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    • 专利摘要:
    The object of the present invention relates to a method and a system for determining a power value of a signal received from each of the neighboring cells to a serving cell while remaining connected thereto. The implementation of the method relies in particular on the use of downlink transmitted CRS signals from the eNB base station to the mobile equipment, with adequate Doppler compensation to allow the protocol stack of mobile equipment to measure the signal level received from each neighboring cell with optimal accuracy.
    公开号:FR3038201A1
    申请号:FR1501298
    申请日:2015-06-23
    公开日:2016-12-30
    发明作者:Dorin Panaitopol;Isabelle Icart
    申请人:Thales SA;
    IPC主号:
    专利说明:

    [0001] The invention relates to a method and a system for measuring the power transmitted by one or more base stations in a communication network and in particular upstream of the transfer step or change of communication cell, better known under the term Anglo-Saxon "Handover" for mobile devices moving in a communication network.
    [0002] It can be used, for example, for LTE (Long Term Evolution) communications for aircraft, for high-speed trains or other communication platforms that are moving very rapidly or in very short periods of time. other systems, whatever the mobile technology used, for example 2G or 3G technology. The mobile equipment may be a user located in an aircraft or other carrier, or equipment disposed on the outside of the aircraft and in communication with one or more users. An LTE mobile user on board an aircraft, such as an aircraft, must be able to communicate with LTE base stations located on the ground. These control the communication and provide a means of connection to the LTE core. The transfer of the data flow between the passengers and the mobile user UE is in particular ensured by means of an internal network to the aircraft, for example a WiFi network. When the aircraft is traveling with a very high speed, the signals received / transmitted by the mobile user from / to a base station are affected by Doppler shifts very much higher than what can tolerate the LTE standard, about 900 Hz. If the Doppler shift is corrected with respect to the serving base station to which the mobile user is attached, the mobile user will not be able to accurately measure the received signal from the neighboring base stations, since the reference signals used to this measurement are affected by a relatively large Doppler shift. The service base station, which is based on these measures for the choice of the new target cell for a change of cell or "Handover", will not be able to make the right decision to change the assignment cell 5 at the right time and the quality of service may be degraded. This can result in a communication break more or less long. The table in FIG. 1 shows some examples of Doppler shift, where c is the speed of light, y is the speed of the mobile user and the angle between the direction of the velocity vector of the mobile equipment and the mobile equipment axis-base serving cell with the following assumptions: - A width of 100 km between two cells, - a downlink frequency fDL or frequency of the forward link, also known as the Anglo-Saxon "downlink" and "F rwa rd Link", 2182 MHz, in the frequency band 2170-2185 MHz, - a rising frequency fuL or return link frequency, also known by the abbreviation "Uplink" and "Reverse Link" Of 1992.5 MHz, in the band 1980-1995 MHz, which leads to different values for fD1max and fD2max. In the document entitled "Analytical Link Performance Evaluation of LTE Downlink with Carrier Frequency Offset" by QI Wang and Markus Rupp, ASILOMAR 2011, it is shown that a carrier frequency offset of 1.5 KHz, or 10% of the value of the The inter-subcarrier space provided in LTE can reduce the signal-to-noise plus interference ratio, or SINR, by more than 30 dB.The power received from the serving base station or base station neighboring and measured at the level of a mobile user may therefore be inaccurate if the Doppler shift or spread relative to the serving cell is not corrected, which justifies the need to find new solutions. Frequency shift effects but does not offer a solution to pre-compensate the Doppler effect EP 2360967 discloses a method in which the uplink Doppler shift compensation setpoint UL / downlink DL is calculated during communication by knowing the position and speed of the mobile user and the position of the serving base station. The cell change is managed by a method which calculates, from the position of the mobile user, the position of the different stations in the vicinity, and a propagation model, the power that should theoretically be received by the mobile user from neighboring cells. The measurement ratio thus calculated is sent to the base station in place of the measurement report made by the mobile user's battery on the downlink radio signal. The solution described is based on an estimate of the level of signal received from one or more neighboring cells using a database of base stations and position information provided by a GPS location device, or satellite, and a propagation model (for example, propagation in free space). The estimated signal level is not representative of the reality and in particular does not take into account environmental phenomena, such as signal masking by obstacles, multipath, etc. It is known to use downlink transmitted Cell-Specific Reference Signal (CRS) signals (from the eNB base station to the mobile unit UE) to LTE for measurements on neighboring cells (and / or serving cell), on a different frequency or on the same frequency as that of the serving cell. In the remainder of the description, a "neighboring basic cell" to the serving cell is a base cell which is in the vicinity of the serving base cell in the sense known to those skilled in the art. technical. The serving base cell knows the cells in its near or far neighborhood and before the Handover procedure, it can send a mobile user UE a list indicating the neighboring cells, which simplifies the handover procedure, although this is not necessarily necessary. The measurements made by the mobile user are used for the Handover decision made by the serving station, 5 hence the interest for the serving base station to know his neighbors well. CRS stands for "cell or base station specific reference signals". The letters "UE" denote, in the context of the present invention, for example an equipment that is mounted on a mobile support or in English "User Equipment" and which also represents by misuse of the mobile user. In the context of the description, the mobile equipment moves at a very high speed, higher or close to the speed value tolerated by the LTE standard in the frequency band considered.
    [0003] In a similar manner, the acronym eNB (eNodeB) denotes a base station. The uplink means a communication of the mobile equipment to the base station, and the downlink a communication from the base station to the mobile equipment at the edge of the aircraft or on the outside of the aircraft.
    [0004] The word "Doppler" includes in this description "Doppler spread" or "Doppler shift". In general, by Doppler effect is meant the frequency offset of a wave (mechanical, acoustic, electromagnetic, etc.) between the measurement on transmission and the measurement on reception, when the distance between a transmitter and a receiver varies over time. In telecommunication, it is considered that signals traveling along different paths or paths may have different Doppler shifts, corresponding to rates of change in phase. Doppler spread is represented by the maximum difference between the frequencies generated by the Doppler effect. In other words, the (maximum) difference in Doppler shifts between the different signal components that contribute to a single path is known as Doppler spread. In the case of an air-ground channel A2G, there is generally only one main path, because an aircraft is in direct view or LOS (Line-Of-Sight) of the base station, and this is the offset Doppler predominating. The object of the present invention is a method and system for determining a power value of a signal received from each of the neighboring cells to a serving cell while remaining connected thereto. The implementation of the method is based in particular on the use of downlink transmitted CRS signals from the eNB base station to the mobile equipment, with adequate Doppler compensation to enable the protocol stack of a mobile equipment to measure the level of the signal received from each neighboring cell with optimal accuracy. The invention relates to a method for estimating the power of a cell in a communication system comprising at least one serving station and one or more neighboring stations eNB, one or more mobile communication units UE, a moving communication unit. with a high speed and being in communication at a time with the service station, comprising at least the following steps: - At the output of the receiver of the communication unit, the received signal r1, R1 is composed of a signal r (eNB1) transmitted by a serving cell eNB1 and a signal r (eNB2) transmitted by at least one neighboring cell eNB2, - transmitting the signal r1, R1 to a Doppler compensation unit which applies a corresponding compensation setpoint value at the Doppler shift on the signal transmitted by the serving cell, a second signal r2, R2 from the compensation unit (602) consists of a first compensated signal r (eNB1) comp, and the signal r (eNB2) transmitted by the at least one neighboring cell eNB2, - transmitting the second signal r2, R2 to: o A first signal combining module (651) which receives the second signal r2, R2 and a first sequence c * (eNB1 ), A specific second signal combining module (652) which receives the second signal r2, R2, and a second sequence c * (eNB2), 3038201 6 C * (eNB1), of reference signals specific to the serving cell. ) comp, C * (eNB2) comp of specific reference signals compensated by a Doppler shift value AD corresponding to the difference between the neighboring cell and the serving cell, - Determining a first power value Pi (eNB1) corresponding to the first signal M1 (r2, c * (eNBi)), M1 (R2, C * (eNBi)) from the first signal combining module corresponding to the serving base cell, - determining a second power value P2 (eNB2) ) corresponding to the second signal M2 (r2, c * (eNB2) comp), M2 (R2, 15 C * (eNB2) comp) from the uxth signal combining module corresponding to at least one neighboring cell, - Comparing the first power value to at least the second power value and deciding a Handover step the neighboring cell chosen for a Handover procedure.
    [0005] According to an alternative embodiment, the first signal combining module and the second signal combining module are a correlator and / or a signal multiplier. The step of comparing the values of the powers is, for example, transmitted to a base station which decides whether or not to trigger the handover. According to an alternative embodiment, the specific reference signals for a neighboring cell are generated and the Doppler effect is corrected on these signals at the protocol stack of the mobile equipment. For example, the specific reference signals 30 are generated for a neighboring cell, the Doppler effect is corrected at a signal generation unit CRS external to the protocol stack of the mobile unit, and 3038201 can be stored. the signal from the external generation unit when there is a signal from the protocol stack. To determine the Doppler compensation setpoints for a serving cell S with which the UE communicates the method executes, for example, the following steps: The instructions to be applied in UL and DL are denoted respectively -f of L, s and fdDL, s, o The Doppler shifts experienced by the uplink signal and the downstream LvF, te, respectively are 10 o fdlu, s =. cos (a) and fdDL, s D cos (a), the instructions -fdui ,, s and -fdpi ,, s to compensate for these offsets. The frequency offset to be applied to the CRS signals before measuring the power of a neighboring cell is determined, for example, as follows: The Doppler shift with respect to the neighboring cell denoted fdDL, N is calculated as follows: - fdDL, N = p -DL, N. cos (a '), where a' is the angle between the unit vector f3 and the direction of the unit vector director of the neighboring UE-cell axis N, denoted u ', 20 - fd -DL, N_more_probable = v.FDL_cell_N_more_probable .cos (more_cell_cell), where a_more_probable cell is the angle between the unit vector -1-3 and the direction of the unit vector direction of the nearest UE-neighbor cell axis N most likely to be used for handover in the direction of displacement having a better received signal or alternatively the maximum relative Doppler relative to the serving cell, fdDL, N = v.FDL, where a far cell in the direction of direction is fixed as the target cell for the HO. visible or measurable displacement.
