FR2846508A1 - CDMA telecommunications network cell search optimization having correlation profile calculated code/spread spectrum/combined correlations peaks found/filtered and successive windows weighted variable coefficient - Google Patents

Abstract

The cell search optimization process calculates the correlation profile between the mobile terminal code and the spread spectrum. Different window profiles are combined, the correlation peaks found and filtered. The measures from two successive time windows are weighted by a variable coefficient.

Description

PROC D OF OPTIMIZING CELL SEARCH BY

  A MOBILE TERMINAL IN A CDMA NETWORK

TECHNICAL AREA

  The invention lies in the field of

  telecommunications and relates more specifically to a method for optimizing the search for cells in a mobile telecommunication network using CDMA radio access technology such as UMTS or cdma2000.

  The invention also relates to a dual-mode GSM / UMTS or single-mode UMTS mobile telephone comprising means for optimizing the search for cells in a telecommunication network in which each cell is identified by a spread code transmitted

by the network to said terminal.

STATE OF THE PRIOR ART

  In order to prepare for possible handovers, a terminal

  mobile during communication must identify each neighboring cell by its specific scrambling code.

  To this end, the technical specifications of the 3GPP (for Third Generation Partnership Project) define a cell search procedure "Cell Search" which consists of carrying out measurements, in particular of reception power, on the neighboring cells so as to switch to the cell which

  offers optimal communication quality.

  Recall that the UMTS network transmits to a terminal in a current cell a primary code and

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  a secondary synchronization code respectively via a primary channel PSCH (for Primary Synchronization Channel) and a secondary channel SSCH (for Secondary Synchronization Channel) to identify neighboring UMTS cells, as well as a

  beacon channel called CPICH (for Common Pilot Channel) to estimate the impulse response of the propagation channel. The primary code is transmitted over time slots (slot in English) and the secondary code is transmitted over time frames.

  The CPICH channel (for Common Pilot Channel) is composed of a predefined sequence of so-called pilot bits / symbols which are permanently transmitted on the cell. The bit rate of these bit / symbols is constant and equal to 30 kbps (kilo bits per second), or 15 ksps (kilo symbols per second). The CPICH 'channel is not

  associated with no transport channel.

  The UMTS cell search procedure

has three stages.

  The goal of the first step is to estimate the time of the start of the slot. This is achieved by correlating the signal received by the mobile terminal with the primary synchronization code (PSCH). As the frequency of the chips transmitted by the UMTS 25 base station is 3.84 MHz and the mobile oversamples, in general by a factor Nec = 4, the mobile must discriminate 3.84 106 * 4 * 10.10-3 / 15 = 10 240 temporal hypotheses. Correlations made with the primary code generate a profile with 10,240 30 values, the maximum value of which provides the instant of

start of niche sought.

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  The purpose of the second step is to identify the group of scrambling codes (64 possible hypotheses) to which the base station belongs and the frame synchronization instant (15 5 possible hypotheses). This is achieved by means of correlations with the secondary synchronization code. The third step aims to identify the scrambling code of the base station 10 (8 possible hypotheses), using

  correlations made on the CPICH channel.

  The preceding steps are implemented sequentially by the mobile terminal and their implementation assumes that the synchronization instant provided by a given step is not marred by an error due to an imprecision of the sampling clock of the mobile terminal or at a Doppler shift between the base station with which the mobile is in

  communication and that which the mobile must identify.

  Figure 1 schematically illustrates the structure of the PSCH and SSCH channels transmitted by a station

basic UMTS.

  The PSCH channel consists of a primary acp code of N chips, (generally N = 256). A chip 25 being a unit of information representing a symbol

  after application of the spread spectrum technique. The acp code repeats slot by slot and is identical for all cells in the network. The PSCH channel is used by the mobile terminal to detect the start of a slot.

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  The SSCH channel consists of a secondary code aC i, k containing 256 chips and o k = 0.1 ... 14 and S iE {1,2,3, ... 16}. This channel allows a terminal to detect the start of a frame in the physical channels 5 dedicated to a specific mobile terminal and in the common physical channels not dedicated to a specific mobile terminal, as well as the group to which

  belongs the scrambling code of the cell.

  Unlike the primary channel PSCH, the 10 codes used in the secondary channel can change from one slot to another according to a preset pattern.

chosen from 64 possible.

  The table in Figure 2 illustrates the relationship between the scrambling code groups and the associated patterns used to construct the codes

  that make up the SSCH secondary channel.

