JP5178580B2 - Mobile station, cell search method - Google Patents

Description

  The present invention relates to a cell search technique performed using a synchronization channel included in a downlink signal of wireless communication.

  In a mobile communication system, a mobile station needs to detect a cell to which the mobile station intends to connect in order to establish initial synchronization or for handover. This process is called cell search. Here, the cell to be detected generally corresponds to each of one or more antennas of the base station. That is, a cell ID is assigned in units of base station antennas (in units of sectors). However, in the following description, for convenience of explanation, it is assumed that a cell ID is assigned to each base station.

  In E-UTRA (Evolved Universal Terrestrial Radio Access), which is a next-generation mobile communication standard, an OFDM (Orthogonal Frequency Division Multiplex) communication method using a multicarrier in the downlink is adopted, and at a predetermined timing of the downlink radio frame, A primary synchronization channel signal (hereinafter referred to as PSC (Primary Synchronization Channel) signal) and a secondary synchronization channel signal (hereinafter referred to as SSC (Secondary Synchronization Channel) signal) as a synchronization signal are mapped over a plurality of subcarriers. In the cell search, the PSC signal is used for timing detection, and the SSC signal is used for detection of a cell ID unique to the base station.

In E-UTRA, an SSC signal transmitted from each base station is generated with a base station-specific code (any one of 168 types of codes corresponding to cell IDs) by cyclic shifting of M sequences. The mobile station detects the cell ID by detecting (specifying) the code included in the received SSC signal. More specifically, in the mobile station, 168 types of M-sequence codes and cell IDs corresponding to the respective codes are known, and correlation values are calculated by calculating correlation values between the respective codes and the received SSC signal. A plurality of cell IDs having high values are detected. The base station corresponding to the detected cell ID becomes a handover destination candidate.
In E-UTRA, in order to detect more types of cell IDs (168 types) than the M-sequence code length (31 bits), two 31-bit M-sequence codes are combined to generate a 62-bit code length. It is set to (in theory, can detect 31 ² types of cells ID).
The specifications for E-UTRA are disclosed in Non-Patent Documents 1 to 4.

Here, in a 31-bit code by cyclic shift of M sequence,
u (a, k): the value of the kth bit of the code of sequence number a,
u (b, k): the value of the k-th bit of the code of sequence number b,
Then, the intersymbol correlation value C (a, b) between u (a, k) and u (b, k) is expressed by the following Equation 1.
However, in the above formula, each bit value is calculated as {1, −1}. At this time, C (a, a) = 31 and C (a, b) = − 1 (where a ≠ b).

3GPP TS 36.211 V8.5.0 (2008-12): 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; "Evolved Universal Terrestrial Radio Access (E-UTRA); Physical Channels and Modulation" (Release 8) (especially 4.1 Frame structure type 1, 6.11 Synchronization signals) 3GPP TS 36.213 V8.5.0 (2008-12): 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; "Evolved Universal Terrestrial Radio Access (E-UTRA); Physical layer procedures" (Release 8) (especially 4.1 Cell search ) 3GPP TS 36.133 V8.4.0 (2008-12): 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; "Evolved Universal Terrestrial Radio Access (E-UTRA); Requirements for support of radio resource management" (Release 8) (especially 4.1 Cell Selection, 4.2 Cell Re-selection) 3GPP TS 36.304 V8.4.0 (2008-12): 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; "Evolved Universal Terrestrial Radio Access (E-UTRA); User Equipment (UE) procedures in idle mode" (Release 8) (Especially 5.2 Cell selection and reselection)

  By the way, in E-UTRA, an inter-cell synchronization system is also studied from the viewpoint of improving reception quality. In the inter-cell synchronization system, radio frames (hereinafter simply referred to as “frames”) received by mobile stations from surrounding base stations are synchronized. In this case, the timing at which the mobile station receives the synchronization signal (PSC signal and SSC signal) from each base station is slightly different depending on the propagation delay between each base station and the mobile station, but at almost the same timing. is there. Therefore, the mobile station detects the cell ID based on the SSC reception signal in a state where SSC signals from a plurality of neighboring base stations are superimposed. In the mobile station, the cell ID may be erroneously detected due to the correlation between the received SSC signal and a known code corresponding to each cell ID.

Regarding the occurrence of this erroneous detection, in the OFDM wireless communication system that is a multi-carrier, the mobile station, for example, the SSC received signal from the two neighboring base stations (BS1, BS2) and the known code corresponding to each cell ID A case where the correlation is taken as an example will be described below.
First,
m: cell ID (m ₁ , m ₂ : cell IDs of base stations BS1 and BS2 respectively)
k: subcarrier position in OFDM modulation R _in (k): SSC received signal R _d (k): demodulated SSC received signal C (m): R _in (k) R _d (k) and C (m) are each expressed by the following formulas.

However, in each of the above formulas,
H ₁ (k), H ₂ (k): channels from the base stations BS1 and BS2 to the mobile station in the kth subcarrier (propagation path modeled by complex numbers),
N (k): noise component in the kth subcarrier,
P (m, k): bit value corresponding to the k-th subcarrier of the code corresponding to cell ID = m (where P (m, k) = {1, −1}),
G (k): channel estimation value represented by a complex number (G (k) with an upper line is a conjugate complex number of G (k)),
It is.