    [0006] 3038201 8 A set value can be applied for the correction of the frequency offset to the CRS signals of a cell adjacent to the serving cell: Before the correction of the serving cell is made: V-FDL + fdDL, N = c - 5 After correction of the serving cell is made: -fdDL, s + fdDL, N = -v-FDL cos (a) +1 '"FL .cos (a) The calculation of the power takes, for example, count the signal r2, R2 received shifted temporally over the duration of a symbol in a time interval defined by the number of samples by cyclic prefix 10 and the number of samples per useful symbol. According to an alternative embodiment, the calculation of the value of the power uses a correlation of the signal received in time domain with a model generated from a CRS sequence known in advance by the mobile equipment receiver UE, and generated locally. by the receiver 15 of a mobile equipment, with a specific LTE OFDM structure containing only drivers without user data, and with the formula: cos (a) 'eNB2 = max z- / V FFT + SCp NL2 tn + CeNB2, comp [nn = 0 1 x - IN r 2 f) The calculation of the power can be performed after an FFT Fourier transform operation on the receiver side of the equipment, thanks to the following equation: 2 PeNB 2 = 1 N Rs -1 R2 [n]. C eNB 2, comp [n N RS where PeNB 2 is the estimated power, R2 [n] is the received signal (after an FFT Fourier transform operation on the receiver side) and the recovery of the positions relating to the drivers and Ce * NB2, ', np [n] are the conjugate complex values of the CRS sequence, which has been locally regenerated and compensated for by the UE as a function of relative Doppler, and which corresponds to the non-conjugated drivers transmitted Com2 [n] by the base station. The Doppler shifts to be applied will be calculated using position information given by a GPS system. According to an alternative embodiment, the signals used in the system comprise synchronization sequences PSS / SSS and in that the Doppler shifts to be applied are deduced from these signals PSS / SSS.
    [0007] The method according to the invention can be implemented in a communication system using LTE 3GPP technologies. The invention also relates to a system for measuring the power of a serving cell in a communication system comprising at least one or more eNB stations, one or more mobile communication units, a communication unit moving with a speed a service station and / or a neighboring station characterized in that the mobile unit UE comprises at least the following elements: - an RF transmitter / receiver, 20 - a transmission Doppler compensation unit - UpLink channel (UL) from the UE to the serving cell: a Doppler compensation unit in reception - DownLink channel (DL) - from the serving cell to the UE, - A mobility management unit adapted to determine the values of the set instructions. Doppler shift, - A CRS signal generation module for the serving cell and for one (or more) neighboring cell (s), - A unit for estimating the power of an adaptive cell to receive a first signal corresponding to a mixed signal comprising the received signal at the receiver of the mobile unit corrected for the Doppler effect cell portion and a CRS signal sequence and at least a second signal corresponding to the mixing of the signal received by the receiver of the mobile unit mixed with a second sequence of signals CRS corrected by the Doppler effect 5 for (at least) a neighboring cell. The system may comprise an external module for generating compensated CRS signals, a mixer receiving the measured signal comprising the compensated signal of the serving cell and the uncompensated signal of the neighboring cell, and a signal sequence CRS generated by said module. external for the neighboring cell. The system may also include a GPS device providing the position, and / or coordinates, and / or speed information of the mobile equipment and in relation to the mobile management unit to determine the values of the instructions to be applied.
    [0008] The system comprises a database containing information relating to the deployment of the communication network and in connection with the mobility management unit. Other features and advantages of the present invention will appear better on reading the following description of examples given by way of illustration and not limiting, appended to the figures which represent: FIG. 1, an example of a table of Doppler shifts FIGS. 2 and 3, a representation of the Doppler shift and its correction; FIG. 4, a representation of the passage from a first communication cell to a second communication cell; FIG. Notations used for the calculation of Doppler compensation, FIG. 6A, a first variant embodiment of the method according to the invention in the time domain, FIG. 6B, another variant in the time domain and FIG. frequency domain, FIGS. 7 to 10, various examples of protocol stack, FIG. 11, a representation of message exchanges, and FIG. 12A. a second embodiment in the time domain, Figure 12B another variant in the time domain 5 and Figure 12C a second variant in the frequency domain. FIG. 2 represents the in-flight displacement for an aircraft, as well as the curve Doppler shift I, curve II, with respect to two eNBA base stations, eNBB, as a function of the position of a mobile user UE. taking as simulation parameters: the path of the aircraft 10 with direction and direction of movement, the mobile user UE moving at a speed of 1200 km / h, at 10 km altitude, a carrier frequency of 2 GHz, an inter-site distance of 100 km (ie Inter-Site Distance or ISD). This representation is not restrictive and highlights the value of Doppler and the sign change as moving equipment moves to a base station and moves away from a base station. Figure 3 schematizes the correction of the Doppler shift by a mobile user UE which corrects the Doppler shift from the station eNBB, curve II. The correction takes into account the following simulation parameters: a mobile user UE lying in an airplane or outside and moving at a speed of 1200 km / h, at 10 km altitude, at a carrier frequency of 2 GHz and at an inter-site distance of 100 km (ie Inter-Site Distance or ISD). It is noted that the Doppler shift with respect to the eNBA station has increased and that, if the Doppler shift is compensated with respect to the eNBB base station (to be able to communicate with eNBB), the measurement of the eNBA station will be inaccurate and will affect the HandOver. If the sum of the signals received from the eNBB base station and the eNBA base station is compensated for the purpose of compensating for the signal received from the eNBB base station, the offset from the eNBA station can be increased as will be described later in the description.
    [0009] FIG. 4 schematizes the passage of an aircraft with one or more UE mobile users located in an aircraft 33 between a first serving cell with the two communication and measurement aspects, 31 and a potential target cell with a single aspect, measuring only, 32. The UE measures and communicates with the serving cell which therefore represents a mobile network access point and, at the same time, the UE measures the potential target cell. FIG. 5 illustrates an example of notations used for the calculation of the Doppler compensation, with: - v: the module of the velocity vector of the UE given by the GPS information, for example, - a: the angle between the direction displacement of the EU, materialized by the unit vector; and the direction of the unit vector director of the mobile equipment axis UE-serving cell S, noted. This angle is calculated from the position of the mobile equipment (eg GPS information) and the serving eNB station (eg from a database containing information on the serving station eNB and / or the number of the serving cell provided by the UE LTE stack, for example), the angle between the moving direction of the mobile equipment, materialized by the unit vector -21 and the direction of the unit vector director of the device. This equipment is based on the position of the mobile equipment (eg GPS information) and the potentially target eNB (eg from a database of base stations). and / or the number of the potentially target neighbor cell provided by the UE LTE stack, for example), -: carrier frequency used in UL, - FAL: carrier frequency used in DL.
    [0010] Without departing from the scope of the invention, one can have a three-dimensional environment or 3D and the neighboring cell can be located after the base station serving, before or next. Before detailing examples of implementation of the process 5 according to the invention, some reminders on the CRS signals are given. CRS signals are part of a mechanism already existing in the LTE standard. Cell-specific Reference Signals (CRS) are normally used to allow mobile equipment to measure cells of different frequencies or cells that use the same frequency band as the serving cell. Technical Specification TS ("Technical Specification") 3GPP 36.211 provides a graphical representation of CRS signals. This same technical specification, TS, details the calculation of CRS signals (15 in section 6.10.1 of 3GPP TS 36.211) from an initial sequence Cinit with the formula: kinit = z ~ n5 + 1) + 1 + 1 ) - (2 N + 1) + 2 + Ncp We see that this initial sequence is therefore dependent on certain parameters such as: 1) They = number of the time slot or slot in the radio frame; 2) I = number of the OFDM symbol in the slot; 3) Ncp = 1 for the normal cyclic prefix and 0 for the extended cyclic prefix; 4) / Vcello or the physical identity of the cell, knowing that in total one can have up to 504 physical cellular identifiers (and that at the system architecture level there are other ways that can identify a unique way any cell). The initial sequence used to generate the pilot sequence is therefore dependent on the physical cellular identifier. Each cell (among the 504 physical identities) therefore uses different driver sequences that can uniquely differentiate any cell.
