JP2010028854A - User device and reception method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a PAPR and improve detection probability of an S-SCH (Secondary Synchronization Channel), in cell search. <P>SOLUTION: A base station device is used which includes a plurality of cells each including a plurality sectors and is used in a mobile communication system. The base station device includes a means to generate a synchronization channel used for cell search of the user device, and a means to wirelessly transmit a signal including the synchronization channel. The synchronization channel includes a primary synchronization channel and a secondary synchronization channel. The primary synchronization channel includes a plurality of types of series, and the secondary channel transmitted by a certain sector in a certain cell includes a code derived from a predetermined generated polynomial expression corresponding to the primary synchronization channel. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a radio communication system to which orthogonal frequency division multiplexing OFDM (Orthogonal Frequency Division Multiplexing) is applied in the downlink, and more particularly to a base station apparatus, a mobile station apparatus, and a synchronization channel transmission method.

  Long Term Evolution (LTE) has been studied by W-CDMA standardization organization 3GPP as a successor to W-CDMA and HSDPA, and as a radio access method, downlink is OFDM and uplink SC-FDMA (Single-Carrier Frequency Multiple Access) has been studied (see, for example, Non-Patent Document 1).

  OFDM is a method in which a frequency band is divided into a plurality of narrow frequency bands (subcarriers) and data is transmitted on each frequency band, and the subcarriers interfere with each other even though they partially overlap on the frequency. By arranging them closely, it is possible to achieve high-speed transmission and increase frequency utilization efficiency.

  SC-FDMA is a transmission method that can reduce interference between terminals by dividing a frequency band and performing transmission using different frequency bands among a plurality of terminals. Since SC-FDMA has a feature that fluctuations in transmission power are reduced, it is possible to realize low power consumption and wide coverage of a terminal.

  In LTE, two types of CPs, Long CP and Short CP, having different lengths are prepared as cyclic prefix (CP) for reducing the influence of intersymbol interference caused by delay waves in OFDM. For example, the Long CP is applied to a cell having a large cell radius, and is applied when an MBMS (Multimedia Broadcast Multicast Service) signal is transmitted, and the Short CP is applied to a cell having a small cell radius. When the Long CP is applied, the number of OFDM symbols in one slot is 6, and when the Short CP is applied, the number of OFDM symbols in one slot is 7.

  By the way, in general, in a wireless communication system using W-CDMA, LTE, or the like, a mobile station is based on a synchronization signal or the like at power-on, standby, communication, or intermittent reception during communication. Therefore, it is necessary to detect a cell having good radio quality for the local station. This process is called cell search in the sense of searching for a cell to which a radio link is to be connected. The cell search method is generally determined based on the time required for the cell search and the processing load on the mobile station when performing the cell search. That is, the cell search method must be a method in which the time required for the cell search is short and the processing load on the mobile station when performing the cell search is small.

  In W-CDMA, cell search is performed using two types of synchronization signals, Primary SCH (P-SCH) and Secondary SCH (S-SCH). Similarly, in LTE, P- The use of two types of synchronization signals, SCH and S-SCH, has been studied.

  For example, as a cell search method, a cell search method for transmitting a P-SCH having one sequence and an S-SCH having a plurality of sequences at a time interval of once every 5 ms has been studied (Non-Patent Document). 2). In the above method, downlink reception timing from each cell is specified by P-SCH, and reception frame timing detection and cell ID or group of cells (Group ID) are detected by S-SCH transmitted to the same slot. The cell-specific information such as is specified. Here, for the demodulation and decoding of the S-SCH, it is generally possible to use a channel estimation value obtained from the P-SCH. When cell IDs are grouped, the cell IDs are detected from the cell IDs belonging to the group IDs of the detected cells. For example, the cell ID is calculated based on the signal pattern of the pilot signal. For example, the cell ID is calculated based on the P-SCH and the demodulation / decoding of the S-SCH. Alternatively, the cell ID may be included as an information element of the S-SCH without grouping the cell IDs. In this case, the mobile station can detect the cell ID when the S-SCH is demodulated and decoded.

  However, when the cell search method is applied, in an inter-station synchronization system in which signals from each cell are synchronized, based on a channel estimation value obtained from P-SCHs transmitted in the same sequence from a plurality of cells. Since S-SCH transmitted in different sequences from a plurality of cells is demodulated and decoded, there is a problem that the transmission characteristics of S-SCH deteriorates. Here, the transmission characteristics include, for example, the time required for cell search. In the case of a non-stationary synchronization system in which signals from each cell are not synchronized, the reception timing of the P-SCH sequence transmitted from a plurality of cells differs among the plurality of cells. No problem arises.

  In order to prevent the deterioration of S-SCH characteristics in the inter-station synchronization system as described above, a cell search method in which the number of P-SCH sequences is 1 to 2 or more, for example, 3 or 7, has been studied. (Non-Patent Document 3). Alternatively, a method of transmitting P-SCH at different transmission intervals for each cell has been proposed in order to prevent S-SCH characteristic deterioration in the inter-station synchronization system as described above (Non-Patent Document 4). In the above-described method, P-SCH having different reception timings from a plurality of cells can be used in S-SCH demodulation / decoding, so that it is possible to prevent the above-described deterioration of S-SCH characteristics.

  By the way, it is considered that the larger the number of P-SCH sequences in Non-Patent Document 3 and the type of P-SCH transmission interval in Non-Patent Document 4 described above, the better. This is because, when the number of P-SCH sequences and the types of P-SCH transmission intervals are small, the probability that the P-SCH sequences are the same in adjacent cells, or the P-SCH transmission intervals are the same. This is because the probability of S-SCH characteristic deterioration in the inter-station synchronization system increases.

  In addition, the time required for the cell search, that is, the cell search transmission characteristics and the processing load of the mobile station when performing the cell search are in a trade-off relationship, and the cell setting depends on the parameter setting or operation method. It is desirable to be able to select whether the transmission characteristics of search are important or whether the processing load of the mobile station is important when performing cell search.

3GPP TR 25.814 (V7.0.0), "Physical Layer Aspects for Evolved UTRA," June 2006 R1-062990, Outcome of cell search drafting session R1-062636, Cell Search Performance in Tightly Synchronized Network for E-UTRA R1-070428, Further analysis of initial cell search for Approach 1 and 2-single cell scenario 3GPP TS 36.211 V1.0.0 (2007-03) 3GPP R1-060042 SCH Structure and Cell Search Method in E-UTRA Downlink 3GPP R1-071584 Secondary Synchronization Signal Design 3GPP R1-071794 C. Chu, "Polyphase codes with good periodiccorrelation properties," IEEE Trans. Inform. Theory, vol. II-18, pp.531-532, July 1972 R.L.Frank and S.A.Zadoff, "Phase shift pulse codes with good periodic correlation properties," IRE Trans. Inform. Theory, vol. IT-8, pp. 381-382, 1962. M.J.E.Golay, "Complementary Series," IRE Trans. Inform. Theory, vol. 7, pp. 82-87, April 1961 3GPP, R1-062487 Hierarchical SCH signals suitable for both (FDD and TDD) modes of E-UTRA 3GPP, R1-070146, S-SCH Sequence Design 3GPP, R1-072093, Details on SSC Sequence Design 3GPP, R1-072661, Scrambling Method for Two S-SCH Short Code

  However, the background art described above has the following problems.