As shown in Equation 4 above, the correlation value calculation taking into account the influence of the propagation path between each base station and the mobile station is not the ideal correlation calculation shown in Equation 1, but the SSC signal from each base station. It is understood that the received signal level is affected.
Here, for example, it is assumed that the mobile station is communicating with the base station BS1 and tries to detect the cell ID of the base station BS2 adjacent to the base station BS1 (neighboring cell search). In this case, as a generally conceivable situation, in the mobile station, the received signal level from the base station BS1 is higher than the level from the base station BS2, and the SSC received signal and the known code corresponding to each cell The cell ID of the base station BS1 is detected first (that is, the correlation value C (m ₁ ) of the cell ID of the base station BS1 is the largest).

  At this time, the mobile station wants to detect a cell ID having the next highest correlation value after the cell ID of the base station BS1 as a handover candidate. However, depending on the signal level of the SSC signal coming from the base station BS1 to the mobile station, the base station There is a case where the cell ID of the base station BS2 cannot be detected as the cell ID having the next highest correlation value after the cell ID of the BS1.

The reason why the cell ID of the base station BS2 cannot be detected will be described below.
As shown in Equation 4 above, Σ in the correlation value equation includes a component (G (k) H ₁ (k) P (m ₁ , k) P (m, k)), the correlation value for the cell ID of the base station BS2 arrives at the mobile station from the base station BS1 when the correlation is obtained between the SSC received signal and the known code corresponding to each cell. Affected by the signal level of the SSC signal. For example, when the signal level of the SSC signal arriving from the base station BS2 to the mobile station is small, the component (G (k) H ₂ (k) P (m ₂ , k) P in Equation 4 based on the SSC signal is used. (m, k)) is also small, so the calculated correlation value may be small. In this case, the correlation value calculated by Equation 4 deviates from the ideal correlation value, and the cell ID of the base station BS2 cannot be detected.

When the signal level of the SSC signal arriving from the base station BS1 to the mobile station is high, the correlation value between the code corresponding to the cell ID of the base station BS2 and the code corresponding to the cell ID of the base station BS1 is large. The length and the sign (positive or negative) greatly affect the correlation value of the cell ID of the base station BS2. Therefore, depending on the signal level of the SSC signal from the base station BS1, the overall correlation value in the cell ID of the base station BS2 can vary greatly.
For example, when the correlation value between the code corresponding to the cell ID of the base station BS2 and the code corresponding to the cell ID of the base station BS1 is a negative value and the absolute value is large, the base station BS2 The overall correlation value in the cell ID is greatly reduced. In this case, the correlation value calculated by Equation 4 deviates from the ideal correlation value, and the cell ID of the base station BS2 cannot be detected.
Further, when the correlation value between the code corresponding to the cell ID of the base station BS2 and the code corresponding to the cell ID of the base station BS1 is a positive value and the absolute value thereof is large, the base station BS2 This greatly increases the overall correlation value in the cell ID. In this case, the correlation value calculated by Equation 4 deviates from the ideal correlation value, and the cell ID of the base station BS2 is erroneously detected until it should not be detected.

  In view of the above viewpoint, when a mobile station simultaneously receives signals including cell-specific information specific to each base station from a plurality of base stations, the possibility of correctly detecting the cell-specific information of each base station has been increased. The problem is to provide a mobile station and a cell search method.

A mobile station that receives a reference signal including any of a plurality of cell-specific information associated in advance for each antenna of a base station from a neighboring base station, and detects at least two or more cell-specific information from the reference signal Provided.
This mobile station
(A) A first correlation calculation that correlates between the received first reference signal and each of the plurality of cell specific information and calculates a first correlation value between the reference signal and each cell specific information. And
(B) a first determination unit that determines first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
(C) Correlation is made between a replica of a component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information, and between the replica and each cell specific information. A second correlation calculation unit for calculating a second correlation value of
(D) a subtraction unit that subtracts the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
(E) a second determination unit that determines second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
Equipped with a,
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers,
For each of the plurality of subcarriers, each subcarrier is multiplied by the square value of the channel estimation value of the subcarrier and the bit value assigned to the subcarrier among the codes corresponding to the first cell specific information. Calculating a multiplication value for a carrier, and multiplying the multiplication value for all of a plurality of subcarriers to generate the replica;
In addition, a cell search method for performing the same processing as that of the mobile station is provided.

  When the mobile station simultaneously receives signals including cell-specific information unique to each base station from a plurality of base stations, it is possible to increase the possibility of correctly detecting the cell-specific information of each base station.

The figure which shows an example of the radio | wireless communications system in which the mobile station which concerns on embodiment is included. The figure which shows an example of a structure of the frame which the mobile station which concerns on embodiment from each base station receives. The block diagram which shows the principal part of the structure of the mobile station which concerns on embodiment. The figure which shows an example of the output (1st correlation value) of a correlation calculating part in the mobile station which concerns on embodiment. The figure which shows an example of the output (2nd correlation value) of the correlation calculating part in the loop of the 1st time in the mobile station which concerns on embodiment. The figure which shows an example of the output (3rd correlation value) of the subtraction part after the 1st loop in the mobile station which concerns on embodiment. The figure which shows an example of the output (2nd correlation value) of the correlation calculating part in the loop of the 2nd time in the mobile station which concerns on embodiment. The figure which shows an example of the output (3rd correlation value) of the subtraction part after the 2nd loop in the mobile station which concerns on embodiment.

  Hereinafter, a radio communication system including the mobile station according to the embodiment will be described.

(1) Configuration of Radio Communication System FIG. 1 is a diagram illustrating an example of a radio communication system including a mobile station (UE: User Equipment) according to the embodiment. The wireless communication system shown in FIG. 1 includes a mobile station 10 and base stations (eNodeB) 20-1 to 20-3 located around the mobile station 10. The radio communication system shown in FIG. 1 is inter-cell-synchronized, and the mobile station 10 receives downlink radio frames (hereinafter simply referred to as “frames”) from the base stations 20-1 to 20-3 in the vicinity of the own station. Are received at almost the same timing.