    [0011] The calculation detail of an initial sequence is given, for example, in section 7.2 of document referenced TS 36.211. The pseudo-random generation sequences are defined by a Gold sequence known to those skilled in the art of length 31. The sequence obtained at the output c (n) is of length MPN where n = pN -1 and is defined by: c (n) = (xi (n + Nc) + x, (n + Nc)) mod2 xi (n + 31) = (n + 3) + (n)) mod2 x2 (n + 31) = (x2 ( n + 3) + x, (n + 2) + x2 (n + 1) + x, (n)) mod2 where ATc = 1600 and where the first m-sequence x1 is initialized with x1 (0) = 1, x1 (n) = 0, n = 1,2, ..., 30. Initialization of the second m-sequence. X2 is denoted by wax = E30ox20) - 2 .... with the dependent value of the application of the sequence. In other words, the sequence c (n) is obtained from the sequences x1 and x2, or the sequence x1 is obtained from an initialization with the values x1 (0) ... x1 (30) and a iterative computation formula for values from xi (31) and the x2 sequence is obtained from an initialization x2 (0) .. x2 (30) and an iterative computation formula for the 15 values from the value x2 (31). The values x2 (0). X2 (30) correspond to a binary transcription (values of 0 and 1) of the integer value described above. A potential implementation of computation of the scrambling code c (n) with a shift register method is known to those skilled in the art.
    [0012] Gold sequences can be used to synchronize or differentiate between different transmission sources. The sequence c (n) is therefore used for the calculation of the value of the CRS signals and is represented by a single pseudo-random sequence per cell, with each time dependent sequence value in the time slot defined by a symbol in a slot (we have 6, 7 or 3 symbols per slot depending on the configuration: extended cyclic prefix, normal cyclic prefix, or MBSFN abbreviated Multicast-Broadcast Single-Frequency) and in the domain frame 3038201 15, and in the frequency slot defined by a frequency-domain subcarrier described in the TS 36.211 standard. The unique combination of coordinates in the time domain (beginning and end of an LTE symbol) and in the frequency domain (beginning and end of a subcarrier) indicates a resource element (RE). ) unique in the time-frequency grid. Each resource element has a useful data transmission or driver transmission function (eg CRS or other), and several resource elements can be grouped together in a resource block or resource block RB. because a resource block RB is defined by a set of twelve frequency domain sub-carriers and a time domain slot (to simplify the allocation of resources for the payload which is normally done by two RB resource blocks at a time). The sequence may serve: 1) to UE mobile equipment (possibly) to synchronize in time and / or frequency, 2) (mainly) to distinguish and measure two different cells (e.g. with different physical identifiers). The reference signal sequence ri, n (m) is therefore defined by: 1 20 rins (m) = r- (1- 2 1 c (2m)) + j (1 2 - c (2m + 1)), m = -1 where ns is the slot number in a radio frame and / is the OFDM symbol number in the slot, or the random generation sequence c (i) is defined in section 7.2 of the aforementioned document TS 36.211. The pseudo-random sequence generator will thus be initialized with: c, '' 21 '' - (7 + 0 + 2 + - + 2 + R + 0 + 2 + Nor, at the start of each OFDM symbol and where the values of the Alcp are: 1 for normal CP NcP 0 for extended CP 3038201 16 The reference signal sequence ri ,,, (m) will be mapped to complex value modulation symbols al "/ used as reference symbols for the antenna port p in slot n, according to the following formula: ## EQU1 ## where k = 6m + (12 + vsh.) mod6 1 0, Nspyl-mb 3 if p E {0,1} 1 if p E {2,3} m = 0,1, ..., 2. NR% -1 ml = m NRmBax, DL NRDBL The variables y and Vshift define the position in the frequency domain for different reference signals where y is given by: 0 if p = 0 and / = 0 3 if p = 0 and / # 0 3 if p = 1 and / = 0 v = 0 if p = 1 and / 0 3 (ns mod 2) if p = 2 3 + 3 (ns mod2) if p = 3 io The specific frequency shift CRS is given by VshIft = mod6. ments RE resources are referenced by the letters (k, i). The positions used for transmission of the reference signal on each antenna port in one slot can not be used for another transmission on another antenna port, i.e., no transmission is carried out. of data on the port of an antenna if on another antenna one uses the same RE to transmit pilot signals. Sections 6.10.1.1 and 6.10.1.2 of the aforementioned document define the sequence and the mapping to be used for unicast type networks (usual use of an LTE network).
    [0013] In a similar manner, the sections 6.10.2.1 and 6.10.2.2 define the generation of the sequence and the mapping between the pilot signals and the resource elements RE for the multimedia broadcasting services known by the abbreviation " MBMS "(Multimedia Broadcast Multicast 5 Service) or MBSFN networks (Multicast-Broadcast Single-Frequency Network). RRC messages used to retrieve or transmit information are known to those skilled in the art and described in this same document.
    [0014] The `rrcConnectionReconfiguration 'message is a specific 3GPP message sent on the dedicated DCCH logical channel for control messages, downlink (DL). This message contains: A) configuration information sent through the message `measConfig 'which contains for example cell identifiers to be measured (in IE information element` MeasObjectEUTRA'), or criteria to trigger a report for event or periodic measurement (in the information element IE ReportConfigEUTRA '), B) information concerning the Handover to a target cell through a `mobilityControlInfo' message which contains information of the type 'PhysCellld' with the identifier target cell physics or `CarrierFreqEUTRA 'with the carrier frequency of the target cell normally expressed as a value of type ARFCN. The `measurementReporr 'message, and the` rrcConnectionReconfigurationComplete' message, are specific 3GPP messages sent on the dedicated DCCH logical channel for uplink (UL) control messages. In the `measurementReport 'message there are measurement reports: A) of the serving cell, eg messages as the result of the power measurement` rsrpResult which contains the measured value 30 `RSRP-Range', or the result of the measure expresses as a service quality report `rsrqResult which contains the value of the measure 3038201 18` RSRQ-Range 'and potentially also an identifier of the measure `Measld', and / or B) of the target cell, eg elements of similar information as `RSRP-Range 'and` RSRQ-Range' but also the physical identifier of the measured target cell, expressed by the IE The message `mcConnectionReconfigurationComplete 'represents a confirmation that the message` rrcConnectionReconfiguration' has been well done. The information elements IE (or 'Information Elements' in English) and the 10 configuration, measurement and report messages are described in detail in the document TS 36.331. The logical channels and the LTE system architecture are described in the referenced specification 3GPP 36.300. The known CRS sequence is transmitted on the entire cell. The UE uses the measurements made on CRS reference signals to estimate the level of the received signal thus allowing, in stand-by mode (or in connected mode), to select (or assist the serving cell in the purpose of selecting) the best cell (neighbor). FIG. 6A represents a first variant embodiment for a wireless communication system comprising a mobile equipment UE 20 located in the aircraft 33 and several base stations, in this figure only are represented for the sake of simplification, the service station eNB1 to which is connected the mobile equipment at a given time before the handover and an eNB2 base station which will ultimately be elected by the handover procedure in the given example. An eNB station may have an architecture such as that described in FIG. 7 (which corresponds to a user plane or "user plane") and in FIG. 8 (which corresponds to a control plane or "control plane") . Each base station provides wireless communications in a corresponding cell or in a plurality of corresponding sectors. A base station generates a sequence of 30 pilot signals (or potentially more than one sequence, one per sector) that may be received by the mobile equipment. In order to determine whether the connection must be with a cell associated with a base station, the mobile equipment will look at the relative intensities of the pilot signals transmitted by the different base stations. In general, these intensities measured by the mobile equipment are used at the base station in order to determine whether or not the mobile should change cell (handover procedure) and to select the best cell under the best conditions, eg the cell for which the power is maximum. To correctly determine the power level of a signal, the mobile equipment will have to correct the Doppler effect CRS signals received, the mobile 10 assists the base station for the decision of a possible handover. FIG. 6A shows an exemplary architecture for the mobile equipment UE, and WiFi layers used for equipment in the aircraft, and equipment that represents the end user 64 (eg that uses the same technology used by relaying equipment). For the sake of simplicity, the elements constituting a base station or a neighboring station will not be detailed because they are known to those skilled in the art. If UL is communicated with the serving station eNB1, it will be done through the blocks 614 (IP layer UE), 613 (L2 UE), 612 (L1 UE) 20 to communicate user data from the mobile user to the IP network or blocks 616 and optionally 615 (L3 UE which includes the RRC and NAS protocols), 613 (L2 UE), 612 (L1 UE) for communicating information for the serving station eNB1 to control the communication, the uplink compensation block 603, the DAC, the antennas 1001, 1002 (FIG. 7, FIG. 8), the propagation channel, the antennas of the service station eNB1, the layer L1 of the service station, the L2 layer of the serving station (for Figures 7 and 8), the L3 layer to control communication (for Figure 8), following communication principles known to those skilled in the art.
    [0015] If DL is communicated with the service station eNB1, it will be done through the layers L3 and L2 of the service station eNB1, the layer L1 of the service station, the antennas 1001, 1002 (FIG. 8) of the serving station eNB1, the propagation channel, the antennas of a UE, the CAN, the downstream compensation block 602, the layer 612 (L1 UE), the layer 613 (L2 UE ) to block 616 and optionally block 615 (L3 UE which includes RRC and NAS protocols) to control communication or up to layer 614 (IP layer) to communicate user data from the IP network to the network. mobile user, following communication principles known to those skilled in the art.
    [0016] Without departing from the scope of the invention, it is possible to have an LTE transmission instead of WiFi at the edge of the aircraft. In this case, instead of using an access point (in English "Access Point" or AP) WiFi, 63 can be used equivalent equipment LTE as for example a femto-cell LTE, acting as a station basic low power.