  As described above, the synchronization channel (SCH) is downlink signaling used for cell search. Hierarchical SCH is determined to be applied to this synchronization channel (see Non-Patent Document 5, for example). That is, it is composed of two subchannels, a primary synchronization channel (Primary SCH) and a secondary synchronization channel (Secondary SCH).

  Among the primary synchronization channel and the secondary synchronization channel, in the secondary synchronization channel, cell-specific information such as a cell ID group, radio frame timing, and transmission antenna number information is notified. The user apparatus detects cell-specific information by detecting a secondary synchronization channel sequence.

  As described above, in the W-CDMA (Wideband Code Division Multiple Access) system, a neighbor cell search is performed when handover is performed. Prior to this neighbor cell search, cell-specific information (neighbor cell information) of neighbor cells is performed. Is notified to the user device in advance. In a neighboring cell search for detecting a cell that is a handover destination during communication or standby, if neighboring cell information or the like is notified in advance, the number of candidate cell-specific information to be detected can be reduced. . However, in the LTE system, whether or not such neighboring cell information is notified has not been determined in detail at present.

As a secondary synchronization channel sequence mapping method, a method of mapping different sequences in the frequency direction has been proposed (see, for example, Non-Patent Document 6 and Non-Patent Document 7). For example, as shown in FIG. 1, an orthogonal sequence 1 (P ₁ (0), P ₁ (1),..., P ₁ (31)) and an orthogonal sequence 2 (P ₂ (0), P ₂ (1) ),..., P ₂ (31)) may be alternately mapped every other subcarrier. Also, for example, as shown in FIG. 2, orthogonal sequence 1 (P ₁ (0), P ₁ (1),..., P ₁ (31)) and orthogonal sequence 2 (P ₂ (0), P ₂ (1),..., P ₂ (31)) may be mapped to consecutive subcarriers. By dividing the sequence into a plurality of groups in this way, the number of patterns that can be transmitted can be increased. Specifically, for example, when one type of sequence having a sequence length of 64 is used, 64 types of patterns can be transmitted, whereas as shown in FIG. 2, two types of sequences having a sequence length of 32 are used. 1024 types of patterns can be transmitted.

  Up to now, as a sequence of synchronization channels, a plurality of, for example, three types of Zadoff-Chu sequences are used for P-SCH, and a binary sequence is used for S-SCH. It is determined to be a combination of short codes (for example, see Non-Patent Documents 5 and 8).

  It is also known that when such an S-SCH sequence is used, the PAPR (peak-to-average power ratio) may increase, particularly in a 1.25 MHz system.

  Also, P-SCH and S-SCH are transmitted in the same 1 ms subframe, and a subframe including P-SCH and S-SCH occurs every 5 ms. In other words, the synchronization channel is transmitted every 5 ms. The user apparatus obtains a channel estimation value in the serving sector by receiving a different P-SCH for each sector, performs channel compensation for S-SCH different for each cell based on the channel estimation value, and performs S-SCH Cell search is performed by demodulating. In the present application, “cell” and “sector” are used synonymously unless there is a risk of confusion, but “cell” is used to mean including a plurality of “sectors” as necessary. In an inter-station synchronization system in which signals from each cell are synchronized, the mobile station receives signals from a plurality of cells simultaneously. Users near the sector boundary belonging to the same base station can determine the sector because they receive a different P-SCH for each sector, but since the S-SCH from each sector is common, the S-SCH is a combination of both sectors. Received as a signal. It is not easy to compensate the channel of this S-SCH only by the channel estimation value in the serving sector. For this reason, there exists a possibility that the detection probability of S-SCH may deteriorate. If each cell transmits the same S-SCH every 5 ms, such interference may occur every 5 ms, and the S-SCH detection probability at the mobile station may decrease.

  Thus, an object of the present invention is to improve the S-SCH detection probability in cell search.

In one embodiment, user equipment is used. The user apparatus receives a signal including a synchronization channel, extracts a primary synchronization channel from the synchronization channel, specifies a primary synchronization channel sequence number, extracts a secondary synchronization channel from the synchronization channel, Based on the primary synchronization channel sequence number identified in the identification unit, a detection unit that descrambles the secondary synchronization channel,
In the signal received by the receiving unit, a plurality of types of primary synchronization channels are defined so as to correspond to each of a plurality of types of primary synchronization channel sequence numbers, and a plurality of types of primary synchronization channel sequence numbers are included in the secondary synchronization channel. A scramble code derived from a predetermined generator polynomial is used corresponding to each of the above.

  According to the embodiment of the present invention, the S-SCH detection probability in cell search can be improved.

It is explanatory drawing which shows the mapping method of a S-SCH series. It is explanatory drawing which shows the mapping method of a S-SCH series. It is a block diagram which shows the structure of the radio | wireless communications system based on one Example of this invention. It is explanatory drawing which shows a radio | wireless frame structure. It is explanatory drawing which shows the structure of a sub-frame. It is a partial block diagram which shows the base station apparatus which concerns on one Example of this invention. It is a block diagram which shows the baseband signal processing part of the base station apparatus which concerns on one Example of this invention. It is explanatory drawing which shows an example of a definition of a synchronizing signal transmission pattern. The figure for demonstrating the determination method of a S-SCH series is shown. The figure for demonstrating another determination method of a S-SCH series is shown. The figure for demonstrating another determination method of a S-SCH series is shown. It is a partial block diagram which shows the mobile station apparatus which concerns on one Example of this invention. It is a flowchart which shows the cell search method based on one Example of this invention. It is explanatory drawing which shows the production | generation method of the scramble code in a primary alerting | reporting channel. It is a figure which shows the transmission method of SCH. It is a figure which shows the modification of a synchronizing signal generation part.

  Embodiments of the present invention will be described below with reference to the drawings. In all the drawings for explaining the embodiments, the same reference numerals are used for those having the same function, and repeated explanation is omitted.

<System>
A radio communication system having a mobile station and a base station apparatus according to an embodiment of the present invention will be described with reference to FIG.

The wireless communication system 1000 is a system to which, for example, Evolved UTRA and UTRAN (also known as Long Term Evolution, or Super 3G) is applied. The wireless communication system 1000 includes a base station device (eNB: eNode B) 200 _m (200 ₁ , 200 ₂ , 200 ₃ ,..., 200 _m , m is an integer of m> 0), a base station device 200 _m A plurality of mobile stations 100 _n (100 ₁ , 100 ₂ , 100 ₃ ,... 100 _n , where n is an integer of n> 0). Base station apparatus 200 is connected to an upper station, for example, access gateway apparatus 300, and access gateway apparatus 300 is connected to core network 400. The mobile station 100 _n communicates with the base station apparatus 200 _{m using} Evolved UTRA and UTRAN in any of the cells 50 _k (50 ₁ , 50 ₂ ,..., 50 _k , k is an integer of k> 0).
Here, the mobile station 100 _n establishes a communication channel with any one of the base station devices 200 _m and establishes a communication channel with any one of the base stations 200 _m and the base station 200 _m , so that there is no communication. It is assumed that things in a state are mixed.

The base station device 200 _m transmits a synchronization signal. The mobile station 100 _n is located in one of the cells 50 _k (50 ₁ , 50 ₂ , 50 ₃ ,... 50 _k , k is an integer of k> 0), and is powered on or in communication At the time of intermittent reception or the like, a cell search for detecting a cell having good radio quality for the own station is performed based on the synchronization signal. In other words, the mobile station 100 _n detects the symbol timing and the frame timing using the synchronization signal, and uses a cell ID (cell-specific scramble code generated from the cell ID) or a set of cell IDs (hereinafter cell ID). Cell-specific control information such as a group) is detected.