  FIG. 3 schematically illustrates the case where the mobile terminal applies the cell search procedure continuously, in standby mode 20 or during initial ignition. In this case, the procedure is initialized at an instant Ti and the processing is carried out for a short duration Dl corresponding to an integer number Nl of time slots (Slots in English). At the instant T2 25 corresponding to the end of the duration D1, the mobile terminal has the information necessary to assess the quality of the radio link. Since all the processing operations are carried out during the same time window 2, any drift of the sampling clock 30 has no effect on the performance of the synchronization procedure. These treatments

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  are repeated identically during a next time window of duration D2. When the cell search procedure is applied continuously, the information collected in one time window is not reused in the next time window.

  FIG. 4 schematically illustrates the case where the mobile applies the cell search procedure in connected mode discontinuously in bursts (burst in English terminology). Unlike the previous case, the mobile terminal uses several disjoint time windows 4, and combines the measurements collected in each of the windows 4, so as to satisfy a given performance criterion 15 depending in particular on the step of the

  cell search considered. Each window 4 allows calculation and storage in memory of a profile.

  The information and results of the processing operations of a given time window are reused in the processing operations carried out in the following time window. Under these conditions, in the presence of a Doppler shift and an imprecision of the mobile phone's sampling clock with respect to the base station that the mobile has to identify, the combination by

  simple addition of the correlation profiles relating to the different windows can lead to an overall failure of the procedure since the synchronization instants relating to the different windows are likely to be different.

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  FIG. 5 represents an example of a correlation profile obtained for a conventional search for

cell in a UMTS network.

  On the horizontal axis of the profile of FIG. 5 5, the instants of the start of a slot correspond to the maximum correlation between the signal received by the mobile terminal and the primary synchronization code (PSCH). The instants of the correlation maxima of the elementary profiles obtained in different time windows 10 can be different in

presence of clock drift.

  The problem therefore arises when the mobile is in connected GSM mode or in connected UMTS mode. In this case, the cell search procedure can only be applied discontinuously, unlike the cases where the mobile is in standby mode or during initial start-up. In this situation, the network can only provide the mobile with fairly short time intervals, the duration of which is less than the duration required to perform the correlations continuously. A solution described in French patent application NO 02 07617 filed by the applicant on June 20, 2002, recommends the application of first order linear filtering to the collection of correlation points relating to the different measurement windows to optimize the cell search procedure. Although this solution significantly improves the cell search procedure, it is however limited by the fact that filtering is

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  based on fixed weighting factors including the

  value is estimated and frozen once and for all.

  The object of the invention is to improve the technique described in the application cited above in order to compensate for the time slip of the radio samples when the cell search procedure is carried out discontinuously. This slip can be caused by the clock frequency error

  internal of the mobile or by the Doppler effect.

PRESENTATION OF THE INVENTION

  The invention recommends a method for optimizing the search for cells in a cellular telecommunications network in which each cell is identified by a spreading code.

  transmitted by the network to the terminal.

  To this end, partial correlations are calculated by the following steps: a) calculating, during a plurality of 20 predefined time windows, the correlation profile between a code generated by the mobile terminal and said spreading code, b) combining the profiles of the different windows, c) detecting the correlation peaks in the combined profiles, d) filtering the detected correlation peaks. According to the invention, the improved method 30 further comprises a step consisting in weighting the

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  measurements made in two time windows

  successive by a variable coefficient.

  In a first implementation variant of the method according to the invention, the weighting coefficient is defined as a function of the time difference which separates two consecutive windows o each profile

is calculated.

  In a second variant of implementation of. method according to the invention, the weighting coefficient is defined as a function of the speed of movement of the mobile terminal in the current cell. According to a preferred embodiment, the method comprises the following steps: - defining an integer number Nf of measurement windows, and, for k = 1 to Nf, and i = 1 to 2560 * Nec, Nec representing the number of samples per chip: - calculate the average vector Ck (i) representing the correlation profile associated with the window of rank k, - estimate the value of the weighting coefficient A (k) as a function of the time elapsed since the calculation of the profile associated with the window of rank kl, - calculate the averaged profile Pk (i) resulting from the profiles Ck obtained in the different windows according to the expression: Pk (i) = (1- A (k)) Pki (i) + i ( k) Ck (i), detect the maximum peak of the profile Pk (i),

  - identify the instant associated with the maximum peak 30 of the profile Pk (i).