    [0017] Without departing from the scope of the invention, it is also possible to have a UMTS transmission instead of WiFi at the edge of the aircraft. In this case, instead of using an access point (in English "Access Point" or AP) WiFi (63) can be used a UMTS equivalent equipment such as femto-cell 3G or HSUPA / HSDPA, acting as a base station 20 of low power, terms known to those skilled in the art. The method is implemented in a UE mobile equipment adapted to the high-speed mobility conditions and which comprises, for example, the elements described below in connection with FIG. 6A. In the example given, the mobile equipment UE does not has no repeater.
    [0018] According to another embodiment, the mobile equipment UE may comprise a repetition module of the signal to the users on board or passengers not shown in the figure for reasons of simplification. The WiFi AP or the Femto-Cell can be integrated in the mobile equipment, contrary to the example of Figure 6A which represents it as a separate unit.
    [0019] An RF receiver / transmitter, 601b, 601a, comprises a receiving and / or transmitting antenna A1 and a transmitting and / or receiving antenna A2, a receiving channel which performs the filtering, baseband transposition and conversion. analogue / digital (CAN) of the received radio signal, a transmission channel which performs the digital-to-analog conversion (DAC), the transposition to the radio frequency, the amplification and the filtering of the signal 5 transmitted on the wireless link. The antennas are, for example, positioned vertically and horizontally (relative to the direction of flight of the aircraft) for different polarizations and the signal received (and transmitted) is obtained / combined on both antennas. A transmit Doppler compensation unit 603 - channel 10 UpLink (UL) - from the mobile equipment to the serving cell: pre-compensates the Doppler shift on the UL channel (direction EU to eNB); by shifting the frequency of the signal transmitted by the UE from the value of the setpoint -f of L, s of the serving cell; knowing that if the mobile approaches a base station, the Doppler is positive and if it moves away from it the Doppler is negative; the pre-compensation corresponds to a change of sign of the Doppler value in UL (in order eg to translate the transmitted signal in the good frequency band to facilitate reception at the base station level) for a transparent reception at the level of the base station, without further modification of the base station).
    [0020] A first example of Doppler compensation is as follows: the mobile equipment UE approaches a base station, the Doppler perceived relative to this station is positive and equal to a value + fc2: o Without pre-compensation at UE block level 603 (ie UE transmits on the fuL frequency), eNB receives the signal on fuL + fc2; O With pre-compensation at the UE block 603 (i.e. UE transmits on the frequency fuL- fD2) eNB receives the signal on fuL. The EU mobile equipment moves away from a base station, the Doppler perceived relative to this station is negative and equal to a value -fD2: o Without pre-compensation at the UE block 603 (ie UE 30 transmits on the frequency fuL), eNB receives the signal on fui-fD2; 3038201 22 o With pre-compensation at the UE block 603 (i.e. UE transmits on the frequency fuL + fD2) eNB receives the signal on fui. A Doppler compensation unit 602 - DownLink (DL) - from the serving cell to the UE: performs the compensation of the signal received by the UE from the setpoint value - fdDL, s of the serving cell ; knowing that if the mobile approaches a base station, the Doppler is positive and if it moves away from it, the Doppler is negative. The compensation corresponds to a change of sign of the Doppler value in DL (with the purpose eg of translating the received signal in the right frequency band to facilitate reception at a UE for a more transparent interpretation of the protocol stack). of an EU, and without further modification of the base station); An eNB database: 604. A second example of Doppler compensation is as follows: The mobile equipment UE approaches a base station, the perceived Doppler relative to this station is positive and equal to one. value + faith: o Without compensation at block UE 602, UE receives the signal on fDL + fDl (eNB transmitted on fDL); o With compensation at the UE block 602, UE receives the signal on fDL (eNB transmitted on fDL). The EU mobile equipment moves away from a base station, the Doppler perceived relative to this station is negative and equal to a value-faith: o Without compensation at the UE block 602, UE receives the signal on fDL- faith (eNB transmitted on fDL); O With compensation at the UE block 602, UE receives the signal on fDL (eNB transmitted on fDL). A mobility management unit: 605, performs the calculation of the instructions - fuL UL (to the serving cell and to the cell or several neighboring cells) and - f dDL DL (of the serving cell 30 and the cell or several neighboring cells) in real time. The mobility management unit is connected to: 3038201 23 - The eNB 604 database containing information relating to the deployment of the Air-Sol network (positions of the different eNBs, size of the cells, sectorization, etc.), - A satellite navigation device (eg a GPS system) or other location system, 607, providing the position, coordinates and possibly information with respect to the UE speed vector, updated in real time, - LTE stack, 608, which receives information allowing the calculation of different Doppler compensation instructions, among others: serving cell identifier, neighbor cell list, destination cell number (eg for HandOver command); the battery is for example compliant with 3GPP LTE specifications and normally configurable with the means provided by the standard. The system also includes the following elements: A cell-specific reference signal (CRS) specific local signal generation module: 609, A cell power estimation unit: 610, an L1 layer distributed between the elements: 612, 617, L2 layer (PDCP / RLC / MAC): 613, A layer (or more layers) that is used for data communication / IP: 614, L1 and L2 layers are common for the user plane portion (formed by the elements 612, 617, 613, 614) and the control plane portion (formed by the elements 612, 617, 613, 616, 615) of the LTE standard and its evolutions, a NAS layer: 615, an RRC layer: 616 with its reception components 616a Dec RRC, 616b transmission RRC Enr, a switch 63 Ethernet or WiFi (with the role of a repeater), represented 30 by the layers 670, 671, 672, the latter being connected to the unit 614 of the UE, q which routes the IP traffic from the UE LTE stack to the users connected to an on-board entertainment server, and, in the opposite direction, the IP traffic of the users to the LTE stack, An end user 64 (End- User) at the edge represented by the layers 660, 661, 662, which benefits from various services: internet, VolP, video streaming, video conference, etc. In the case where the block 605 receives from the PHY layer or directly calculates the offsets with respect to the synchronization references using the primary synchronization signals PSS and secondary SSS (in accordance with the standard TS 36.211), it is not necessary to have a database 604 and a positioning system 607. The received signals will be used to synchronize and the Doppler shift values to be applied will be deduced from these PSS / SSS signals. The mechanisms of exchange between the aforementioned blocks are known to those skilled in the art, particularly in the aforementioned TS specification.
    [0021] A neighboring service station or station includes, a L1 layer such as 612, a L2 layer as 613, a layer for IP data as 614. The cyclic prefix addition operations, CP or "add CP", 680, the P / S parallel-to-serial conversion, 681, the IFFT Fourier inverse transform 682, can be performed directly in block 609 as shown in FIG. 6A (or outside block 609). The compensation can be performed in block 609, before or after the Fourier transform. Without departing from the scope of the invention instead of CP one can simply do zero padding, one keeps a guard interval with zero samples of the same size as the size of the cyclic prefix. Fig. 6B shows the case where the P / S 690 parallel-serial conversion and Fourier IFFT 691 inverse transformation operations are performed directly in block 609 and a block carrying out cyclic prefix removal "CP Removal" 692 is arranged before mixer 651 and 652. If this block is used, the block "CP" of FIG. 6A which adds the cyclic prefix is no longer necessarily used - however it is still possible to use a block which is zero padding in its place. Figure 6C corresponds to an implementation in the frequency domain. The module 609 can operate directly in frequency, and a block 694 "CP r" = "CP Removal" block which removes the cyclic prefix and an "S / P" block 695 which performs a serial-parallel conversion (differ from P / S) before performing the Fourier transform by the FFT operation, 696, and the multiplication with the compensated signal generated by the module 609.
    [0022] FIGS. 7 and 8 describe the previously mentioned functionalities of an eNB station: that of the communication of the user data to (in DL) / since (in UL) the S1-U interface with the S-GW (see FIG. 7). ) and that of transmitting and relaying information intended to control the communication (see FIG. 8) in DL and in UL using the RRC layer of the eNB or the NAS layer of the mobility management entity MME (the last to through the S1-MME interface with the MME). In addition, an eNB may be connected to another eNB through the X2-U interface (the interface has not been shown in Figure 7 for the sake of simplification) for the transmission of user data (very Similar with S1-U) and through the X2-C interface (the interface known to those skilled in the art has not been shown in Figure 8 for simplification concerns) for the transmission of control information (very similar interface with S1-MME except the last layer of the S1-AP protocol which is replaced by X2-AP), following communication principles known to those skilled in the art. Figure 9 describes the protocol stack for the transfer of user data between an application server AS and the mobile equipment UE. In DL the signal passes through the layers of a P-GW from top to bottom: IP, GTP-U, UDP / IP, L2P-GW, L1P-GW, then goes back to the L1 S-GW, L2 S-GW, 30 UDP / IP, GTP-U and will be transmitted to the serving eNB and further to the UE through the L2 (PDCP, RLC, MAC) and L1 (PHY) layers of the base station 3038201. eNB, following communication principles known to those skilled in the art and described eg in TS 36.300. Very similarly, in UL the signal goes through the layers of a UE from top to bottom, goes up in the layers of an eNB by L1 (PHY), L2 (MAC, RLC, PDCP), and after 5 it will be transmitted to L1 S-GW, L2 S-GW, UDP / IP, GTP-U then will be transmitted to P-GW and further to the application server AS, following communication principles known to those skilled in the art and described in TS 36.300. Figure 10 depicts the protocol stack for the transfer of control information between the mobility management entity MME and the mobile equipment UE, or between the base station eNB and the mobile equipment UE. In DL the control information goes through the layers of an MME from the top down from the NAS layer, traversing the S1-AP, SCTP, IP, L2, L1 layers / protocols and then back up into the eNB which 15 seamlessly relays the NAS layer to the UE end-user, traversing the L3 (RRC), L2 (PDCP, RLC, MAC), L1 (PHY) layers, following communication principles known to humans of the trade and described eg in TS 36.300. Similarly, in DL the control information passes through the layers of an eNB station from top to bottom from the L3 layer (RRC) through the L2 (PDCP, RLC, MAC), L1 (PHY) layers. ), following communication principles known to those skilled in the art and described eg in TS 36.300. Figure 10 also describes the transfer of control messages by an eNB for the messages destined for the RRC layer (eNB function) and the NAS layer 25 (MME function), using the L1 (PHY) and L2 (MAC, RLC, PDCP) of an eNB, following communication principles known to those skilled in the art and described in the document TS 36.300. Blocks 662, 661, 660 (Fig. 6A) correspond to a protocol stack used at the end user level (e.g. laptop, tablet or laptop using e.g. WiFi if the repeater uses WiFi).