Here, the cell search is performed both when the mobile station 100 _n is in a communication state and when it is in a no-communication state. For example, the cell search in the communication state includes a cell search for detecting a cell having the same frequency and a cell search for detecting a cell having a different frequency. In addition, cell search in the wireless communication state includes, for example, cell search at power-on and cell search at standby.

Hereinafter, since the base station apparatus 200 _m (200 ₁ , 200 ₂ , 200 ₃ ,... 200 _m ) has the same configuration, function, and state, the base station apparatus 200 _m is hereinafter referred to as the base station 200 _m unless otherwise specified. Proceed with the explanation. Hereinafter, since the mobile station 100 _n (100 ₁ , 100 ₂ , 100 ₃ ,... 100 _n ) has the same configuration, function, and state, the following description will be given as the mobile station 100 _n unless otherwise specified. To proceed. Hereinafter, since the cells 50 _k (50 ₁ , 50 ₂ , 50 ₃ ,... 50 _k ) have the same configuration, function, and state, the following description will be given as the cell 50 _k unless otherwise specified. .

  Radio communication system 1000 employs OFDM (Orthogonal Frequency Division Multiple Access) for the downlink and SC-FDMA (Single Carrier Frequency Division Multiple Access) for the uplink as the radio access scheme. As described above, OFDM is a scheme in which a frequency band is divided into a plurality of narrow frequency bands (subcarriers) and data is transmitted on each frequency band. SC-FDMA is a transmission method that can reduce interference between terminals by dividing a frequency band and performing transmission using different frequency bands among a plurality of terminals.

  Here, communication channels in Evolved UTRA and UTRAN will be described.

For the downlink, a physical downlink shared channel (PDSCH) shared by each mobile station 100 _n and a downlink control channel for LTE are used. In the downlink, the mobile station information and transport format information mapped to the physical downlink shared channel, the mobile station information mapped to the physical uplink shared channel, and the transport format information using the LTE downlink control channel Information, acknowledgment information of the physical uplink shared channel, etc. are notified, and user data is transmitted through the physical downlink shared channel.

In the downlink, the base station apparatus 200 _m transmits a synchronization signal for the mobile station 100 _n to perform cell search.

For the uplink, a physical uplink shared channel (PUSCH) shared by each mobile station 100 _n and an uplink control channel for LTE are used. There are two types of uplink control channels: a physical uplink shared channel and a time multiplexed channel, and a frequency multiplexed channel.

  In the uplink, downlink quality information (CQI: Channel Quality Indicator) to be used for physical shared channel scheduling in the downlink, adaptive modulation and coding (AMC: Adaptive Modulation and Coding) by the uplink control channel for LTE. And acknowledgment information (HARQ ACK information) of the downlink physical shared channel is transmitted. Further, user data is transmitted through the physical uplink shared channel.

  In downlink transmission, as shown in FIG. 4, one radio frame (Radio Frame) is 10 ms, and there are 10 subframes in one Radio Frame. Further, as shown in FIG. 5, one subframe is composed of two slots, and one slot includes seven OFDM symbols when a short CP is used (upper diagram in FIG. 5). When a long CP is used, it is composed of six OFDM symbols (the lower diagram in FIG. 5).

<Base station apparatus eNB>
Next, base station apparatus 200 _{m according} to an embodiment of the present invention will be described with reference to FIG.

  The base station apparatus 200 according to the present embodiment includes a transmission / reception antenna 202, an amplifier unit 204, a transmission / reception unit 206, a baseband signal processing unit 208, a call processing unit 210, and a transmission path interface 212.

Packet data transmitted from the base station apparatus 200 _m to the mobile station 100 _n via the downlink is subjected to baseband signal processing from the upper station located above the base station apparatus 200, for example, the access gateway apparatus 300 via the transmission path interface 212. Input to the unit 208.

  The baseband signal processing unit 208 divides and combines packet data, RLC layer transmission processing such as RLC (radio link control) retransmission control transmission processing, MAC retransmission control, for example, HARQ (Hybrid Automatic Repeat Request) transmission processing, Scheduling, transmission format selection, channel coding, inverse fast Fourier transform (IFFT) processing is performed, and the data is transferred to the transmission / reception unit 206. The baseband signal processing unit 208 performs a synchronization signal generation process as will be described later. The synchronization signal is multiplexed with the packet data and transferred to the transmission / reception unit 206.

  The transmission / reception unit 206 performs frequency conversion processing for converting the baseband signal output from the baseband signal processing unit 208 into a radio frequency band, and then is amplified by the amplifier unit 204 and transmitted from the transmission / reception antenna 202. Here, the baseband signal is the above-described packet data, synchronization signal, or the like.

On the other hand, for data transmitted from the mobile station 100 _n to the base station apparatus 200 _m via the uplink, a radio frequency signal received by the transmission / reception antenna 202 is amplified by the amplifier unit 204, and frequency-converted by the transmission / reception unit 206. It is converted into a band signal and input to the baseband signal processing unit 208.

  The baseband signal processing unit 208 performs FFT processing, error correction decoding, MAC retransmission control reception processing, and RLC layer reception processing on the input baseband signal, and the access gateway device via the transmission path interface 212 300.

  The call processing unit 210 performs state management of the radio base station 200 and resource allocation.

  Next, the configuration of the baseband signal processing unit 208 will be described with reference to FIG. In addition, since the embodiment according to the present invention mainly relates to the downlink, in the same figure, the portion related to the downlink processing is shown, and the portion related to the uplink processing is omitted.

The baseband signal processing unit 208 includes a RLC processing unit _{208 1, MAC (Medium Access Control} ) processing unit 208 _2, an encoding unit 208 _3, a data modulation unit 208 _4, a multiplexing unit 208 _5, deserializer and parts 208 _6, a multiplier 208 _7, a multiplier 208 _8, a scramble code generator 208 _9, an amplitude adjusting unit _{208 10,} a combining unit _{208 11,} and IFFT (IDFT) _{208 12,} CP adding section 208 ₁₃ and a synchronization signal generation unit 209.

Transmission data sequence of downlink packet data received from the transmission path interface unit, in the RLC processing unit 208 _1, segmentation and concatenation, transmission processing of RLC layer transmission processing such as the RLC retransmission control is performed, MAC processor 208 in _2, the transmission processing of HARQ (Hybrid Automatic Repeat reQuest), scheduling, selection of transmission format, after the transmission processing of the MAC layer assignment such frequency resources is performed, encoded in the encoding unit 208 _3, a data is data modulated in modulation section 208 _4. Then, the transmission data sequence which is data-modulated, pilot symbol in multiplexing section 208 ₅ are multiplexed, the transmission data sequence in which the pilot symbols are multiplexed, on the frequency axis is parallel conversion in the serial-parallel conversion unit 208 ₆ It is converted into N information symbol sequences and arranged on the frequency axis. Here, the pilot symbol is, for example, a downlink reference signal (DL-RS: Downlink Reference Signal). For N information symbol sequences aligned on the frequency axis, in each of N multipliers 208 _7, the scrambling code scrambling code generating unit 208 ₉ outputs is multiplied in the frequency direction, further, the scrambling code Is multiplied by the amplitude adjustment sequence value output from the amplitude adjustment unit 208 _{10 in} each of the N multiplication units 208 ₈ , and is output to the synthesis unit 208 ₁₁ . Combining unit 208 _11, the symbol sequence of the scrambling code and amplitude adjusting sequence value-multiplied sequence length N, the sync signal generated in the synchronization signal generating unit 209, specific to corresponding one of the N subcarriers Multiplex on subcarriers.