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  Preferably, the method according to the invention is implemented by a mobile terminal in a mobile telecommunication network based on CDMA technology comprising a plurality of cells, each cell hosting a base station exchanging synchronization data with the mobile terminal. in slots and time frames, the start of a slot being detected by means of a primary code Cp transmitted via a primary synchronization channel PSCH, and the start of a frame being detected by means of a secondary code Cilk containing Ns chips transmitted to the terminal via an SSCH secondary channel. The terminal according to the invention comprises a) means for calculating, during a plurality of predefined time windows, the correlation profile between a code generated by the mobile terminal and a spreading code specific to a given cell, b) means to combine the profiles of the different windows, c) means for detecting the peaks of correlations in the combined profiles,

  d) means for filtering the peaks of detected correlations.

  Preferably, this terminal also comprises - means for weighting the measurements

  performed in two successive time windows 30 by a variable coefficient.

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  To implement the method, the terminal comprises: - means for defining an integer number Nf of measurement windows, and, for k = 1 to Nf, and i = 1 5 to 2560 * Nec, Nec representing the number of samples per chip means for calculating the average vector Ck (i) representing the correlation profile associated with the window of rank k, - means for estimating the value of the weighting coefficient A, (k) as a function of the time elapsed since the calculation of the profile associated with the row window kl, - means for calculating the averaged profile Pk (i) resulting from the profiles Ck obtained in the different windows Pk (i) = (1- A (k)) Pkl (i) + A (k) Ck (i), means for detecting the maximum peak of the profile Pk (i), - means for identifying the instant

  associated with the maximum peak of the profile Pk (i).

BR VE DESCRIPTION OF THE DRAWINGS

  - Figure 1 schematically illustrates the structure of the primary PSCH and secondary SSCH synchronization channels transmitted by a UMTS base station, - Figure 2 shows a table illustrating the relationship between the scrambling code groups and the associated patterns used for 30 build the codes that make up the SSCH secondary channel.

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  - Figure 3 schematically illustrates the cell search procedure in standby mode or during the commissioning of the mobile terminal, - Figure 4 schematically illustrates the cell search procedure in connected mode, - Figure 5 schematically illustrates a profile correlation obtained by a UMTS cell search procedure of the prior art, - Figure 6 is a flowchart 10 illustrating a preferred mode of implementation of the method

according to the invention.

  EXHIBITION OF SIZE OF SPECIFIC EMBODIMENTS

  The invention is based on the idea of carrying out partial correlations, and of adding them

according to a weighting factor.

  Figure 6 is a flowchart illustrating

  a preferred mode of application of the method according to the invention in step 1 of the search for UMTS cells defined by the 3GPP specifications.

  The process applies analogously to

  steps 2 and 3 of these specifications.

  The following definitions will be used in

the rest of this description:

  Nf: number of windows on which step 1 is performed, Nec: number of samples per chip, A (k): Weighting coefficient between 0 and 1 associated with window k, making it possible to give more or less weight in the present compared to the past,

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  Pk: Vector containing the averaged correlation profile of window k, taking into account the profiles obtained in the different measurement windows. It is a vector of positive reals, comprising 2560 * Nec values. Referring to Figure 6, step 10 consists in initializing the correlation profile of the niche synchronization: Pk.1 (i) = 0 for i = 1 at 2560 * Nec Step 12 consists in calculating for k = 1 at Nf, the correlation profile associated with each window k. This step provides a vector Ck consisting

  real positives of dimension 2560 * Nec.

  Step 14 consists in estimating the value of the weighting coefficient A (k) associated with the window k as a function of the time elapsed since the calculation of the profile

  associated with the window of rank k-1.

  Step 16 consists in updating the averaged profile Pk (i) by applying digital filtering for i = 1 to 2560 * Nec:

  Pk (i) = (1- X (k)) Pk-l (i) + X (k) Ck (i).

  Note that the weighting coefficient X (k) is chosen as a function of the time difference T between 25 the two successive windows in which each

profile is calculated.

  In a first implementation of the method, a time difference ts representing a threshold value is specified experimentally. When the time difference T between two windows of successive measurements

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  is less than ts, the weighting coefficient is

  defined by a fixed value for example, A (k) = 0.5.

  If on the contrary, the value of the time difference T of the window k is greater than t5, A, (k) 5 can be calculated according to a function which increases as a function of the distance between the windows. Through

example

  A (k) = 1- 0, 5 * (In step 18, we check if the number Nf of

windows is reached.

  If this is the case, step 20 consists in detecting the maximum correlation peak

  which will indicate the start of a niche.

  If the number Nf of windows is not

  reached, the procedure resumes from step 12.