    [0023] The blocks 672, 671, 670 (FIG. 6A) correspond to a WiFi protocol stack which serves as a WiFi access point (AP) for the end users. The signals exchanged between the different elements will be described in relation with FIG. 6A. The receiver of the mobile equipment receives the signal from the service station eNB1 and the signals from one or more neighboring stations, in the example the neighboring station eNB2. At the output of the receiver 601b, the signal r1 is composed of the signal r (eNB1) transmitted by the serving cell eNB1 and of the signal r (eNB2) transmitted by the neighboring cell eNB2. r1 is transmitted to the Doppler compensation unit 602 which applies a compensation setpoint corresponding to a signal necessary to compensate (only) the signal of the serving cell. This compensation is necessary to enable the mobile to communicate (and in particular for the downstream channel to receive control information / data and useful data) with the (or from) the base station. The signal r2 from the Doppler compensation unit consists of the first compensated signal r (eNB1) comp and the signal r (eNB2) comp compensated with respect to the eNB1. This second signal r2 is transmitted in this example to the UE LTE protocol stack of the mobile equipment. It is transmitted to the physical layer 612 (and 617), to a first signal mixer 651 and to a second signal mixer 652. The signals r1 and r2 contain, for example, each of the drivers, the payload data and the data signal. control that can be targeted at multiple mobile devices and multiple users. Moreover, if several cells transmit at the same time on the same frequency band drivers or data (user or control), we will find the sum of these signals (with a potential frequency and time shift, and potentially with powers different) in the signals r1 and r2. In the example considered, there is at least one signal from the serving base station (eNB1) and a signal from the neighboring base station (eNB2).
    [0024] 3038201 28 It is possible to use different means, IFFT or FFT operations and functional components, with the objective of having a multiplication of type r2 xc * (time domain) or R2 x C * (frequency domain) that we can perform sample by sample or block by block.
    [0025] The first mixer (multiplication or correlation block) of signals 651 also receives a signal comprising a sequence c * (eNBi) (conjugate complex) obtained from a c (eNB1) sequence of CRS signals generated (locally) by mobile equipment for the serving cell according to a method known to those skilled in the art. At the output of this first mixer (multiplication or correlation) a signal composed of the mixture of signals M1 (r2, c * (eNB1)) is transmitted to the power estimation module in order to estimate the power P1 (eNB1) associated with the serving cell. The value of the power Pi (eNB1) is transmitted to the RRC layer of the mobile equipment to be inserted into a signal which will be transmitted to the lower layers and thereafter to the Doppler compensation unit 603 for transmission to the base station serving through the mobile transmitter. The second mixer (multiplication or correlation block) of signals 652 receives, on the one hand, the signal r2 and, on the other hand, a signal 20 comprising a sequence of signals CRS generated locally by the mobile equipment for the neighboring cell and compensated for. a Doppler shift value AD, provided by the mobility management unit. This offset value AD corresponds, for example, to the neighbor cell Doppler shift - serving cell. The signal c * (eNB2) comp comprising the compensated sequence of CRS signals (and after the operation "*" of complex conjugation) is mixed (multiplication or correlation) with the signal r2. The mixture M2 (r2, c * (eNB2) comp) is transmitted to the power estimation module 610 in order to estimate the power P2 (eNB2) associated with the neighboring cell. The value of the power P2 (eNB2) is transmitted to the RRC layer 30 of the mobile equipment to be inserted into a signal which will be transmitted to the lower layers and thereafter to the Doppler compensation unit 3038201 29 603 for transmission. to the serving base station through the uplink mobile transmitter. The signal containing the two power values P1, P2 is compensated in the uplink before being transmitted, for example to the base cell which will compare the power value P2 (eNB2) and the power value Pi (eNB1). ) to decide whether it is necessary to perform handover and also to choose the identifier of the next most appropriate cell. The base cell comprises the modules adapted to compare the different power values measured for different neighboring stations and decide on the best neighboring cell to be used to perform the handover. The various handover algorithms may be based on a simple comparison or on methods based on hysteresis techniques as described in document TS 36.331. For example, the serving base station may check for a certain time that the condition for performing the handover does not change. In addition, the configuration and reports of the mobile can be done periodically or in an event. The power values will be transmitted according to a mechanism described for example in FIG.
    [0026] In contrast to the possible implementations shown in FIGS. 6A and 6B, in FIG. 6C the second multiplexing or correlation block receives the signal R2 and a signal sequence CRS generated by the external module and compensated. The mixture M2 (R2, C * (eNB2) comp) is transmitted to the power estimation module 610. The power value P2 (eNB2) is calculated and sent to the RRC layer of the mobile. The Doppler compensation / correction setpoint for the uplink and downlink serving cell is obtained, for example, by using the mobile positioning information (eg GPS), 607, and from the positioning information of the mobile. the serving base station contained in the database. The mobility management unit will execute, for example, the following three steps. 3038201 30 1) Location step: calculation of geographical position / coordinates of the mobile and identification of the geographical position / coordinates of the serving cell. 2) Relative speed measurement step with respect to the serving station (in function: a of the time traveled between two or more consecutive positions, and positions of the base station and the position of the aircraft / train / platform of high speed), 3) Doppler compensation calculation step corresponding to the relative speed 2) (and it is necessary to update the calculation from time to time) for the transmission / reception frequencies. The CRS signals are created in the example given inside the LTE stack, taking into account the offset calculated outside the stack eg by the mobility management unit, which makes it possible to improve the accuracy of measuring the power of signals transmitted by a station and received by the mobile equipment. According to an alternative embodiment, the signals will be mixed after a correlation operation if the signal is not completely synchronized (eg if the time reference is not known by the sequence generation unit or by the calculation unit of power). The calculation of the setpoints is, for example, carried out in the manner described below: Calculation of the instructions to be applied for the serving cell: The Doppler compensation instructions to be applied in the UL-way, and in the DL-pathway, -fdDL, s, for the serving cell are calculated as follows: o The instructions to apply in UL and DL are noted -f L, s and -fdDL, respectively. The letter S is here used to designate the serving cell (or "Serving cell"), with which the mobile equipment communicates and which also serves to control communication by the serving station. O The Doppler shifts experienced by the up-and-down FD and L channel signal, respectively, v. cos (a) are: o fduc, s = v - (a) and fdDL, s = -. cos (a), cc The setpoints -fduL5 and -fdDL, s make it possible to compensate for these offsets, with the notations given in FIG. 5. The method according to the invention is based in particular on the calculation of the Doppler compensation to be applied to the CRS signals transmitted downward from the eNB station to a UE mobile equipment, in order to allow the protocol stack of the mobile equipment located in a first serving cell to best measure the received signal level from each neighboring cell , target cells candidates for handover, while remaining connected to the serving cell. The idea is to correct the position of the CRS signals as a function of the relative Doppler of the base station to be measured. Once the power measurement has been performed, the mobile equipment can send a very accurate measurement value to the serving base station which will decide whether or not to change the cell in a more optimal manner, based on real measurements and which take into account the effects of the communication channel under normal propagation conditions (eg without Doppler).
    [0027] The method will calculate the frequency offset to be applied to the CRS signals to measure the power of a neighboring cell in a downlink. CRS signals are transmitted continuously by a cell to the mobile equipment. It is thus possible for a mobile equipment UE to receive reference signals transmitted by several neighboring cells, at the same time and / or on the same frequency resources. The method according to the invention performs for example the steps described below. The Doppler shift relative to the neighboring DL cell (denoted fdDL, N) can be calculated as follows: ## EQU1 ## where a 'is the angle between the unit vector f, and the direction of the unit vector director of the neighboring UE-cell axis N, denoted u '(see FIG. 4), fdDL, N _more_probable = v.FDL_cell_N_more_probable .cos (a_cell_more_probable), or a_more_probable cell is the angle between the unit vector fi and the direction of the unit vector director of the nearest neighbor EU-cell axis N most likely neighboring cell (to be used for the handover eg in the direction of displacement eg by having a better received signal or alternatively the maximum relative Doppler relative to the serving cell), - fdDL, N = v "FDL, where a far cell is set as the target cell for the HO in the moving direction but always visible or measurable (and therefore the cos (a ') = 1).