As described later, subframes and slots synchronization signal is transmitted is determined by the synchronization signal control unit 209 _1. In subframe numbers and slot number synchronization signal is transmitted, the synchronization signals synchronizing signal generated by the generation unit 209, combining unit 208 ₁₁ other signals (scramble code and amplitude adjusting sequence value to the downlink packet data (Symbol sequence multiplied by). In the subframe number and slot number to which no synchronization signal is transmitted, the synchronization signal created in the synchronization signal generation unit 209 is not multiplexed. In this case, only the symbol sequence multiplied sequence length N of the scrambling code and the amplitude adjustment sequence value to the downlink packet data is provided to the inverse Fourier transform unit 208 _12. The subcarrier on which the synchronization signal is multiplexed is located in a band including the center of the entire bandwidth, for example. The bandwidth of the subcarrier on which the synchronization signal is multiplexed is, for example, 1.25 MHz.

The inverse Fourier transform unit (IFFT unit) 208 ₁₂ converts the N symbols into orthogonal multicarrier signals. CP adding section _{208 13,} to the multi-carrier signal for each Fourier target time, it inserts a CP. There are two types of CP length (CP length), Long CP and Short CP, and which CP length is used for each cell is selected.

A synchronization signal generation process in the synchronization signal generation unit 209 will be described. The synchronization signal includes a first synchronization signal (hereinafter referred to as a primary synchronization channel, a primary synchronization channel or P-SCH) and a second synchronization signal (hereinafter referred to as a secondary synchronization channel, a secondary synchronization channel or S-). (Referred to as SCH). The synchronization signal generation unit 209 includes a synchronization signal control unit 209 ₁ , a synchronization signal generation unit 209 ₂ , a data modulation unit 209 ₃ , a serial / parallel conversion unit 209 ₄ , a multiplier 209 _5, and an amplitude adjustment unit 209 ₆ It comprises. Synchronization signal generator 209 ₂ includes a P-SCH generator 252, the S-SCH generation unit 254, a multiplication unit 256, includes a scrambling sequence generating unit 258, and a multiplexing unit 260. Synchronization signal control section 209 ₁ is connected to P-SCH generation section 252, S-SCH generation section 254, scramble sequence generation section 258 and multiplexing section 260 of synchronization signal generation section 209 ₂ .

The synchronization signal control unit 209 ₁ is configured such that the base station apparatus 200 _m provides a P-SCH sequence number and an S-SCH sequence number based on the cell ID or cell ID group of a cell for which communication using Evolved UTRA and UTRAN is provided. And a subframe number and a slot number in which P-SCH and S-SCH are transmitted are determined. For example, after specifying the cell ID group, the mobile station may specify the cell based on the pilot signal, that is, the signal pattern of the Reference Signal. In this case, for example, the reference signal signal pattern and the cell ID are defined in advance. Or a mobile station may specify a cell based on the demodulation and decoding of P-SCH and S-SCH, for example. In this case, for example, the P-SCH sequence number and the cell ID information are defined in advance. In P-SCH, for example, a different sequence is selected for each sector. For example, the P-SCH sequence of a three-sector cell is selected from a set including three different sequences.

The synchronization signal control unit 209 _1, the sequence number of the P-SCH and informs the P-SCH generation unit 252, and notifies the sequence number of the S-SCH to the S-SCH generation unit 254. Further, the synchronization signal control unit 209 _1, a subframe number and the slot number the P-SCH and S-SCH are transmitted, and notifies the multiplexing unit 260 as synchronization signal transmission timing information.

For example, as shown in Non-Patent Document 5 and FIG. 8, the wireless communication system 1000 defines a subframe number and a slot number in which P-SCH and S-SCH are transmitted. In this example, a plurality of types, for example, three types of P-SCH sequences are used, and a synchronization signal is transmitted in subframe number # 1 and subframe number # 6. Also, in this example, the P-SCH is mapped to the last OFDM symbol of the slot, so that the mobile station uses the P-SCH regardless of whether the Long CP or the Short CP is used. Can be demodulated. The reason is that, in the last OFDM symbol of the slot, the sixth OFDM symbol when the Long CP is applied and the seventh OFDM symbol when the Short CP is applied coincide in time. In other words, the timing at the beginning and end of the slot is the same for both the short CP and the long CP. At this time, the wireless communication system may associate the P-SCH sequence number and the cell ID information in advance. By such an association is performed by the wireless communication system 1000, the synchronization signal control unit 209 ₁ of the base stations 200 _m of the cell in which the base stations 200 _m provides communications using the Evolved UTRA and UTRAN The P-SCH sequence number can be determined based on the cell ID.

In general, the communication area provided by the base station apparatus 200 _m is divided into two or more areas. This is called sectorization. When the base station apparatus 200 _m has a plurality of sectors, the cell ID or the cell ID group may be used as an ID of an area combining all the sectors of the base station apparatus 200 _{m. It} may be used as the ID of each sector of _m . When a cell ID or a cell ID group is used as an ID of an area including all sectors of the base station apparatus 200 _m , the synchronization signal sequence, a subframe number and a slot number in which the synchronization signal is transmitted, Is set for each base station apparatus 200 _m . When the cell ID or the cell ID group is used as the ID of each sector of the base station apparatus 200 _m , the combination of the synchronization signal sequence and the subframe number and slot number to which the synchronization signal is transmitted is It is set for each sector of the station apparatus 200 _m .

  Examples of P-SCH sequences include CAZAC (Constant Amplitude Zero Autocorrelation sequence) sequences such as Zadoff-Chu sequences (Non-patent Document 9), Frank sequences (Non-patent Document 10), Modulated Frank sequences (Non-Patent Document 10), and Galley Coal. A series (Non-Patent Document 11), a Double Repeat Goal Complementary sequence (Non-Patent Document 12), a PN (Pseudo Noise) series, or the like may be used.

  Further, as the S-SCH sequence, a non-orthogonal sequence or a scramble sequence that is an orthogonal sequence may be a two-layer S-SCH sequence (Non-patent Document 13) obtained by multiplying an orthogonal sequence or a non-orthogonal sequence. An S-SCH sequence in which a plurality of orthogonal sequences or non-orthogonal sequences are alternately arranged in the frequency domain may be used, or a plurality of orthogonal sequences or non-orthogonal sequences may be multiplied by a scramble sequence that is a non-orthogonal sequence or an orthogonal sequence An S-SCH sequence (Non-Patent Document 6) may be used, or an S-SCH sequence (Non-Patent Document 7) in which a plurality of orthogonal sequences or non-orthogonal sequences are arranged in consecutive subcarriers may be used. An S-SCH sequence in which a plurality of orthogonal sequences or non-orthogonal sequences are arranged in consecutive subcarriers and multiplied by a scramble sequence that is a non-orthogonal sequence or an orthogonal sequence may be used. As the orthogonal sequence, a Walsh-Hadamard sequence, a phase rotation orthogonal sequence, and an orthogonal M sequence may be used. As the non-orthogonal sequence, a CAZAC sequence such as a GCL sequence, a Golay sequence, and the like. , Golay Complementary sequence (Non-Patent Document 11), M-sequence (Non-Patent Document 14), PN sequence, and the like may be used.

P-SCH generator 252 and the S-SCH generation unit 254, based on the notified synchronization signal sequence information and synchronization signal transmission timing information by the synchronization signal control unit 209 _1, generates a P-SCH sequence and S-SCH sequence, respectively To do.