  The method according to the invention applies to each of the first 3 steps of the UMTS FDD cell search procedure Step 1: Time synchronization at the slot level Step 2: Time synchronization at the frame level and identification of the scrambling code group Step 3 Identification of the scrambling code This process can be implemented by - A mobile terminal in GSM mode (GSM 900, DCS 1800 or PCS 1900) connected, and making measurements on neighboring UMTS FDD cells (use of

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  idle frames of multi-frame 26 and multi-frame 51); - A mobile terminal in UMTS FDD mode connected and making measurements on the neighboring UMTS 5 FDD cells having a carrier frequency different from that of the cell communicating with the mobile terminal; - A mobile terminal in GPRS or EDGE or HSCSD mode connected, and making measurements on the 10 neighboring UMTS FDD cells; - A mobile terminal in cdma2000 mode connected, and making measurements on the neighboring UMTS FDD cells; - In any system with CDMA 15 technology o correlation profiles must be calculated and

  added discontinuously.

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Claims (10)

  1. Method for optimizing the search for cells in a cellular telecommunications network in which each cell is identified by a spreading code transmitted by the network to the   terminal, method comprising the following steps.   a) calculating, during a plurality of predefined time windows, the correlation profile between a code generated by the mobile terminal 10 and said spreading code, b) combining the profiles of the different windows, c) detecting the correlation peaks in the combined profiles, d) filtering out the peaks of correlations detected, a process characterized in that it comprises   in addition to a step consisting in weighting the measurements made in two successive time windows 20 by a variable coefficient.   2. Method according to claim 1, characterized in that said weighting coefficient is defined as a function of the time difference X which separates two consecutive windows where each profile is calculated. 3. Method according to claim 2, characterized in that said weighting coefficient 30 is defined by the expression R, (k) = 1-0.5 * (tC / T) o Ir, SP 21454 HM   represents an experimentally specified time difference threshold. 4. Method according to claim 3, 5 characterized in that said weighting coefficient is defined as a function of the speed of movement of the   mobile terminal in the current cell.   5. Method according to one of claims 1 10 to 4, characterized in that it comprises the steps   following: - define an integer Nf of measurement windows, and for k = 1 to Nf, and i = 1 to 2560 * Nec, Nec representing the number of samples per chip: - calculate the average vector Ck (i) representing the correlation profile associated with the window of rank k, - estimate the value of the weighting coefficient A (k) as a function of the time elapsed since the calculation of the profile associated with the window of rank kl, - calculate the averaged profile Pk ( i) resulting from the profiles Ck obtained in the different windows according to the expression: Pk (i) = (1- A (k)) Pkl (i) + A (k) Ck (i), detect the maximum peak of the profile Pk (i), - identify the instant associated with the peak profile Pk (i).   6. Method according to one of claims 1 30 to 5, wherein the mobile telecommunications network   is based on CDMA technology and has a SP 21454 HM   plurality of cells, each cell hosting a base station exchanging synchronization data with slots and time frames, the start of a slot being detected 5 by means of a primary code aCp transmitted via a primary channel synchronization PSCH, and the start of a frame being detected by means of an aC.ik secondary code containing Ns chips transmitted to the terminal via a channel secondary SSCH.   7. Method according to claim 6, characterized in that the telecommunications network is the UMTS network.   8. Mobile telecommunication terminal comprising means for optimizing the search for cells in a telecommunication network in which each cell is identified by a spreading code transmitted by the network to said terminal, characterized in that it comprises: a) means for calculating, during a plurality of predefined time windows, the correlation profile between a code generated by the mobile terminal and a spreading code specific to a given cell, b) means for combining the profiles of the different windows.   c) means for detecting the peaks of correlations in combined profiles, d) means for filtering the peaks of correlations detected, SP 21454 HM   9. Terminal according to claim 8, characterized in that it further comprises:   - Means for weighting the measurements 5 carried out in two successive time windows by a variable weighting coefficient.   10. Terminal according to claim 9, characterized in that it comprises: - means for defining an integer Nf of measurement windows, and, for k = l to Nf, and i = 1 to 2560 * Nec, Nec representing the number of samples per chip: - means for calculating the average vector 15 Ck (i) representing the correlation profile associated with the window of rank k, - means for estimating the value of the weighting coefficient (k) in function of the time elapsed since the calculation of the profile associated with the window 20 of rank kl, - means for calculating the averaged profile Pm (i) resulting from the profiles Ck obtained in the different windows: Pk (i) = (1- A ( k)) Pk-l (i) + A (k) Ck (i), - means for detecting the maximum peak of the profile Pk (i), - means for identifying the instant   associated with the maximum peak of the profile Pk (i). SP 21454 HM