JP2011166769A - Primary synchronization sequence detecting method and apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and apparatus for detecting a primary synchronization sequence. <P>SOLUTION: A primary synchronization detecting method includes the steps of: calculating a cross-correlation value of each sequence of reception signals at continuous sample points having the same length as a local primary synchronization sequence and each local primary synchronization sequence; calculating a normalized cross-correlation value by normalizing each calculated cross-correlation value by utilizing a point value at a sample point in each sequence of reception signals at the continuous sample points; and determining a position and a type of the primary synchronization sequence in the reception signal on the basis of the calculated, maximum, normalized cross-correlation value. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates generally to the communications field. More specifically, the present invention relates to a method and apparatus for detecting a primary synchronization sequence (PSS) from a received signal, for example, TDD-LTE (Time Division Duplex-Long Term Evolution). -Used in mu evolution) systems.

  In the TDD-LTE system, the received signal is related to the time domain signal of the local primary synchronization sequence to obtain the synchronization realization and the cell primary synchronization sequence type. After receiving the signal, it is necessary to detect the primary synchronization sequence from the received signal.

  According to the LTE standard, the primary synchronization sequence has three types (for example, PSS ID0, PSS ID1 and PSS ID2 can be displayed), so after receiving the received signal, specify the type of primary synchronization sequence in the received signal It is necessary to confirm to. In addition, according to the LTE standard, the length of the primary synchronization sequence is 128 bits. Therefore, it is necessary to specifically determine the start position of the primary synchronization sequence in the received signal after receiving the received signal.

  Specifically, according to the LTE standard, there is always a 128-point long PSS signal in the received signal every half frame (ie, 9600 sample points), so the length of the received signal should not be less than 9600 + 128 points. Is preferred. The length of the received signal is particularly preferably just 9600 + 128 points. Thereby, it is ensured that the received signal includes the PSS signal. Therefore, the detection of the primary synchronization sequence is a process of acquiring the start position of the primary synchronization sequence and the type of the primary synchronization sequence substantially among 9600 + 128 points of the received signal.

  However, in actual applications, detecting the primary synchronization sequence from the received signal may be affected by various factors. For example, in the initial stage of cell search, a terminal (ie, user equipment UE) may be subject to uplink signal interference from other adjacent terminals, which affects the primary synchronization sequence detection performance. Further, there is a possibility that a carrier frequency offset (CFO) exists between the base station (BS) and the terminal, which affects the detection performance of the primary synchronization sequence. In addition, interference due to a DC offset may occur in components in the base station or terminal, and this interference affects the detection performance of the primary synchronization sequence.

  The following presents a simplified summary of the disclosed method and apparatus in order to provide a basic understanding of each aspect of the disclosed method and apparatus. It should be understood that this summary is not an exhaustive overview of the disclosed method and apparatus. It is not intended to be key or critical to the invention, nor is it intended to limit the scope of the disclosed method and apparatus. Its purpose is merely to provide a concept in a simplified form and is a preface to the more detailed description that follows.

  The disclosed method and apparatus may include various elements, eg, interference in the process of detecting uplink signals from other terminals, interference in the process of detecting a carrier frequency offset between the base station and the terminal, and / or components in the base station or terminal. It is an object of the present invention to provide a method and apparatus for detecting a primary synchronization sequence in a TDD-LTE system that can at least partially reduce interference with a detection process such as interference due to DC offset.

  The disclosed method and apparatus provide a method and apparatus for detecting a primary synchronization sequence in a TDD-LTE system capable of detecting a primary synchronization sequence from a received signal with high efficiency and time saving in the process of searching for neighboring cells Another purpose is to do.

  Another aspect of the present invention provides computer code that, when executed on a computing device, causes the computing device to perform the process steps of the method, a computer-readable storage medium on which the computer code is stored, and a computer program product. One purpose.

  According to one aspect of the method, a primary synchronization sequence detection method for detecting a primary synchronization sequence from a received signal in a TDD-LTE system is provided. The method includes the steps of calculating a cross-correlation value between an individual sequence of received signals at successive sample points of the same length as the local primary sync sequence and an individual local primary sync sequence; Calculating a normalized cross-correlation value by normalizing the calculated individual cross-correlation values by utilizing the point values of the sample points in the individual sequence, and calculating the maximum normalization Determining the position and type of the primary synchronization sequence in the received signal based on the cross-correlation value determined.

  According to another aspect of the method, there is provided a primary synchronization sequence detection method for detecting a primary synchronization sequence from a received signal from a neighboring cell in a neighboring cell search process when synchronous communication is performed in a TDD-LTE system. . The method comprises the steps of constructing a search window for selecting a series of consecutive sample points from a received signal to detect a primary synchronization sequence, and receiving at successive sample points in the search window of the same length as the primary synchronization sequence. Calculating a cross-correlation value between an individual sequence of signals and an individual local primary synchronization sequence, and determining the position and type of the primary synchronization sequence in the received signal based on the calculated maximum cross-correlation value Includes steps.