For example, the synchronization signal generator 209 _2, when generating the S-SCH, may be a hierarchy of cell-specific information reported in S-SCH. The cell-specific information includes at least one information among cell ID group, radio frame timing, and transmission antenna number information. Here, when the mobile station performs a cell search, the wireless communication system 1000 may notify a part of the layered information as prior information such as neighboring cell information. For example, as a prior information, a cell ID group may be notified, a part of the cell ID group may be notified, a radio frame timing may be notified, or transmission antenna number information may be notified. Alternatively, any one piece of information may be included among information obtained by combining a part of the cell ID group, the cell ID group, the radio frame timing, and the transmission antenna number information. In this way, the number of sequences detected when the mobile station performs cell search can be reduced.

  Specifically, for example, as shown in FIG. 9A, the cell ID group is divided into a plurality of types of sequences, for example, two types of sequences each including a sequence including a short code of 31 sequence length. The “first short code” on the vertical axis in the figure indicates the sequence index of the first short code when two types of short codes having a sequence length of 31, for example, are used in the S-SCH sequence. In the figure, the “second short code” on the horizontal axis indicates the sequence index of the second short code. Although 31 sequence indexes are prepared, as described above, the number of sequence indexes assigned to the first short code and the second short code may be limited as necessary.

  As shown in the figure, the sequence index of the first short code used at (frame) timing # 1 is selected from the first numerical range (0-13). The sequence index of the second short code used at the timing # 1 is selected from the second numerical range (23-30). The sequence index of the first short code used at timing # 2 after 5 ms from timing # 1 is selected from the second numerical range (23-30). The sequence index of the second short code used at timing # 2 is selected from the first numerical range (0-13).

  Thus, if the numerical ranges of the sequence indexes used at the first and second timings are not overlapped with each other, the number of code candidates when searching for each of the first and second short codes is small, and the search can be performed quickly. In addition, when the sequence index of the first short code is detected, it is advantageous in that it quickly becomes clear that it corresponds to the timing # 1.

  FIG. 9B is a diagram for explaining another method for determining an S-SCH sequence. In the illustrated example, the sequence indexes of the first and second short codes are selected from the same numerical range (0-30). For convenience of explanation, the sequence indexes of the first and second short codes are m and n. In the illustrated example, a combination of m and n is selected so that, for example, mn ≦ Δ or nm ≦ Δ is satisfied. m and n are integers of 0-30, and Δ is an integer of 29 or less. Since the sequence index is selected from a wider numerical range than in the case of FIG. 9A, the degree of freedom of the combination of codes used for the secondary synchronization channel is increased, which is preferable from the viewpoint of easily avoiding collisions. .

  FIG. 10 is a diagram for explaining another method for determining an S-SCH sequence. Also in the illustrated example, the sequence indexes of the first and second short codes are selected from the same numerical range (0-30). However, there is no simple regularity like FIG. 9A, 9B, and the 1st and 2nd short code | cord | chord is variously combined so that the same combination may not arise.

The P-SCH sequence generated by the P-SCH generation unit 252 is input to the multiplexing unit 260, and the S-SCH sequence generated by the S-SCH generation unit 254 is input to the multiplication unit 256. Synchronous signal control unit 209 ₁ inputs information indicating a scrambling sequence to the scrambling sequence generating unit 258. For example, the synchronization signal control unit 209 ₁ inputs information indicating a common scrambling code in all cells to the scramble sequence generation unit 258. Scramble sequence generation unit 258, based on the information indicating the scramble sequence that is input by the sync signal controller 209 _1, and inputs to the multiplier 256 to generate a scrambling sequence. In multiplication section 256, the S-SCH is multiplied by the scramble sequence, and the S-SCH sequence multiplied by the scramble sequence is input to multiplexing section 260. The scramble sequence length may be scrambled (spread) across two types of short codes, or scrambled for each of the two types of short codes. For example, system information for the S-SCH sequence, for example, any of frame timing, cell ID group, transmission antenna number information, and the like may be notified by a plurality of types of scramble sequences. By doing so, it is possible to reduce the PAPR of the S-SCH sequence, particularly in a 1.25 MHz system.

However, when adjacent cells and / or cells in the same base station use the same S-SCH sequence, the detection probability of S-SCH in the user apparatus deteriorates due to interference from the adjacent cells. For this reason, cell search takes time, and cell search time characteristics deteriorate. By randomizing the interference from the interference from neighbor cells, from the viewpoint of solving this problem, the synchronization signal control unit 209 ₁ supplies information indicating different scrambling sequence for each cell from among a plurality of types of scrambling codes It is preferable to input to the scramble sequence generation unit 258. In this case, different S-SCH scrambling codes may be used for each cell, that is, a plurality of types of scrambling sequences may be used, or different scrambling sequences may be used for each base station. In this case, the scramble sequence generation unit 258, based on the information indicating the scramble sequence that is input by the sync signal controller 209 _1, and inputs to the multiplier 256 to generate a scrambling sequence. Here, the scramble sequence to be generated may be a scramble sequence specific to the P-SCH sequence associated with the P-SCH sequence number. For example, as described in Non-Patent Document 15, a scramble sequence specific to the sequence number of one of the two short codes may be generated. Multiplier 256 multiplies the S-SCH sequence by the scramble sequence input by scramble sequence generator 258 and inputs the result to multiplexer 260. The scramble sequence length may be scrambled over two types of short codes, or may be scrambled for each of the two types of short codes. For example, the scramble sequence to be multiplied may be a scramble sequence unique to all cells, a scramble sequence unique to the P-SCH sequence, a plurality of types of scramble sequences, or two types. Of these short codes, a scramble sequence specific to the sequence number of one short code may be used. Further, for example, one of the two types of short codes may be multiplied by a scramble common to all cells, and the other short code may be multiplied by a scramble sequence specific to the P-SCH sequence. . Also, for example, one of the two types of short codes is multiplied by a scramble sequence specific to the P-SCH sequence, and the other short code is multiplied by a scramble sequence specific to one short code sequence number. You may make it do. For example, system information for the S-SCH sequence, for example, any of frame timing, cell ID group, transmission antenna number information, and the like may be notified by a plurality of types of scramble sequences. Multiplexing unit 260 multiplexes the S-SCH sequence P-SCH sequence and the scrambling sequence is multiplied to the input to the data modulation unit 209 _3.

The synchronization signal sequence generated by the synchronization signal generation unit 209 ₂ is data-modulated by the data modulation unit 209 ₃ , and is further subjected to serial / parallel conversion by the serial / parallel conversion unit 209 ₄ to be converted into N _SCH symbol sequences on the frequency axis. Converted. The multiplier 209 ₅ multiplies the N _SCH symbol signals by the amplitude adjustment sequence value input by the amplitude adjustment unit 209 ₆ and outputs the result to the synthesis unit 208 ₁₁ .

<User device UE>
Next, the mobile station 100 according to the present embodiment is described with reference to FIG.

  The mobile station 100 includes a basic waveform correlation unit 102, a synchronization signal replica generation unit 104, a code sequence multiplication unit 106, an upper layer code correlation unit 108, a timing detection unit 110, and an S-SCH detection unit 112.