  Note that cell IDs as cell-specific information are generally allocated in units of sectors (that is, in units of base station antennas). In this embodiment, for convenience of explanation, it is assumed that cell IDs are allocated in units of base stations. Naturally, even if such a setting is made, the generality is not lost.

  In this wireless communication system, the mobile station 10 is communicating with the base station 20-1, but prepares for handover and synchronizes frames based on a synchronization signal (reference signal) included in a frame from each base station. At the same time, a process (peripheral cell search) for detecting cell IDs of base stations (20-2, 20-3) other than the base station 20-1 as handover candidates is performed.

  FIG. 2 is a diagram illustrating an example of a configuration of a frame received by the mobile station 10 from each of the base stations 20_1 to 20_3. The example shown in FIG. 2 is a frame configuration specified in E-UTRA. The frame shown in FIG. 2 includes 10 subframes (not shown) in a 10 ms frame. In the first subframe and the fifth subframe, a plurality of primary synchronization channel (hereinafter, PSC: Primary Synchronization Channel) signals and secondary synchronization channel (hereinafter, SSC: Secondary Synchronization Channel) signals are used as synchronization signals. Mapped to subcarrier. That is, the PSC signal and the SSC signal are inserted in the frame at a period of 5 ms.

As the SSC signal, for example, an M sequence is used as a sequence having excellent autocorrelation characteristics. The SSC signal corresponding to the cell ID of each base station is generated with a code based on an M-sequence cyclic shift. This code is 62 bits long by combining two sets of 31-bit M series codes. The 62-bit SSC signal is BPSK-modulated bit by bit and then mapped to 62 subcarriers for transmission.
In this wireless communication system, there are 168 types of SSC signal codes corresponding to each cell ID. In the following, the code indicated by the SSC signal is referred to as “SSC code” in distinction from the code indicated by the PSC signal (“PSC code” described later). In the mobile station 10, 168 types of SSC codes are known.

On the other hand, as the PSC signal, for example, a Zadoff-Chu sequence (63-bit length) which is one of CAZAC (Constant Amplitude Zero Auto-Correlation) sequences is applied. Of the 63-bit Zadoff-Chu sequence signal, 62 bits excluding the center are used as the PSC signal. This 62-bit PSC signal is mapped to 62 subcarriers and transmitted.
In this embodiment, three types of codes are used for the PSC signal based on the Zadoff-Chu sequence. Hereinafter, the code indicated by the PSC signal is referred to as a “PSC code” in distinction from the SSC code described above. In the mobile station 10, three types of PSC codes are known.

  In this wireless communication system, for example, 504 cell IDs are prepared. In the cell search, the mobile station 10 first detects the timing based on the PSC signal in the received frame, and further correlates the SSC received signal with each of the 168 known SSC codes. A plurality of cell IDs corresponding to the SSC code having a high correlation value are detected.

  As described above, in this wireless communication system, it is assumed that the frames from the base stations 20-1 to 20-3 around the mobile station 10 are synchronized. In this case, the timing at which the mobile station 10 receives the synchronization signal (PSC signal and SSC signal) from each base station 20-1 to 20-3 is slightly different according to the propagation delay with each base station, The timing is almost the same. That is, in the wireless communication system according to the present embodiment, frames from neighboring base stations arrive at the mobile station 10 almost simultaneously. Therefore, the mobile station 10 detects the cell ID from the SSC reception signal in a state where the SSC signals from a plurality of base stations are superimposed.

(2) Principle of Cell Search Method Applied in the Present Embodiment Hereinafter, the cell search method applied in the mobile station 10 of the present embodiment, particularly the principle of the method of detecting the cell ID from the demodulated SSC signal, Will be described.

First,
m: cell ID (m ₁ , m ₂ : cell IDs of the base stations 20-1 and 20-2, respectively),
k: subcarrier position in OFDM modulation,
C (m): correlation value for cell ID = m,
Then, C (m) is expressed by Equation 5 below by expanding Equation 4 above.

However, in Equation 5 above,
H ₁ (k), H ₂ (k): channels from the base stations 20-1 and 20-2 to the mobile station (the propagation path is modeled as a complex number)
N (k): noise component,
P (m, k): bit value corresponding to the k-th subcarrier of the code corresponding to cell ID = m (where P (m, k) = {1, −1}),
G (k): channel estimation value represented by a complex number (G (k) with an upper line is a conjugate complex number of G (k)),
It is.

Formula 5 is a formula when it is assumed that there are only two base stations 20-1 and 20-2 around the mobile station. By generalizing Equation 5, the correlation value for each cell ID is the sum of the correlation values calculated on the assumption that the SSC signal is received only from each individual base station for all base stations. It will be understood that it will be. Therefore, when the cell ID having the largest correlation value has already been detected and the cell ID having the second largest correlation value is to be detected correctly, the cell search method of this embodiment performs the following processing. That is, the correlation value calculated when it is assumed that only the SSC signal corresponding to the cell ID having the largest correlation value is received is subtracted from the correlation value calculated based on the SSC reception signal. As a result, the influence of the SSC signal corresponding to the cell ID having the largest correlation value can be excluded from the correlation value calculated based on the SSC received signal, so that the cell ID having the second largest correlation value is correctly detected. Will be able to.
Similarly, the cell IDs having the largest correlation values after the third are sequentially detected.