    [0028] The letter N is here used to designate the neighboring cell (or "neighbor cell"). Note that no frequency compensation setpoint is applied in the uplink for the neighboring cell N before it is decided to perform the initial access (RACH) on the neighboring cell (eg during or after the HO procedure) . The uplink compensation is always made with respect to the serving station S (with which the mobile is communicating). In addition, downlink (DL), it is possible that the correction with respect to the serving cell does not occur at the same time as the neighboring cell. The set point to be applied to the CRS signals of a cell 25 adjacent to the serving cell in order to be able to correct the frequency offset is therefore: Before the correction of the deserter cell is made (eg by the blocks 605 and 602): + - FDL + fdDL, N. cos (a ') 3038201 33 - After correction of the serving cell is made (eg by blocks 605 and 602): -fclpios + fdDL, N = 12.F, DL .cos (a) + r ± L . cos (a '). The set value to be applied to the CRS signals for the downstream neighbor cell 5 is obtained, for example, by using the mobile positioning information (eg GPS), 607, and from the information contained in the database therein. including positioning information of the serving base station and the neighboring base station. The mobility management unit will execute, for example, the following four steps: 1) Step Location: calculation of geographical position / coordinates of the mobile, identification of the geographical position / coordinates of the serving cell, and identification of the geographical position / coordinates of the neighboring cell. 2) Relative speed measurement step with respect to the service station (depending on: a of the time traveled between two or more consecutive positions, and b of the positions of the serving base station and the position 20 of the aircraft (3) Relative speed measurement step with respect to the neighboring station (depending on: a of the time traveled between two or more consecutive positions, and 25 b of the positions of the neighboring base station and the position of the aircraft / train / high speed platform), 4) Doppler compensation calculation step corresponding to the relative velocities 3) and / or 2) (and it is necessary to update the calculation from time to time) for the frequencies of transmission / reception.
    [0029] The method according to the invention is not limited to one application for a single neighboring base station, since in the previous steps of step 3038201, step 1) up to step 4) the Doppler compensation can be calculated independently. for an unlimited number of neighboring cells. FIG. 11 is a diagram showing an example of message and information exchanges between the various elements of the system, in particular the serving base station, a neighboring base station and the mobile equipment. The mobile equipment UE performs Doppler pre-compensation 71 with respect to the first serving base station eNB1, the UE is then connected and transmits and receives data.
    [0030] The `rrcConnectionReconfiguration 'message 72 is a specific 3GPP message sent on the downlink (DL) DCCH channel (dedicated logical channel for control messages). This message contains: - configuration information sent through the `measConfig 'message which contains, for example, cell identifiers to be measured (in the IE MeasObjectEUTRA information element), or for example criteria for triggering a report in the information element IE ReportConfigEUTRA% - information about the Handover HO to a target cell through the message rmobilityControllnfo '(which contains information of the type PhysCellld' with the physical identifier of the target cell or `CarrierFreqEUTRA 'with the carrier frequency of the target cell normally expressed by a value of type ARFCN abbreviated Anglo-Saxon absolute radio-frequency channel number).
    [0031] The mobile equipment UE implements the method according to the invention based on the specific use of the CRS signals which allows the UE to correct the CRS signals as a function of the relative Doppler of the base station eNB2, of which several Examples are given for illustrative purposes in Figures 6A-6C and 12A-12C.
    [0032] The UE then prepares the identity measurement reports on the basis of rules defined in the standard. The UE then transmits a measurementReporr message, 75, to the serving base station which will take the decision of Handover 76, which transmits a request from Handover HO to the second base station eNB2. This second station performs an admission control 78, and transmits an acknowledgment message 79 to the first serving base station, eNB1. eNB1 then sends a message `mcConnectionReconfiguration '80 to the UE. The `measurementReport and` rrcConnectionReconfigurationComplete 'messages are specific 3GPP messages sent on the uplink (UL) channel DCCH (dedicated logical channel for control messages). In the `measurementReport 'message we find measurement reports: - of the serving cell, ie messages as the result of the power measurement` rsrpResult which contains the measurement value `IRSRP-Range', or the result of the measurement which expresses as a service quality report `rsrqResult which contains the value of the measure` RSRQ-Range 'and potentially also an identifier of the measure Weasld', and / or - of the target cell, ie similar pieces of information as RSRP-Range 'and RSRQ-Range' but also the physical identifier of the measured target cell, expressed by IE PhysCellld '. The `rrcConnectionReconfigurationComplete 'message means that the` mcConnectionReconfiguration' message has been successfully completed. The `mcConnectionReconfigurationComplete 'message will be used later - see message 91 sent as a response to message` `rrcConnectionReconfiguration' '80 and to validate the HO procedure (e.g. procedures or part of procedures between steps 81 and 90). The information elements IE (or 'Information Elements' in English) and the configuration, measurement and reporting messages are described in detail in TS 36.331. The logical channels and the LTE system architecture are described in TS 36.300.
    [0033] The UE disconnects, 81, from the first serving base station, then there is delivery of transit packets for the target eNB2, 82, with status transfer from the first serving base station and one sending data, 83, to the second base station eNB2. The second base station eNB2 queues the packets from the serving base station 84. The mobile equipment synchronizes 85 with respect to the second base station eNB2 and then reads the messages. the second station eNB2 86, then it will perform a pre-compensation 10 of the Doppler shift with respect to the second base station for the communication and measurement aspects. The UE transmits the RACH message, 88, to eNB2, which returns a timing advance command, 89. The UE reconnects to the eNB2 base station, 90, and transmits the message `rrcConnectionReconfigurationComplete 91, the UE is then connected to the second base station eNB2, and can transmit and receive data. The legend of the figure is as follows: UE = mobile equipment connected to the station eNB1, preparing a HandOver (HO) to the station eNB2, 20 eNB1 = eNodeB1, serving base station or serving cell or source cell , eNB2 = eNodeB2, Neighbor Neighbor Base Station or Target Neighbor Cell, UE, eNodeB, Evolved Packet Core (EPC), Mobility Management Entity (MME), Serving GateWay (S-GW), and Packet Data Network GateWay (P-GW) Or PDN-GW) are conventional terminologies and known (at least) in the 3GPP world, RACH = Random Access Channel, channel used by the UE during initial access (or during the HO procedure because in LTE one uses a Handover procedure of "Hard HandOver" type, that is to say, the transmission is cut off before reconnecting to a new cell).
    [0034] FIGS. 12A to 12C show a second variant of the method and the system for implementing it in which the sequence of CRS signals for at least one neighboring station will no longer be generated at the protocol stack but in a module from the mobile equipment external to the stack. In this variant embodiment, the elements identical to those described in FIG. 6A or 6B, 6C respectively bear the same references. With respect to FIG. 6A and 6B, 6C respectively, the system also includes: - an external generation module for the CRS signals: element 809; - an external unit for estimating the power of a cell: element 810; multiplexing or correlation block 820 receiving the measured signal comprising the compensated signal for the serving cell and the uncompensated signal of the neighboring cell, with a pilot signal sequence generated by the external CRS signal generation module for the cell neighbor. Figure 12A illustrates an example of time domain implementation such as Figure 6A. A set of FFT, S / P and CP removal blocks 850, 851, 852 are installed before the two mixers 651 and 652 on the signal path r2. An assembly 854, 855, IFFT, P / S and 856, CP is positioned before the mixer 820. Compensation can be performed in block 809, before or after the Fourier transform. Figure 12B illustrates the pendant of the system depicted in Figure 6B.
    [0035] A set of FFT, S / P and CP removal blocks, 860, 861, 862 are installed before the two mixers 651 and 652 on the signal path r2. An IFFT 863, P / S 864, CP 866 assembly is positioned before the mixer 820 and a CP Removal block 865 for the second mixer inlet. Figure 12C shows an exemplary implementation in the frequency domain. A set of blocks 870, FFT, 871, S / P and 872 CP removal is installed before the two mixers 651 and 652 on the signal path r2. A set 873, FFT, 874, S / P, 875 Removal CP is disposed before the mixer outside the protocol stack 608 on the signal path r2, in order to obtain its frequency domain equivalent, R2. The implementation of the method according to the invention for this "second" embodiment variant described in FIG. 12A includes, in addition to the steps that take place outside the protocol stack 608, the steps described in connection with FIG. FIG. 6A for the time implementation, FIG. 6C for the frequency implementation the additional steps described below.
    [0036] From the cellular identifiers (IDs) obtained from the information of the RRC layer (after decoding), eg information sent in DL by the serving base station, the mobility management module will determine the value of Doppler shift to apply. The neighboring cell information / IDs are transmitted to the CRS driver sequence generation module in order to generate the CRS signals for the neighboring stations, the CRS signals are compensated by a Doppler shift. The first multiplexing or signal correlation block 651 also receives a signal comprising a c (eNB1) or C (eNB1) sequence of CRS signals generated by the mobile equipment for the serving cell according to a method known to man. of career. At the output of this first mixer, a signal composed of the signal mixture Mi (r2, c * (eNE31)) or M1 (R2, C * (eNB1)) is transmitted to the power estimation module in order to estimate the power Pi (eNB1) associated with the serving cell. The value of the power Pi (eNB1) is transmitted to the RRC layer of the mobile equipment to be inserted into a signal which will be transmitted to the lower layers L2 (613), L1 (612) and thereafter to the unit. Doppler compensation 603 for transmission to the serving base station. The second signal multiplexing or correlation block 652 receives on the one hand the signal r2 or R2 and on the other hand a signal comprising a sequence obtained from a signal sequence CRS generated by the mobile equipment for the transmission. neighboring cell. The signal c * (eNB2) or C * (eNB2) is mixed with the signal r2 or R2. The mixture M2 (r2, c * (eNB2)) or M2 (R2, C * (eNB2)) is transmitted to the power estimation module in order to estimate the power P2 (eNB2) associated with the neighboring cell.