  The mobile station 100 inputs the multicarrier signal received by the antenna to the basic waveform correlation unit 102. On the other hand, the synchronization signal replica generation unit 104 generates a synchronization signal replica having a preset basic waveform, and sequentially inputs the synchronization signal replica to the basic waveform correlation unit 102. The basic waveform correlator 102 detects the correlation between the received multicarrier signal and the basic waveform synchronization signal replica. The code sequence multiplication unit 106 multiplies (or reverses the code) the output of the basic waveform correlation unit 102 for the basic waveform by the code sequence. Upper layer code correlation section 108 detects the correlation of the output of code sequence multiplication section 106 with the upper layer code. In this way, P-SCH replica correlation can be performed.

  Timing detection section 110 detects the P-SCH timing and the P-SCH sequence number from the correlation value. When the P-SCH sequence number is detected, descrambling of the S-SCH sequence multiplied by the scramble sequence is performed. Then, based on the detected timing of P-SCH, S-SCH is detected by S-SCH detection section 112 using P-SCH as a reference signal. Here, for example, when the cell ID group is notified as the prior information, the radio frame timing and the transmission antenna number information are detected. If the base station is scrambled, it is necessary to perform descrambling after synchronous detection.

  This will be specifically described.

Cell search is performed by P-SCH and S-SCH included in downlink signals. Note that a cell search is performed based on the P-SCH sequence and the S-SCH sequence defined by the wireless communication system 1000 described above. That is, the cell ID or the cell ID group is detected by detecting the P-SCH sequence and the S-SCH sequence. Then, after detecting the cell ID, broadcast information, for example, a primary broadcast channel is received using a scrambling code associated with the cell ID, and the cell search process is terminated. The details of the P-SCH sequence and the synchronization signal transmission pattern defined by the wireless communication system 1000 are the same as those described in the base station apparatus 200 _m , and will not be repeated.

  For example, when the wireless communication system 1000 defines the synchronization signal transmission pattern in FIG. 8 and the P-SCH sequence number and the cell ID information are associated in advance, the timing detection unit 110 sets the synchronization channel Timing and P-SCH sequence numbers are detected. Further, the S-SCH detection unit 112 may detect cell specific information by performing descrambling with a scramble sequence multiplied by an S-SCH sequence and detecting an information element included in the S-SCH, for example. It becomes possible.

<Synchronous channel transmission / reception>
Next, a synchronization channel transmission method according to the present embodiment will be described.

  The S-SCH generation unit 254 selects a plurality of synchronization signal sequences. For example, at each of the radio frame timings # 1 and # 2, a sequence having a length of 32 including 16 short codes (first layer cell ID group indicator # 1) and a sequence having a length of 32 including 16 short codes (first layer cell ID group indicator # 1). Two types of second layer cell ID group indicator # 2) are selected. Next, the S-SCH generation unit 254 generates prior information to be notified in advance to the mobile station. For example, prior information indicating a first layer cell ID group that is a part of information for specifying a cell ID group is generated. The generated prior information is transmitted.

In addition, the S-SCH generation unit 254 generates a secondary synchronization channel based on the selected sequence of a plurality of synchronization signals. For example, the secondary synchronization channel which shows the 2nd layer cell ID group which is a part of information which specifies a cell ID group with the 1st layer cell ID group which is a part of information which specifies a cell ID group is produced | generated. Synchronous signal control unit 209 ₁ inputs information indicating a scrambling sequence to the scrambling sequence generating unit 258. For example, the synchronization signal control unit 209 ₁ inputs information indicating a common scrambling code in all cells to the scramble sequence generation unit 258. Further, for example, the synchronization signal control unit 209 ₁ inputs information indicating a plurality of types scrambling code to scramble sequence generation unit 258. The secondary synchronization channel is input to the multiplication unit 256, multiplied by the scramble sequence generated by the scramble generation unit 258 in the multiplication unit 256, and transmitted.

  The mobile station detects cell specific information based on the prior information and the secondary synchronization channel.

  Next, a cell search method in the wireless communication system 1000 according to the present embodiment will be described with reference to FIG.

  As a first step, the mobile station detects the correlation between the primary synchronization channel sequence and the received signal, and detects the carrier frequency and timing of the primary synchronization channel (S1102, S1104). As a result, the primary synchronization channel sequence number is detected (step S1106). In this first step, the mobile station may obtain the phase difference of the signal and perform frequency offset compensation.

  If the timing of the primary synchronization channel, the carrier frequency, and the primary synchronization channel sequence number are known, the timing of the secondary synchronization channel and the carrier frequency are also known. The descrambling is performed on the secondary synchronization channel multiplied by the scramble sequence.

  Next, frame timing is detected from the cell-specific secondary synchronization channel sequence used in the secondary synchronization channel (S1108). Since a plurality of (for example, two) synchronization channels are typically arranged in one frame, it is necessary to detect the frame timing after timing detection. Also, a cell ID group is detected from the cell-specific secondary synchronization channel sequence (S1110).

  Here, for example, by reporting a part or all of the cell ID group to the mobile station in advance as prior information, the number of unique information candidates to be detected can be reduced, so that the detection accuracy can be improved. As a result, the characteristics can be improved. As prior information, for example, radio frame timing may be notified, or transmission antenna number information may be notified.

  When the base station has a plurality of transmission antennas, the base station notifies the mobile station of the transmission antenna number information on the secondary synchronization channel, and the mobile station transmits the transmission antenna number information (MIMO (Multiple Input Multiple Output) in the second step). (Number of antennas information) may be detected (S1112). In particular, the transmission station number information used for the base station to transmit the broadcast channel may be detected.

  Next, a cell ID is detected using the cell ID group detected in the second step and the primary synchronization channel sequence number detected in the first step (S1114).

  Next, a radio communication system having a mobile station and a base station apparatus according to another embodiment of the present invention will be described. The configurations of the wireless communication system, the base station apparatus, and the mobile station according to the present embodiment are the same as those described with reference to FIGS. 3, 6, 7, and 11.

In the base station apparatus 200 according to the present embodiment, the synchronization signal control unit 209 _1, based on the P-SCH sequence number, and inputs the information indicating the P-SCH sequence specific scramble sequence to the scramble sequence generation unit 258. In this case, the scramble sequence generation unit 258, based on the information indicating the scramble sequence that is input by the sync signal controller 209 _1, and inputs to the multiplier 256 to generate a scrambling sequence. Multiplier 256 multiplies the S-SCH sequence by a scramble sequence unique to the P-SCH sequence and inputs the result to multiplexing unit 260. In this case, the P-SCH sequence number and the scramble sequence number are explicitly associated in advance. This is different from the case of the first embodiment in which such an explicit association is not made between the P-SCH and the scramble sequence number. Since a different sequence is selected for each sector in P-SCH, S-SCH is multiplied by a different scramble sequence. For example, since the P-SCH sequence of a three-sector cell is selected from a set including three different sequences, the scramble sequence multiplied by the S-SCH sequence is also configured to include three different scramble sequences. Selected from the set.

  The timing detector 110 of the mobile station 100 detects the P-SCH timing and the P-SCH sequence number from the correlation value between the output of the code sequence multiplier 106 and the upper layer code. When the P-SCH sequence number is detected, descrambling of the S-SCH sequence multiplied by the scramble sequence specific to the P-SCH sequence is performed. Then, based on the detected timing of P-SCH, S-SCH is detected by S-SCH detection section 112 using P-SCH as a reference signal.

  In the cell search method, the primary synchronization channel sequence number is detected in step S1106 in the flow described with reference to FIG. Based on the detected primary synchronization channel sequence number, the primary synchronization channel-specific scramble sequence multiplied by the secondary synchronization channel is also known. The descrambling is performed on the secondary synchronization channel multiplied by the scramble sequence specific to the primary synchronization channel. Then, it becomes step S1108.