  Such a correlation value process is particularly useful when a mobile station in communication with a base station with the highest received signal level searches for a cell ID of another base station with a much lower received signal level than that base station. It is valid. For example, in FIG. 1, when the mobile station 10 is communicating with the base station 20-1, it is assumed that the cell ID of the base station 20-2 is to be searched as a base station adjacent to the base station 20-1. To do. In this case, the mobile station 10 is in a situation where the received signal level from the base station 20-1 is much higher than the level from the base station 20-2. At this time, the mobile station 10 detects the cell ID of the base station 20-1 by calculating the correlation value (the above formula 5) for each cell ID based on the SSC received signal, and thereafter, only the base station 20-1 The correlation value calculated when it is assumed that the SSC signal is received from is subtracted. Thereby, the influence by the received signal level from base station 20-1 and / or the correlation value of the SSC code between base station 20-1 and base station 20-2 can be excluded.

  Here, when performing a neighboring cell search based on the above-described principle, it is necessary to calculate a correlation value when it is assumed that an SSC signal is received only from a specific base station. Therefore, the mobile station of the embodiment generates an SSC signal from only a specific base station as an SSC replica.

(3) Cell search method applied in this embodiment Next, the cell search method applied in the mobile station 10 will be described step by step.

(First step)
In the first step of this method, a correlation value calculation is performed between the SSC received signal and the SSC code corresponding to each cell ID, whereby a correlation value for each cell ID (hereinafter referred to as a first correlation value) is obtained. The cell ID (first cell specific information) calculated and having the largest correlation value is detected. It is assumed that the detected cell ID is, for example, the cell ID of the base station 20-1 communicating with the mobile station 10.

(Second step)
Next, in the second step of this method, when the mobile station 10 detects a cell ID having the next highest correlation value after the cell ID of the base station 20-1, the base station 20-1 in which the cell ID has already been detected. In order to eliminate the influence of the received signal level from the SSC signal, a replica of the SSC signal from the base station 20-1 (SSC replica) is generated. Then, by performing a correlation value calculation between the SSC replica of the base station 20-1 and the SSC code corresponding to each cell ID, a correlation value (hereinafter referred to as a second correlation value) for each cell ID is calculated. The

Note that the SSC replica of the base station 20-1 corresponds to Equation 6 below in Equation 5 above. That is, the SSC replica of the base station 20-1 is P (m ₁ , k) in the ideal case where there is no influence of the propagation path between the base station 20-1 and the mobile station. Is taken into account as shown in Equation 6.

Further, if the second correlation value calculated based on this SSC replica is I (m) (m: cell ID), I (m) is expressed by Equation 7 below. This I (m) is the same as the first term of C (m) shown in Equation 5.

(Third step)
Next, in the third step of the method, the second correlation value is subtracted from the first correlation value for each cell ID. The third correlation value obtained by this subtraction is the received signal level from the base station 20-1 already detected and / or the correlation value between the SSC codes between the base station 20-1 and another base station. The effects of are excluded. This subtraction is equivalent to erasing the first term from C (m) in Equation 5 above.

(4th step)
Finally, in the fourth step of this method, the cell ID (second cell specific information) having the largest correlation value is detected among the third correlation values for each cell ID.

  In the wireless communication system of FIG. 1, assuming that the cell ID detected in the fourth step corresponds to the base station 20-2, the cell IDs of other base stations 20-3 are obtained by repeating the above steps. Are also detected in the same manner. That is, in this cell search method, SSC replicas corresponding to the base station corresponding to the detected cell ID are sequentially generated, and a correlation value (second correlation value) is calculated based on the SSC replica. By subtracting from the calculated correlation value (first correlation value), new cell IDs are sequentially detected.

When generating an SSC replica, Equation 6 can be approximated as shown in Equation 8 below. This approximation is based on the assumption that the channel from the base station 20-1 to the mobile station is dominant (ie, H ₁ (k) = G (if | H ₁ |> | H ₂ | k)).

At this time, I (m) shown in Equation 7 can be approximated as follows.

(4) Configuration of Mobile Station According to Embodiment Hereinafter, a main part of the configuration of the mobile station 10 will be described with reference to FIG. FIG. 3 is a block diagram illustrating a main part of the configuration of the mobile station 10.
As illustrated in FIG. 3, the mobile station 10 according to the embodiment includes a filter 50, a timing detection unit 51, an FFT unit 52, a channel estimation unit 53, a demodulation unit 54, a correlation calculation unit 55 (first correlation calculation unit), and subtraction. Unit 56, peak search unit 57 (first determination unit, second determination unit), replica generation unit 58, and correlation calculation unit 59 (second correlation calculation unit).

  The timing detection unit 51 detects the timing at which the PSC signal is inserted based on the OFDM received signal limited to a desired band by the filter 50. That is, since three types of PSC codes are known in the mobile station 10, the timing detection unit 51 shifts the timing little by little, and the PSC signal replicas (hereinafter referred to as PSC replicas) and received signals based on the three types of PSC codes. The correlation value is calculated. By searching for the peak of the correlation value, it is detected which of the three types of PSC codes used in the received frame and the timing at which the PSC signal is inserted are detected.

  The FFT unit 52 performs FFT (Fast Fourier Transform) on the band-limited OFDM reception signal based on the FFT timing given from the timing detection unit 51. As a result, the PSC signal and the SSC signal in the OFDM reception signal are converted into signals in the frequency domain. Then, the PSC signal separated by the FFT unit 52 is given to the channel estimation unit 53 and the demodulation unit 54.