    [0037] The third multiplexing or correlation block receives the signal r2 and a signal sequence CRS generated by the external module and compensated. The mixture M3 (r2, c * (eNB2) comp) is transmitted to the power estimation module 810. The power value P3 (eNB2) is calculated and sent to the RRC layer of the mobile. In the context of FIGS. 12A to 12C, the Doppler effect is corrected at an external CRS signal generation unit to the protocol stack of the mobile unit, and the signal from the generation unit is retained. external when there is a signal from the protocol stack. Similarly, the RRC layer of the mobile can block or ignore e.g. the estimation P2 obtained from the PHY layer of the mobile.
    [0038] In contrast to the possible implementations shown in FIGS. 12A and 12B, in FIG. 12C the third multiplexing or correlation block receives the signal R2 and a signal sequence CRS generated by the external module and compensated. The mixture M3 (R2, C * (eNB2) comp) is transmitted to the power estimation module 810. The power value P3 (eNB2) is calculated and sent to the RRC layer of the mobile. The power estimate of the neighboring cell (or several cells) is sent in a RSRP (s) type information of the neighboring cell (or of several neighboring cells) or directly in an RRC MeasurementReport type message. will overwrite the message calculated by the LTE stack with a more accurate power measurement. Then, the information will be sent in a conventional RRC message to the serving base station and taking into account a "conventional" processing that is to say a passage through the layers PDCP, RLC, MAC, PHY and with proper encryption and coding.
    [0039] A first method for calculating the power value uses a correlation of the received signal (in time domain) with a model 3038201 generated from a CRS sequence known in advance by the receiver of the mobile equipment UE. This model is locally generated by the receiver of a UE and it has the specific OFDM structure e.g. LTE but it contains only drivers without useful user data. The power of a neighboring base station eNB2 can be estimated by the following equation: ( N-1 2 _Er, [n + d-ce * ,, '2> comp [n N n = 0 max On found the same estimated powerNB2 but unlike the second method described below the calculation is made from the signal r2 [n] 10 which is shifted temporally over the duration of a symbol, with r in the interval o <r _ <NFFT + N-1, NEP the number of samples per cyclic prefix and NF 'the number of samples per useful symbol OFDM Alternatively the locally generated model can be shifted * ,, 82 ,,,,, jn] on the signal Received r 2 [n] .N value represents the total number of samples that are used to make the estimate (eg it may correspond for example to a duration of a TTI 1 ms, a frame of 10 ms, 10 frames or 100 ms etc.), the notation "*" to the conjugate of a complex value, and the notation "" to the absolute value The signal or the model C e * NB 2, comp [n] is a signal in time, obtained after the IFFT calculation and the addition of a cyclic prefix, on the conjugate values of the CRS signals which have been placed at the right place and with the good values in the time-frequency grid of an OFDM transmission . These signals correspond to the CRS signals transmitted by the base station eNB2 which have been compensated by the mobile equipment for taking into account the relative Doppler shift and which corresponds to the non-conjugated complexes C eNB2 [n] As for the second method, the relative Doppler shift is not necessarily equal to that between the measured base station and the UE mobile equipment, because the mobile UE may introduce an additional offset due to an additional frequency offset, or because of a pre-correction of the Doppler with respect to another cell or with respect to the serving base station (eg in this case eNB1). For example, the compensation to be applied to the CRS signals before the correction of the deserter cell 5 is made (eg by blocks 605 and 602) is + fdDL, eNB2 =. Cos (a), and after the correction of serving cell is made (eg by the blocks 605 and 602) is -fd -DL, eNB1 + fdDL, eNB2 = cos (a) +33 .cos (a) if we consider a zero frequency offset between the base station and the EU mobile. This method uses the CP cyclic prefix which can improve the estimate of the power. rdn] is the received signal. We can write rdn] as a sum " I PeNB2 - C eNB 2,4D [n] + P. ,, eNB2 - S eNB 2, AD [n] + b [n] + i [n] where Pe'2 - CeNB2,4D [n] + ' 113s, eNB2 - S eNB2, AD [n] is the signal received from the base station eNB2 with the drivers CeNB2,4D [n] and the useful signal seNB24, [n], the noise b [n] 15 and the interference i [n], where i [n] can decompose into interference from another neighboring base station or serving base station (eg eNB1) or another system which uses an identical frequency band (or a near band that interferes with it) Another method is used after a FFT Fourier transform operation on the receiver side UE on the received signal composed of the signal from the serving cell and the receiver. one or more signals from the base station (s) (ie, in the DL path), possibly after the cyclic prefix has been removed The letter "C *" is associated with the variants implemented in the frequent domain iel, for example in Figure 6C or Figure 12C. The power of a neighboring base station eNB2 can be estimated by the following equation: 1 N le -1 R2 [n]. eNB2, comp [n NRS 0 PeNB2 3038201 42 where PeNB2 is the estimated power, R2 [n] is the received signal (after an FFT Fourier transform operation on the receiver side) and the recovery of the positions relating to the drivers and Ce * NB2 , ',,, [n] are the conjugate complex values of the CRS sequence, which has been locally regenerated and compensated by the UE as a function of relative Doppler, and which corresponds to the (non-conjugated) drivers transmitted by the base station C eNB2 [n]. The received signal R2 [n] can indeed be rewritten as -PeNB2 C eNB2, AD [n] + B [n] + I [n], where we find the real power of the base station eNB2 measured at the level of the UE mobile station, and 10 C eNB2,4D [n] pilots received from the eNB2 base station and affected by a relative Doppler AD, noise B [n] and interference / [n] which may be for example a sum of several signals such as the signal of the base station eNB1 (which can interfere with the measurement made on eNB2 if eg 1) the identifier of the cell eNB1 and eNB2 in modulo 6 have the same value or 15 Si 2) the eNB1 cell transmit data on RE "Resource Elements" or the eNB2 cell transmit pilots) or other signals from other base stations or other aircraft-specific systems, satellite systems or other commercial systems. using the same frequency band or frequency close to that measured by the EU. The value N Rs represents the number of pilots used to make the estimate (or the number of "reference signais"), the notation "*" to the conjugate of a complex value, and the notation "" to the absolute value.
    [0040] It is possible to find: First method, time domain 3038201 43 (max 0.1Q s 7.7 + NCP-IN E PeNB2 - C eNB2, ADPI + ri + IP, NR ,, s eNB2 - SeNB2, AD [n + b [n + i [n + z-]). ceNB2, comp [nf 2 N-1 II N-1 2 1 max -, 2_, VP, NB2 - C eNB2, AD [n rJ. C eNB2, comp [n 0 <r <N, T + Ncp-1 , n = 0 which is an estimate close to the power received from the neighboring base station eNB2. or else Second method, frequency domain 1 Nx -, L WPeNB 2 iu - NB2 DNA + B [n] + I [n]). C: 'B2,' mp [il NRS, NRa 2 -1 1, IPeNB2 - C eNB2, AD [n]. C NB2 comp [11 NRS, 0 which is an estimate close to the power received from the neighboring base station eNB2. If the locally generated CRS sequence is not normalized eg it is multiplied by a factor of to avoid overflow of the memory or a register, the two formulas become: First method 2 (fo7 "N-1 2 Zr2 p ## EQU1 ## where ## EQU1 ## and ## EQU1 ## Second method ## EQU1 ## where ## EQU1 ## where ## EQU1 ## and this [n] = - r_ ceNB2, comp [n] are the eNB2, comp eNB2, comp 11 has non-normalized sequences.
    [0041] According to an alternative embodiment, if the compensation in DL with respect to the serving cell is already made by the compensation unit, then the compensation is made for the compensation unit. the measurement is "Doppler shift", neighboring cell serving cell. If the compensation in DL with respect to the serving cell is not yet made by the compensation unit, the compensation made for the measurement is "Doppler shift", neighboring cell. The previously described method can be used for different versions or technologies that are provided by 3GPP (e.g. LTE, LTE Advanced) or IEEE (e.g. WiMax) technology. It can also be implemented in the case of the IEEE 802.11 standard or the Wifi standard, the standards around 10 UMTS, for physical layers based on 4G technologies such as OFDM (Orthogonal Frequency Division Modulation), the CDMA (Code division multiple access), or for the 5G technology (GFDM for Generalized Frequency Division Multiplexing, FBMC for multicarrier filter bank).
    [0042] At the mobility processing block or outside this block, there may be an intermediate step which uses the PSS / SSS signals to synchronize at the time level but also at the frequency level. This additional step can be used to identify the Doppler shifts per cell and therefore, in this situation the method does not necessarily need a database to be able to compensate Doppler shifts as a function of identifiers corresponding to one or more cells. neighbors. This new architecture without using a database is simpler but also it is autonomous. Instead of transmitting a list of identifiers, without departing from the scope of the invention, the serving base station can send a set of instructions to add a cell to a list or to delete a cell from the list, one by one. or several at a time, incrementally. The method can be implemented for FDD (Frequency Division Duplexing) or TDD (Time Division Duplexing) modes.