  In this way, when adjacent cells and / or cells in the same base station use the same S-SCH sequence, it is possible to randomize interference from adjacent cells and detect S-SCH. Probability can be improved. As a result, the time required for the cell search can be shortened, and the cell search time characteristics can be improved.

  In addition, when channel estimation is performed based on a P-SCH sequence in S-SCH detection, channel estimation can be performed in consideration of a channel state for each cell, and channel estimation accuracy can be improved. Since the accuracy of channel estimation can be improved, the detection accuracy of S-SCH can be improved.

  In this embodiment, a P-SCH specific scramble sequence is applied (multiplied) to the S-SCH sequence. Unlike the first embodiment, a predetermined correspondence exists between the P-SCH sequence and the scramble sequence, and the correspondence is known by the mobile station. The mobile station performs SCH symbol timing detection at the initial stage (first stage) of cell search, and at the same time, also detects the P-SCH sequence number. Since the P-SCH sequence number and the scramble sequence number multiplied by the S-SCH have a one-to-one correspondence, the S-SCH scramble sequence number is assigned to the S-SCH scramble sequence number of the first embodiment based on the detected P-SCH sequence number. It can be identified more quickly than the case. For this reason, it is not necessary to detect a plurality of types, for example, three types of S-SCH scrambled sequence numbers. Accordingly, it is possible to generate three types of S-SCH scrambled sequences without increasing the amount of calculation in detecting S-SCH sequences.

  In addition, it is possible to generate 510 types of scramble sequences without increasing the amount of calculation in detecting a primary broadcast channel (P-BCH). As described above, in the detection of the S-SCH sequence, it is possible to use three types of scramble sequences without increasing the amount of calculation. This will be described with reference to FIG. P-SCH includes three types of scramble sequences and is not scrambled. The S-SCH is scrambled by a P-SCH specific scramble sequence, for example, three types of scramble codes. The P-BCH is scrambled by a cell-specific scramble sequence, for example, 510 types of scramble codes. The S-SCH sequence notifies 170 types of cell ID group information using orthogonal sequences, for example, two types of short codes. Therefore, in the demodulation of P-BCH, (3 types of scrambled sequences) × (170 types of cell ID group information) = 510 types of scramble codes can be generated without increasing the amount of calculation.

  Further, when channel estimation is performed based on an S-SCH sequence in P-BCH demodulation, channel estimation can be performed in consideration of a channel state for each cell, and channel estimation accuracy can be improved. Since the accuracy of channel estimation can be improved, the demodulation accuracy of P-BCH can be improved.

FIG. 14 is a diagram for explaining the difference between the conventional example, the first and second embodiments, and the third embodiment described below. In the conventional example, primary synchronization channels P ₁ , P ₂ , and P ₃ are transmitted as P-SCH in sectors 1, ₂ , and ₃ , respectively. For example, as shown in the figure, when the number of sectors per base station is 3, since the P-SCH is different for each sector, the user apparatus can determine the serving sector and can acquire the channel estimation value in the serving sector. . This is the same in the embodiment. In the conventional example, information (SE _i : i is a parameter for distinguishing cells) indicating different secondary synchronization channels is prepared for each cell, and sectors belonging to the same base station transmit the same secondary synchronization channel SE _i . As described above, due to the same signal being transmitted in adjacent sectors, the S-SCH detection probability may deteriorate near the sector boundary.

In the first and second embodiments, the information SE _i indicating the secondary synchronization channel is multiplied by a different scramble code SC _{j for} each sector. Even if SE _i is the same in all sectors, SC ₁ × SE _i , SC ₂ × SE _i , and SC ₃ × SE _i are all different codes if the scramble code SC _j is different for each sector. As a result, different S-SCH can be transmitted for each sector, and S-SCH can be demodulated with high accuracy even near the sector boundary. In the second embodiment, a primary synchronization channel P _i different for each sector and a scramble code SC _i different for each sector are associated with each other in advance, and the correspondence is known by the user apparatus. As a result, the S-SCH can be quickly demodulated after the confirmation of the primary synchronization channel P-SCH.

Since the scramble code is used in the first and second embodiments, some code (SE _i ) to be multiplied by the scramble code must exist. However, in the present invention, the existence of such two types of codes (SC _i and SE _i ) is not essential. In the third embodiment of the present invention, different generator polynomials Q ₁ (X), Q ₂ (X), and Q ₃ (X) are associated with primary synchronization channels P ₁ , P ₂ , and P _{3 that} are different for each sector. . The generator polynomial Q _i (X) is a polynomial for generating a code such as X ⁵ + X ² +1. The sequence generated by the generator polynomial may be any appropriate sequence, but is preferably a linear feedback shift register (LSFR) sequence, more preferably an M sequence. For example, it is assumed that the generator polynomial Q ₁ (X) corresponding to the primary synchronization channel P ₁ of the first sector is a polynomial that generates an M sequence having a code length of 31. In this case, in the first sector, a plurality of any one of the 31 code sequences that can be generated by the generator polynomial Q ₁ (X) is combined and used for the S-SCH. Similarly, in the second sector, a combination of any one of the 31 code sequences that can be generated by the generator polynomial Q ₂ (X) is used in the S-SCH, and in the third sector, it is generated. A combination of any one of the 31 code sequences that can be generated by the polynomial Q ₃ (X) is used for the S-SCH. The user apparatus confirms the serving sector by specifying the primary synchronization channel P-SCH, and a generator polynomial (for example, used in the serving sector based on the correspondence shown in the lower right of FIG. 14) , Q ₁ (X)). Then, the user apparatus confirms which of the 31 codes derivable from the generator polynomial Q ₁ (X) is actually used as the S-SCH by comparing with the received signal. Since the P-SCH (Pi) and the generator polynomial (Qi (X)) have only one-to-one correspondence, if the user apparatus can identify the serving sector, it is derived from the generator polynomial used in other sectors. There is no need to consider any sign. Only codes that can be derived from a generator polynomial corresponding to one of the P-SCHs need be considered. For simplification of explanation, only one generator polynomial corresponds to one sector, but one combination of a plurality of generator polynomials may correspond to one sector. In this case, another sector corresponds to another combination of a plurality of generator polynomials.

FIG. 15 shows a part of the base station apparatus used in the third embodiment. The illustrated portion relates to the synchronization signal control unit 209 ₁ and the synchronization signal generation unit 209 ₂ . FIG. 15 is generally the same as that shown in FIG. 7, but the scramble code generation unit 258 and the multiplication unit 256 are not drawn because a scramble code is not used in this embodiment. However, also in this embodiment, it is possible to use a scramble code. For example, when the same scramble code is used in all sectors, the S-SCH generation unit 254 multiplies the scramble code. Further, as described in Non-Patent Document 15, the S-SCH generation unit 254 generates a scramble code associated with the sequence number of the first short code among the two types of short codes in the S-SCH sequence. The second short code may be multiplied. Correspondence between the primary synchronization channel P-SCH and the generating polynomial Qi (X) is managed by the synchronization signal control unit 209 _1. S-SCH generation unit 254 generates a secondary synchronization channel in accordance with instructions from the synchronization signal control unit 209 _1, and inputs to the multiplexing unit 250. S-SCH generation unit 254 in this embodiment generates a sign based on the generator polynomial specified by the synchronization signal control unit 209 ₁ Qi (X), the sign to be actually used as the S-SCH to the multiplexing unit 260 input. Thereafter the S-SCH laden synchronization channel is transmitted to the data modulation unit 209 _3, is wirelessly transmitted via the already described process.