  The channel estimation unit 53 is a channel for each subcarrier to which the PSC signal is mapped based on the PSC signal given from the FFT unit 52 and the PSC replica (known) corresponding to the PSC code detected by the timing detection unit 51 Estimate. Here, since the SSC signal and the PSC signal are adjacent on the time axis in the frame, the channel estimation value for the SSC signal can be considered to be substantially the same as that of the PSC signal. Therefore, the demodulation unit 54 demodulates the SSC signal using the channel estimation value of the PSC signal given from the channel estimation unit 53.

  Here, as described above, since the frames from the base stations 20-1 to 20-3 are synchronized in the wireless communication system of the present embodiment, the SSC reception signals output from the demodulation unit 54 are The SSC signal from the base station is superimposed. Each unit after the correlation calculation unit 55 detects the cell ID according to the cell search method based on the SSC reception signal.

  The correlation calculation unit 55 performs a correlation value calculation between the SSC reception signal obtained by the demodulation unit 54 and the SSC code corresponding to each cell ID, thereby obtaining a correlation value (first correlation value) for each cell ID. ) Is calculated. This correlation value calculation is equivalent to the calculation according to the above equation 4 (or the uppermost equation of equation 5). This calculation is performed as follows. That is, first, for the cell ID of m = 1, the signal value of each subcarrier and each bit (= {1, -1}; known) of the code of m = 1 corresponding to each subcarrier. Multiplication is performed, and the multiplication results of all subcarriers are added. Thereby, the correlation value corresponding to the cell ID of m = 1 is calculated. Similarly, the above processing is performed for cell IDs after m = 2. As a result, a correlation value (first correlation value) corresponding to each cell ID (for each cell ID) is obtained.

The subtracting unit 56 subtracts the correlation value (second correlation value) obtained from the correlation computing unit 59 from the first correlation value obtained from the correlation computing unit 55 for each cell ID, and obtains the third correlation value for each cell ID. Generated and output to the peak search unit 57. At the stage where the SSC replica has not been generated and the second correlation value is not yet output from the correlation calculation unit 59, the first correlation value for each cell ID is output to the peak search unit 57 as it is.
The peak search unit 57 detects the cell ID having the largest correlation value from the first correlation value or the third correlation value for each cell ID.

  The replica generation unit 58 generates an SSC replica corresponding to the cell ID detected by the peak search unit 57. This SSC replica generation process is equivalent to the execution of the calculation according to Equation 8 above. That is, the square value of the channel estimation value of each subcarrier obtained by the channel estimation unit 53 and each bit corresponding to each subcarrier of the SSC code corresponding to the cell ID detected by the peak search unit 57 (= { 1, −1}; known).

  The correlation calculation unit 59 performs a correlation value calculation between the SSC replica generated by the replica generation unit 58 and the SSC code corresponding to each cell ID, whereby a correlation value (second correlation value) for each cell ID is obtained. ) Is calculated. This correlation value calculation is equal to the calculation according to the above-described Expression 4 (or the upper expression of Expression 5). The calculation process itself is the same as the process of the correlation calculation unit 55.

  In this mobile station 10, when detecting a plurality of cell IDs, the processing of the peak search unit 57, the replica generation unit 58, the correlation calculation unit 59, and the subtraction unit 56 is repeated in order (loop processing).

(4) Example of Operation of Mobile Station According to Embodiment The operation of the mobile station 10 according to the embodiment will be described with reference to FIGS.
FIG. 4 is a diagram illustrating an example of the output (first correlation value) of the correlation calculation unit 55. FIG. 5 is a diagram illustrating an example of the output (second correlation value) of the correlation calculation unit 59 in the first loop. FIG. 6 is a diagram illustrating an example of the output (third correlation value) of the subtraction unit 56 after the first loop. FIG. 7 is a diagram illustrating an example of the output (second correlation value) of the correlation calculation unit 59 in the second loop. FIG. 8 is a diagram illustrating an example of the output (third correlation value) of the subtraction unit 56 after the second loop.

In the output result example of the correlation calculation unit 55 shown in FIG. 4, it is assumed that the correlation value peaks p <b> 1 to p <b> 3 are peaks to be detected in order. In other words, if an ideal correlation value calculation without the influence of the propagation path is performed, it is assumed that peaks p1 to p3 of the correlation value are detected in order.
Since the correlation value (first correlation value) shown in FIG. 4 is calculated based on the SSC reception signal on which the SSC signals from a plurality of base stations are superimposed, the signal of the SSC signal corresponding to the cell ID to be detected Depending on the inter-code correlation value with the cell ID of the peak p1 where the correlation value is the maximum or when the level is low, the order of the correlation values based on FIG. The order may deviate. For example, in FIG. 4, since the correlation value calculated by the correlation calculation unit 55 is such that peak p4> peak p3, if it is detected in the order of the peak values indicated by this correlation value result, the peak p4 is erroneously detected. Will be detected before the cell ID of peak p3.

  Based on the result of FIG. 4, the peak search unit 57 in the first loop detects the cell ID of the peak p1. The replica generation unit 58 generates an SSC replica corresponding to the cell ID of the peak p1. FIG. 5 shows a result (second correlation value) obtained by performing correlation value calculation between the SSC replica and the SSC code corresponding to each cell ID by the correlation calculation unit 59. FIG. 5 shows the correlation value when it is assumed that only the SSC signal corresponding to the cell ID of the peak p1 is received. Of course, the correlation value is maximum for the cell ID indicated by the peak p1 in FIG. Become.