    [0043] The method can also be implemented for intra-frequency measurements, when the neighboring base station whose frequency is to be measured uses a carrier frequency different from that of the serving cell. The repeater embedded in the aircraft, can be a WiFi access point, an Ethernet router, an access point for a non-3GPP 5 technology such as WiMax, FlashLink, and other mobile technologies such as 3GPP technology , LTE, UMTS, HSDPA, CDMA. The method and the system according to the invention makes it possible in particular to accurately measure the power at reception of neighboring base stations, in the presence of very large Doppler shifts related to the mobility at a very high speed, thanks to the implementation of the signals. CRS with adequate Doppler compensation. The method can be used to measure multiple cells at the same time, since each CRS locally generated in the UE can be individually corrected with the Doppler shift of the corresponding cell. 15
    权利要求:
    Claims (18)
    [0001]
    CLAIMS1 - A method for estimating the power of a cell in a communication system comprising at least one serving station and one or more neighboring stations eNB, one or more mobile communication units, a communication unit moving with a high speed and being in communication at a time with the service station, comprising at least the following steps: - At the output of the receiver of the communication unit, the received signal r1, R1 is composed of a signal r (eNB1) transmitted by a serving cell eNB1 and a signal r (eNB2) transmitted by at least one neighboring cell eNB2, - transmitting the signal ri, R1 to a Doppler compensation unit which applies a compensation setpoint value corresponding to the Doppler shift on the signal transmitted by the serving cell, a second signal r2, R2 coming from the compensation unit (602) consists of a first compensated signal r (eNB1) comp and the signal r (eNB2) transmitted by the at least neighboring cell eNB2, - transmitting the second signal r2, R2 to: a first signal combining module (651) which receives the second signal r2, R2 and a first sequence c * (eNB1), C * (eNBi) ), a reference signal specific to the serving cell, o A second signal combining module (652) which receives the second signal r2, R2, and a second sequence c * (eNB2) comp, C * (eNB2) comp of reference signals specific to a cell or to a base station compensated by a Doppler shift value AD corresponding to the difference between the neighboring cell and the serving cell, - determining a first power value P1 (eNB1) corresponding to the first signal M1 (r2, c * (eNB1)), M1 (R2, C * (eNB1)) 3038201 47 from the first signal combining module corresponding to the serving base cell, - determining a second power value P2 (eNB2) corresponding to the second signal M2 (r2, c * (eNB2) comp), M2 (R2, C * (eNB 2) comp) from the second signal combining module corresponding to at least one neighboring cell, - comparing the first power value with at least the second power value and deciding a step of Handover the neighboring cell chosen for a procedure of Handover. 10
    [0002]
    2 - Process according to claim 1 characterized in that the first signal combining module and the second signal combining module are a correlator and / or a signal multiplier. 15
    [0003]
    3 - Method according to one of claims 1 or 2 characterized in that the step of comparing the values of the powers is transmitted to a base station which decides to trigger or not the Handover.
    [0004]
    4 - Method according to one of the preceding claims characterized in that one generates the specific reference signals for a neighboring cell and corrects the Doppler effect on these signals at the protocol stack of the mobile equipment.
    [0005]
    5 - Method according to one of the preceding claims characterized in that the specific reference signals are generated for a neighboring cell and the Doppler effect is corrected at a unit for generating specific external reference signals to the protocol stack of the mobile unit, and retaining the signal from the external generation unit when there is a signal from the protocol stack. 3038201 48
    [0006]
    6 - Method according to one of claims 1 to 5 characterized in that one determines the Doppler compensation instructions for a serving cell S with which the UE communicates by performing the following steps: o The instructions to be applied in UL and DL are denoted respectively -fduL, s and -fd -DL, S o The Doppler shifts experienced by the up-and-down signal, respectively, are: o v.FuL = v. FDL _ fdUL, S = - cos (a) and fdDL, s. cos (a), the setpoints -f du4s and -fdDL, s to compensate for these offsets.
    [0007]
    7 - Method according to one of the preceding claims characterized in that the frequency offset to be applied to the CRS signals before measuring the power of a neighboring cell is determined as follows: o Doppler shift compared to the neighboring cell denoted fdDL, N is calculated as follows: fdDL, N = - cos (a% where a 'is the angle between the unit vector i) and the direction of the unit vector director of the neighboring UE-cell axis N, denoted u ', 20 "DL, N_more_probable = v.FDL_cell_N_more_probable .cos (more likely_cell), where it is more likely that it is the angle between the unit vector e and the direction of the unit vector direction of the UE-axis. next cell N most likely to be used for the handover in the direction of displacement having a better received signal or alternatively the maximum relative Doppler relative to the serving cell, - fdDL, N =, where one fixes as target cell for the HO a e remote cell in the direction of visible or measurable displacement. 3038201 49
    [0008]
    8 - Process according to claim 7 characterized in that a set value is applied for the correction of the frequency offset to the CRS signals of a cell adjacent to the serving cell: Before the correction of the serving cell be done: V. FDL + fdDL, N =. COS (Cr) After correction of the serving cell is made: -f dDL, s + fc1DL, N = 'DL. cos (a) + 1-'2 "cos (a)
    [0009]
    9 - Method according to one of the preceding claims, characterized in that the calculation of the power takes into account the received signal r2, R2 shifted temporally over the duration of a symbol in a time interval defined by the number of samples per prefix cyclic and the number of samples per useful symbol.
    [0010]
    10 - Method according to one of the preceding claims, characterized in that the calculation of the value of the power uses a correlation of the signal received in time domain with a model generated from a CRS sequence known in advance by the receiver of the mobile equipment UE, and locally generated by the receiver of a mobile equipment, with a specific LTE OFDM structure containing only drivers without user data, and with the formula: N-1 1 * r r2 [nr J - C eNB2, comp [l 2 i V n = 0 P, B2 = max ^ + Nc, -1 where PNB, is the estimated power, r2 the signal received in the time domain, C e NB2, comp {111 conjugate complex values of the CRS sequence, which has been locally regenerated and compensated for by the mobile equipment as a function of relative Doppler and which corresponds to the unconjugated complexes cam [n]. 3038201 50
    [0011]
    11 - Method according to one of claims 1 to 9 characterized in that the calculation of the power is performed after an FFT Fourier transform operation on the receiver side of the equipment, thanks to the following equation: PeNB 2 - 1 N r 2 112 Lni -, e NB2, comp [n] 1v RS n = 0 where feNB2 is the estimated power, Rdn] is the signal received after an FFT Fourier transform operation on the receiver side and the recovery of the positions relating to the pilots and CeNB2,, o, np [n] are the conjugate complex values of the CRS sequence, which has been locally regenerated and compensated for by the UE as a function of relative Doppler, and which corresponds to the 10 non-conjugated pilots transmitted C eNB2. [n] by the base station.
    [0012]
    12 - Method according to one of the preceding claims characterized in that one calculates Doppler shifts to be applied using position information given by a GPS system. 15
    [0013]
    13 - Method according to one of claims 1 to 11 characterized in that the signals used in the system comprise synchronization sequences PSS / SSS and in that the Doppler shifts to be applied are deduced from these signals PSS / SSS. 20
    [0014]
    14 - Method according to one of claims 1 to 13 characterized in that it is implemented in a communication system using LTE 3GPP technologies. 25
    [0015]
    15 - System for measuring the power of a serving cell in a communication system comprising at least one or more eNB stations, one or more mobile communication units, a communication unit moving with a high speed, a station of And / or a neighboring station characterized in that the mobile unit UE comprises at least the following elements: - an RF transmitter / receiver, (601a, 601b), - a transmitter Doppler compensation unit - UpLink channel ( UL) - 5 from the UE to the serving cell (603), a receiving Doppler compensation unit (602) - DownLink channel (DL) from the serving cell to the UE, - A mobility management unit ( 605) adapted to determine the values of the Doppler shift setpoints; - a CRS signal generation module (609) for the serving cell and for one or more neighboring cells; power estimate a cell (610) adapted to receive a first signal corresponding to a mixed signal comprising the received signal at the receiver of the mobile unit corrected for the Doppler effect serving cell portion and a sequence of CRS signals and at least one second signal corresponding to the mixing of the signal received by the receiver of the mobile unit mixed with a second sequence of CRS signals corrected by the Doppler effect for (at least) a neighboring cell. 20
    [0016]
    16 - System according to claim 15 characterized in that it comprises a device comprising an external module for generating compensated CRS signals (809), a mixer (810) receiving the measured signal comprising the compensated signal of the serving cell and the unbalanced signal of the neighboring cell, and a signal sequence CRS generated by said external module for the neighboring cell.
    [0017]
    17 - System according to claim 15 characterized in that it comprises a GPS device providing the position, and / or coordinates, and / or speed information of the mobile equipment and in connection with the mobile management unit to determine the values of the instructions to apply. 3038201 52
    [0018]
    18 - System according to claim 17 characterized in that it comprises a database (604) containing information relating to the deployment of the communication network and in connection with the mobility management unit.
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    同族专利:
    公开号 | 公开日
    FR3038201B1|2018-07-13|
    EP3110203A1|2016-12-28|
    EP3110203B1|2020-08-26|
    ES2848831T3|2021-08-12|
    引用文献:
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    优先权:
    申请号 | 申请日 | 专利标题
    FR1501298A|FR3038201B1|2015-06-23|2015-06-23|METHOD AND SYSTEM FOR MEASURING POWER IN A COMMUNICATION SYSTEM|
    FR1501298|2015-06-23|FR1501298A| FR3038201B1|2015-06-23|2015-06-23|METHOD AND SYSTEM FOR MEASURING POWER IN A COMMUNICATION SYSTEM|
    EP16175670.5A| EP3110203B1|2015-06-23|2016-06-22|Measuring power in a communication device taking acount of doppler effect|
    ES16175670T| ES2848831T3|2015-06-23|2016-06-22|Power meter in a communication device that takes into account the Doppler effect|
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