  In the above-described embodiment, an example in a system to which Evolved UTRA and UTRAN (also known as Long Term Evolution or Super 3G) is applied has been described. However, the mobile station device, the base station device, and the synchronization according to the present invention are described. The channel transmission method can be applied to all systems using orthogonal frequency division multiplexing OFDM (Orthogonal Frequency Division Multiplexing) in the downlink.

  For convenience of explanation, specific numerical examples will be described to facilitate understanding of the invention. However, unless otherwise specified, these numerical values are merely examples, and any appropriate value may be used.

  Although the present invention has been described above with reference to specific embodiments, each embodiment is merely an example, and those skilled in the art will understand various variations, modifications, alternatives, substitutions, and the like. I will. For convenience of explanation, an apparatus according to an embodiment of the present invention has been described using a functional block diagram, but such an apparatus may be realized by hardware, software, or a combination thereof. The present invention is not limited to the above-described embodiments, and various variations, modifications, alternatives, substitutions, and the like are included without departing from the spirit of the present invention.

  Hereinafter, the means taught by the present application will be exemplified.

(Section 1)
A base station apparatus used in a mobile communication system including a plurality of cells including a plurality of sectors,
Means for generating a synchronization channel used for user equipment cell search;
Means for wirelessly transmitting a signal including the synchronization channel;
The synchronization channel comprises a primary synchronization channel and a secondary synchronization channel;
The primary synchronization channel has a plurality of types of sequences,
A base station apparatus in which a secondary synchronization channel transmitted in a sector of a cell includes a code derived from a predetermined generator polynomial corresponding to the primary synchronization channel.

(Section 2)
The base station apparatus according to claim 1, wherein a sequence of codes derived from the predetermined generator polynomial belongs to a linear feedback shift register (LFSR) sequence.

(Section 3)
The base station apparatus according to claim 2, wherein the sequence of codes derived from the predetermined generator polynomial is an M sequence.

(Section 4)
The base station apparatus according to any one of claims 1 to 3, wherein a cell ID group and a radio frame timing are specified by specifying the secondary synchronization channel.

(Section 5)
A user apparatus used in a mobile communication system including a plurality of cells including a plurality of sectors,
Means for receiving a signal including a synchronization channel;
Means for extracting a primary synchronization channel from the synchronization channel and performing a cell search;
Have
The cell search by determining whether a code constituting a secondary synchronization channel in the received synchronization channel is a code derived from a predetermined generator polynomial corresponding to a sector determined from the primary synchronization channel. A user device that is configured to perform

(Section 6)
6. The user equipment according to claim 5, wherein the sequence of codes derived from the predetermined generator polynomial belongs to a linear feedback shift register (LFSR) sequence.

(Section 7)
The user apparatus according to claim 6, wherein the sequence of codes derived from the predetermined generator polynomial is an M sequence.

(Section 8)
The user apparatus according to any one of claims 5 to 7, wherein a cell ID group and a radio frame timing are specified by specifying the secondary synchronization channel.

(Section 9)
A method used in a mobile communication system including a plurality of cells including a plurality of sectors,
Wirelessly transmitting a signal including a synchronization channel to a user equipment;
Receiving a signal including a synchronization channel at a user equipment;
Extracting a primary synchronization channel from the synchronization channel and performing a cell search;
Have
The cell search by determining whether a code constituting a secondary synchronization channel in the received synchronization channel is a code derived from a predetermined generator polynomial corresponding to a sector determined from the primary synchronization channel. The way that was done.

50 _k (50 ₁ , 50 ₂ , 50 ₃ ) Cell 100 _n (100 ₁ , 100 ₂ , 100 ₃ , 100 ₄ , 100 ₅ ) Mobile station 102 Basic waveform correlator 104 Synchronization signal replica generator 106 Code sequence multiplier 108 Upper layer code correlation unit 110 Timing detection unit 112 S-SCH detection unit 200 _m (200 ₁ , 200 ₂ , 200 ₃ ) Base station apparatus 202 Transmission / reception antenna 204 Amplifier unit 206 Transmission / reception unit 208 Baseband signal processing unit 209 Synchronization signal generation unit 210 Call processor 212 Transmission path interface 208 ₁ RLC processor 208 ₂ MAC controller processor 208 ₃ Encoder 208 ₄ Data modulator 208 ₅ Multiplexer 208 ₆ Serial / parallel converter 208 ₇ Multiplier 208 ₈ Multiplier 208 ₉ scrambling code generator _{208 10} amplitude adjusting unit 208 ₁ combining unit _{208 12} inverse Fourier transform unit ₂₀₈ 13 CP adding unit 209 ₁ Synchronization signal control unit 209 ₂ sync signal generator 209 ₃ data modulator 209 ₄ serial-parallel converter 209 ₅ multiplier 209 ₆ amplitude adjusting unit 252 P-SCH Generation unit 254 S-SCH generation unit 256 Multiplication unit 258 Scramble sequence generation unit 260 Multiplexer 300 Access gateway device 400 Core network 1000 Wireless communication system

Claims (10)

A receiver for receiving a signal including a synchronization channel;
A primary synchronization channel is extracted from the synchronization channel, and a identifying unit that identifies a primary synchronization channel sequence number;
A secondary synchronization channel is extracted from the synchronization channel, and based on the primary synchronization channel sequence number identified in the identification unit, a detection unit that descrambles the secondary synchronization channel,
In the signal received by the receiving unit, a plurality of types of primary synchronization channels are defined so as to correspond to each of a plurality of types of primary synchronization channel sequence numbers, and a plurality of types of primary synchronization channel sequence numbers are included in the secondary synchronization channel. A scramble code derived from a predetermined generator polynomial corresponding to each of the above is used.   The user apparatus according to claim 1, wherein a scramble code corresponding to a sector is used in a secondary synchronization channel included in a signal received by the reception unit.   3. The user apparatus according to claim 1, wherein the scramble code derived from the predetermined generator polynomial belongs to a linear feedback shift register (LFSR) sequence.   The user apparatus according to claim 3, wherein the scramble code derived from the predetermined generator polynomial is an M sequence.   The user apparatus according to any one of claims 1 to 4, wherein the detection unit identifies a cell ID group and a radio frame timing by detecting the secondary synchronization channel. Receiving a signal including a synchronization channel;
Extracting a primary synchronization channel from the synchronization channel and identifying a primary synchronization channel sequence number;
Extracting a secondary synchronization channel from the synchronization channel, and descrambling the secondary synchronization channel based on the identified primary synchronization channel sequence number,
In the signal received in the receiving step, a plurality of types of primary synchronization channels are defined so as to correspond to a plurality of types of primary synchronization channel sequence numbers, and the secondary synchronization channel includes a plurality of types of primary synchronization channel sequences. A scramble code derived from a predetermined generator polynomial corresponding to each number is used.   The receiving method according to claim 6, wherein a scrambling code corresponding to a sector is used in the secondary synchronization channel included in the signal received in the receiving step.   8. The receiving method according to claim 6, wherein the scramble code derived from the predetermined generator polynomial belongs to a linear feedback shift register (LFSR) sequence.   The reception method according to claim 8, wherein the scramble code derived from the predetermined generator polynomial is an M sequence.   10. The receiving method according to claim 6, wherein the descrambling step specifies a cell ID group and a radio frame timing by detecting the secondary synchronization channel.