  The third correlation value shown in FIG. 6 is a correlation value (third correlation value) for each cell ID obtained by subtracting the second correlation value shown in FIG. 5 from the first correlation value shown in FIG. In FIG. 6, as compared with FIG. 4, the peak p1 disappears, and the variation of the correlation value is small across all the cell IDs. Particularly in FIG. 6, the peak p4 seen in FIG. 4 is hardly noticeable.

  Based on the result of FIG. 6, the peak search unit 57 after the first loop detects the cell ID of the peak p2. The replica generation unit 58 after the first loop generates an SSC replica corresponding to the cell ID of the peak p2. FIG. 7 shows a result (second correlation value) obtained by performing correlation value calculation between the SSC replica and the SSC code corresponding to each cell ID by the correlation calculation unit 59 after the first loop. FIG. 7 shows the correlation value when it is assumed that only the SSC signal corresponding to the cell ID of the peak p2 is received. Of course, the correlation value is maximum for the cell ID indicating the peak p2 in FIG. Become.

  The third correlation value shown in FIG. 8 is a correlation value (third correlation value) for each cell ID obtained by subtracting the second correlation value shown in FIG. 7 from the first correlation value shown in FIG. In FIG. 8, as compared with FIG. 6, the peak p2 disappears and the fluctuation of the correlation value is further reduced over all the cell IDs. Based on the result of FIG. 8, the peak search unit 57 after the second loop detects the cell ID of the peak p3.

As described above, according to the mobile station or cell search method of this embodiment, every time a cell ID is detected, an SSC replica corresponding to the detected cell ID is generated, and the correlation value based on the SSC replica is generated. The component is subtracted from the correlation value based on the received SSC signal. Therefore, the influence of the detected cell ID on the subsequent detection of the cell ID can be eliminated.
Therefore, it is less likely that a cell ID having a large intersymbol correlation value with a detected cell ID is erroneously detected, and the possibility of erroneous detection can be reduced. In addition, this erroneous detection is remarkable when the signal level of the SSC signal of the detected cell ID is large. However, since the influence of the signal level can be eliminated, a cell ID other than the detected cell ID can be assigned. Reduce the minimum signal level of the SSC signal that can be detected. For example, in the examples shown in FIGS. 4, 6, and 8, it can be seen that the fluctuations in the absolute values of the correlation values other than the peaks are sequentially reduced, and the detection of the peak p <b> 3 is finally facilitated. Therefore, due to the influence of the propagation path between the mobile station and the base station, there is a high possibility that the cell ID of the base station can be detected even when the received signal level at the mobile station is small.

(5) Modification 1 for calculating the second correlation value
Hereinafter, a modified example of the second correlation value calculation for reducing the processing load when the second correlation value is calculated will be described.
For example, in E-UTRA, since the band of the subcarrier group to which the synchronization signal (PSC signal, SSC signal) is allocated is narrow (62 subcarriers), the influence of frequency selective fading is small. That is, there is little variation in the channel estimation value for each subchannel. Therefore, in a system where the band of the subcarrier group to which the synchronization signal is allocated is narrow, such as E-UTRA, I (m) in Equation 9 may be approximated as Equation 10 below.

In this case, the correlation calculation unit 59 calculates the square value of the channel estimation value of the subcarrier for each of the plurality of subcarriers, integrates the square value for all of the plurality of subcarriers, and calculates the first integrated value (Σ | G (k) | ² ) is obtained. Further, the correlation calculation unit 59 has an inter-code correlation value (ΣP (m ₁ , k) P between the code corresponding to the cell ID detected by the peak search unit 57 and the code corresponding to each of the plurality of cell IDs. (m, k)) is calculated. Then, the correlation calculation unit 59 calculates the second correlation value by multiplying the first integrated value and the intersymbol correlation value. Similarly, the second correlation value can be calculated in the second step of the cell search method described above.
In this case, the SSC replica can be considered as an ideal P (m ₁ , k).

According to this modification of the second correlation value calculation, as shown in Equation 10, the calculation of the intersymbol correlation value (ΣP (m ₁ , k) P (m, k)) is a binary calculation. The amount of calculation can be reduced.
In addition, it is preferable that an inter-code correlation value between codes corresponding to each of a plurality of cell IDs is stored in advance in an LUT (Look Up Table), and this LUT is referred to in the calculation of the inter-code correlation value. Thereby, the calculation amount can be further reduced.

(6) Second modification of second correlation value calculation
Hereinafter, another modified example of the second correlation value calculation for reducing the processing load when the second correlation value is calculated will be described.
First, based on Equation 5 above, the correlation value C (m ₁ ) (first correlation value) for the cell ID = m ₁ is as shown in Equation 11. Here, the received signal level from the base station 20-1 corresponding to the cell ID = m ₁ is, under the assumption that greater than that of the base station other than the base station 20-1, the first term in equation 11 Becomes dominant, and the second and following terms can be ignored. In that case, Equation 11 can be approximated as Equation 12. Since P (m, k) = {1, -1}, P (m ₁ , k) P (m ₁ , k) = 1 in Expression 12.

From the above formulas 10 and 12, the second correlation value I (m) (m: cell ID) can be approximated as the following formula 13.

Here, the correlation value C (m ₁ ) (first correlation value) for the cell ID = m ₁ has already been calculated before calculating the second correlation value. Therefore, the second correlation value I (m) can be obtained by multiplying C (m ₁ ), which is a known value, by the intersymbol correlation value (ΣP (m ₁ , k) P (m, k)). . Therefore, compared with the first modification of the second correlation value calculation described above, the amount of calculation can be further reduced by the amount that the calculation of Σ | G (k) | ² is not required.

