtained by adding a so-called delay time to the instant of transmission of the reference signal (PRS1, PRS2) by the radio unit (RU), the time delay being of a value greater than a transmission path time of a so-called comparison signal (S1, S2), between the radio unit (RU) and the network entity (DU), and

10. Computer program (110), comprising instructions which, when these instructions are executed by a processor, lead the latter to implement the steps of the method for receiving an uplink reference signal (PRS1, PRS2) used for geolocation of a mobile terminal (1), according to any one of claims 1 to 8.

11. Information medium readable by a network entity of a cellular network, and comprising instructions of a computer program (110) in accordance with claim 10.