In this modification, the calculation result of the correlation calculation unit 55 corresponding to the cell ID detected by the peak search unit 57 is held. Correlation calculation unit 59 has an intersymbol correlation value (ΣP (m) between the SSC code (SSC replica) corresponding to the cell ID detected by peak search unit 57 and the SSC code corresponding to each of the plurality of cell IDs. ₁ , k) P (m, k)) is calculated. Then, the correlation calculation unit 59 multiplies the stored calculation result of the correlation calculation unit 55 by the intersymbol correlation value to calculate the second correlation value. Similarly, the second correlation value can be calculated in the second step of the cell search method described above.
Also in this case, the SSC replica can be considered as an ideal P (m ₁ , k). Further, the point that it is preferable to refer to the LUT in the calculation of the intersymbol correlation value is the same as in the first modification of the second correlation value calculation.

  Regarding the above embodiment, the following additional notes are disclosed.

(Appendix 1)
A mobile station that receives a reference signal including any of a plurality of cell-specific information previously associated with each antenna of a base station from a neighboring base station, and detects at least two or more cell-specific information from the reference signal There,
A first correlation calculation unit that correlates between the received first reference signal and each of the plurality of cell specific information and calculates a first correlation value between the reference signal and each cell specific information;
A first determination unit for determining first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
A correlation between the replica of the component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information is obtained, and a second between the replica and each cell specific information is obtained. A second correlation calculation unit for calculating a correlation value;
A subtraction unit that subtracts the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
A second determination unit for determining second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
Mobile station equipped with. (1)

(Appendix 2)
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers.
The mobile station described in Appendix 1. (2)

(Appendix 3)
For each of the plurality of subcarriers, each subcarrier is multiplied by the square value of the channel estimation value of the subcarrier and the bit value assigned to the subcarrier among the codes corresponding to the first cell specific information. Calculating a multiplication value for a carrier, and multiplying the multiplication value for all of a plurality of subcarriers to generate the replica;
The mobile station described in Appendix 2. (3)

(Appendix 4)
For each of the plurality of subcarriers, a first integrated value obtained by calculating a square value of a channel estimation value of the subcarrier and integrating the square value for all of the plurality of subcarriers, and the uniqueness of the first cell The second correlation value is calculated by multiplying the inter-code correlation value between the code corresponding to the information and the code corresponding to each of the plurality of cell specific information.
The mobile station described in Appendix 2. (4)

(Appendix 5)
Multiplying the first correlation value for the first cell specific information by an inter-code correlation value between a code corresponding to the first cell specific information and a code corresponding to each of the plurality of cell specific information. And calculating the second correlation value,
The mobile station described in Appendix 2. (5)

(Appendix 6)
A lookup table for storing inter-code correlation values of the plurality of cell specific information, wherein the inter-code correlation value is calculated with reference to the lookup table;
A mobile station described in Appendix 4 or 5.

(Appendix 7)
A cell search method for receiving a reference signal including any of a plurality of cell-specific information associated in advance for each antenna of a base station from surrounding base stations and detecting at least two or more cell-specific information from the reference signal Because
Receiving a first reference signal;
Correlating between the first reference signal and each of the plurality of cell specific information, calculating a first correlation value between the reference signal and each cell specific information;
Determining first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
A correlation between the replica of the component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information is obtained, and a second between the replica and each cell specific information is obtained. Calculating a correlation value;
Subtracting the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
Determining second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
A cell search method comprising: (6)

(Appendix 8)
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers.
The cell search method described in appendix 7. (7)

(Appendix 9)
The step of calculating the second correlation value includes:
For each of the plurality of subcarriers, each subcarrier is multiplied by the square value of the channel estimation value of the subcarrier and the bit value assigned to the subcarrier among the codes corresponding to the first cell specific information. Calculating a multiplication value for a carrier, and multiplying the multiplication value for all of a plurality of subcarriers to generate the replica;
The cell search method described in appendix 8. (8)

(Appendix 10)
The step of calculating the second correlation value includes:
For each of the plurality of subcarriers, a first integrated value obtained by calculating a square value of a channel estimation value of the subcarrier and integrating the square value for all of the plurality of subcarriers, and the uniqueness of the first cell The second correlation value is calculated by multiplying the inter-code correlation value between the code corresponding to the information and the code corresponding to each of the plurality of cell specific information.
The cell search method described in appendix 8. (9)

(Appendix 11)
The step of calculating the second correlation value includes:
Multiplying the first correlation value for the first cell specific information by an inter-code correlation value between a code corresponding to the first cell specific information and a code corresponding to each of the plurality of cell specific information. And calculating the second correlation value,
The cell search method described in appendix 10. (10)

(Appendix 12)
A lookup table for storing inter-code correlation values of the plurality of cell specific information, wherein the inter-code correlation value is calculated with reference to the lookup table;
The cell search method described in Appendix 10 or 11.

  DESCRIPTION OF SYMBOLS 10 ... Portable terminal (UE), 50 ... Filter, 51 ... Timing detection part, 52 ... FFT part, 53 ... Channel estimation part, 54 ... Demodulation part, 55 ... Correlation calculation part (1st correlation calculation part), 56 ... Subtraction , 57... Peak search unit (first determination unit, second determination unit), 58... Replica generation unit, 59... Correlation calculation unit (second correlation calculation unit)

Claims (6)

A mobile station that receives a reference signal including any of a plurality of cell-specific information previously associated with each antenna of a base station from a neighboring base station, and detects at least two or more cell-specific information from the reference signal There,
A first correlation calculation unit that correlates between the received first reference signal and each of the plurality of cell specific information and calculates a first correlation value between the reference signal and each cell specific information;
A first determination unit for determining first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
A correlation between the replica of the component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information is obtained, and a second between the replica and each cell specific information is obtained. A second correlation calculation unit for calculating a correlation value;
A subtraction unit that subtracts the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
A second determination unit for determining second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
Equipped with a,
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers,
For each of the plurality of subcarriers, each subcarrier is multiplied by the square value of the channel estimation value of the subcarrier and the bit value assigned to the subcarrier among the codes corresponding to the first cell specific information. Calculating a multiplication value for a carrier, and multiplying the multiplication value for all of a plurality of subcarriers to generate the replica;
Mobile station. A mobile station that receives a reference signal including any of a plurality of cell-specific information previously associated with each antenna of a base station from a neighboring base station, and detects at least two or more cell-specific information from the reference signal There,
A first correlation calculation unit that correlates between the received first reference signal and each of the plurality of cell specific information and calculates a first correlation value between the reference signal and each cell specific information;
A first determination unit for determining first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
A correlation between the replica of the component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information is obtained, and a second between the replica and each cell specific information is obtained. A second correlation calculation unit for calculating a correlation value;
A subtraction unit that subtracts the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
A second determination unit for determining second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
With
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers,
For each of the plurality of subcarriers, a first integrated value obtained by calculating a square value of a channel estimation value of the subcarrier and integrating the square value for all of the plurality of subcarriers, and the uniqueness of the first cell The second correlation value is calculated by multiplying the inter-code correlation value between the code corresponding to the information and the code corresponding to each of the plurality of cell specific information.
Mobile station. A mobile station that receives a reference signal including any of a plurality of cell-specific information previously associated with each antenna of a base station from a neighboring base station, and detects at least two or more cell-specific information from the reference signal There,
A first correlation calculation unit that correlates between the received first reference signal and each of the plurality of cell specific information and calculates a first correlation value between the reference signal and each cell specific information;
A first determination unit for determining first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
A correlation between the replica of the component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information is obtained, and a second between the replica and each cell specific information is obtained. A second correlation calculation unit for calculating a correlation value;
A subtraction unit that subtracts the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
A second determination unit for determining second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
With
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers,
Multiplying the first correlation value for the first cell specific information by an inter-code correlation value between a code corresponding to the first cell specific information and a code corresponding to each of the plurality of cell specific information. And calculating the second correlation value,
Mobile station. A cell search method for receiving a reference signal including any of a plurality of cell-specific information associated in advance for each antenna of a base station from surrounding base stations and detecting at least two or more cell-specific information from the reference signal Because
Receiving a first reference signal;
Correlating between the first reference signal and each of the plurality of cell specific information, calculating a first correlation value between the reference signal and each cell specific information;
Determining first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
A correlation between the replica of the component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information is obtained, and a second between the replica and each cell specific information is obtained. Calculating a correlation value;
Subtracting the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
Determining second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
Bei to give a,
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers,
The step of calculating the second correlation value includes:
For each of the plurality of subcarriers, each subcarrier is multiplied by the square value of the channel estimation value of the subcarrier and the bit value assigned to the subcarrier among the codes corresponding to the first cell specific information. Calculating a multiplication value for a carrier, and multiplying the multiplication value for all of a plurality of subcarriers to generate the replica;
Cell search method. A cell search method for receiving a reference signal including any of a plurality of cell-specific information associated in advance for each antenna of a base station from surrounding base stations and detecting at least two or more cell-specific information from the reference signal Because
Receiving a first reference signal;
Correlating between the first reference signal and each of the plurality of cell specific information, calculating a first correlation value between the reference signal and each cell specific information;
Determining first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
A correlation between the replica of the component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information is obtained, and a second between the replica and each cell specific information is obtained. Calculating a correlation value;
Subtracting the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
Determining second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
With
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers,
The step of calculating the second correlation value includes:
For each of the plurality of subcarriers, a first integrated value obtained by calculating a square value of a channel estimation value of the subcarrier and integrating the square value for all of the plurality of subcarriers, and the uniqueness of the first cell The second correlation value is calculated by multiplying the inter-code correlation value between the code corresponding to the information and the code corresponding to each of the plurality of cell specific information.
Cell search method. A cell search method for receiving a reference signal including any of a plurality of cell-specific information associated in advance for each antenna of a base station from surrounding base stations and detecting at least two or more cell-specific information from the reference signal Because
Receiving a first reference signal;
Correlating between the first reference signal and each of the plurality of cell specific information, calculating a first correlation value between the reference signal and each cell specific information;
Determining first cell specific information indicating a value having the highest correlation among the first correlation values for each cell specific information;
A correlation between the replica of the component corresponding to the first cell specific information in the first reference signal and each of the plurality of cell specific information is obtained, and a second between the replica and each cell specific information is obtained. Calculating a correlation value;
Subtracting the second correlation value from the first correlation value to generate a third correlation value for each cell specific information;
Determining second cell specific information indicating a value having the highest correlation among the third correlation values for each cell specific information;
With
The reference signal is transmitted from the base station by a plurality of subcarriers,
The cell specific information is a code obtained by cyclically shifting a predetermined sequence, and each bit value of the code is assigned to each of the plurality of subcarriers,
The step of calculating the second correlation value includes:
Multiplying the first correlation value for the first cell specific information by an inter-code correlation value between a code corresponding to the first cell specific information and a code corresponding to each of the plurality of cell specific information. And calculating the second correlation value,
Cell search method.