  According to one aspect of the apparatus, a primary synchronization sequence apparatus is provided that detects a primary synchronization sequence from a received signal in a TDD-LTE system. The apparatus includes: a cross-correlation value calculating unit that calculates cross-correlation values between individual sequences of received signals at continuous sample points having the same length as the local primary synchronization sequence; and individual local primary synchronization sequences; A normalization unit that calculates a normalized cross-correlation value by normalizing each calculated cross-correlation value by using a point value of a sample point in each sequence of received signals in And a determining unit that determines a position and type of a primary synchronization sequence in the received signal according to the maximum normalized cross-correlation value.

  According to another aspect of the apparatus, there is provided a primary synchronization sequence apparatus that detects a primary synchronization sequence from a received signal from an adjacent cell in a neighboring cell search process when synchronous communication is performed in a TDD-LTE system. A selection unit comprising a search window for selecting a series of consecutive sample points from the received signal to detect a primary synchronization sequence, and individual signals at successive sample points in the search window having the same length as the primary synchronization sequence; The position and type of the primary synchronization sequence in the received signal are determined based on the cross-correlation value calculation unit that calculates the cross-correlation value between the sequence and each local primary synchronization sequence, and the calculated maximum cross-correlation value. And a determination unit.

  According to another aspect, corresponding computer code, a computer readable storage medium and a computer program product are also provided.

These and other advantages of the disclosed method and apparatus will become more apparent from the detailed description of the embodiments given below with reference to the drawings.
The disclosed method and apparatus may be better understood by reference to the following description taken in conjunction with the accompanying drawings, in which the same or similar reference numerals denote the same or similar parts throughout the drawings. The foregoing drawings are included in and constitute a part of this specification, together with the following detailed description, and further by way of example to illustrate the preferred embodiment of the invention and the principles and advantages of the disclosed method and apparatus. Used to interpret

3 illustrates a method for detecting a primary synchronization sequence from a received signal of a TDD-LTE system in one embodiment. FIG. 7 is a schematic diagram showing processing of a cross-correlation value between a received signal sequence and a local primary synchronization sequence at successive sample points having the same length as the local primary synchronization sequence (step S101 in FIG. 1) in another embodiment. FIG. 6 is a schematic diagram showing normalization processing (step S102 in FIG. 1) in another embodiment. It is a flowchart which shows the interference deletion step in another Example. 6 is a flowchart illustrating a process of detecting a primary synchronization sequence from a received signal from a neighboring cell in a neighboring cell search process in the case of synchronous communication of a TDD-LTE system in another embodiment. 1 shows an apparatus for detecting a primary synchronization sequence from a received signal of a TDD-LTE system in one embodiment. 6 shows a detailed structure of the cross-correlation value calculation unit 601 shown in FIG. 6 in another embodiment. FIG. 7 shows a detailed structure of the normalization unit 602 shown in FIG. 6 in another embodiment. It is a schematic diagram which shows the structure of the interference deletion part in another Example. 1 shows an apparatus for detecting a primary synchronization sequence from received signals from neighboring cells in a search process of neighboring cells in the case of synchronous communication in a TDD-LTE system according to one embodiment. FIG. 2 is a block diagram of an exemplary configuration of a general personal computer that can implement the method and / or apparatus according to the embodiments.

  Exemplary embodiments of the disclosed method and apparatus are described below with reference to the drawings.

  In order to avoid obscuring the description of the disclosed method and apparatus due to unnecessary details, the drawings show only apparatus configurations and / or processing steps that are closely related to the disclosed method and apparatus. Other details not relevant to the disclosed method and apparatus have been omitted.

  FIG. 1 is a diagram illustrating a method for detecting a primary synchronization sequence from a received signal of a TDD-LTE system in one embodiment.

  As shown in FIG. 1, after receiving a received signal, a cross-correlation value between the sequence of the received signal and the local primary synchronization sequence at successive sample points is calculated in step S101.

  It should be pointed out that the received signal in step S101 is actually a pre-processed received signal. For example, the pre-processing includes performing a quantization process on a received signal through a DAC (digital analog converter) and performing a high-pass filter with a low-pass filter to remove frequency information other than the primary synchronization sequence code. Can do. Obviously, such a pre-processing process is not the main point of the present invention, and there can be processing methods other than the above-described exemplary processing processes. Therefore, the drawing does not show the pretreatment process. The received signal referred to in the text indicates such a preprocessed received signal. Unless otherwise specified, the length of the received signal in the text is not smaller than 9600 + 128 points.

  FIG. 2 is a schematic diagram showing a process (S101 in FIG. 1) for calculating a cross-correlation value between a received signal sequence and a local primary synchronization sequence at consecutive sample points having the same length as the local primary synchronization sequence according to another embodiment. FIG.

  In this embodiment, for the received signal sequence at the continuous sample point of the same length as the primary synchronization sequence and the local primary synchronization sequence, first, the received signal sequence at the continuous sample point and the local primary synchronization sequence are divided, Then, a partial cross-correlation value between corresponding portions is calculated for each portion, and a cross-correlation value between the received signal sequence and the local primary synchronization sequence at the continuous sample point is calculated based on the partial cross-correlation value.

  As shown in FIG. 2, the process of calculating the cross-correlation value includes the following steps.

  In step S201, a local primary synchronization sequence having a predetermined number of sample points is divided.

  Specifically, the local primary synchronization sequence is equally divided into an appropriate number of parts. For example, it can be divided into 3, 4, 5, etc. Among them, one or several indivisible sample points in the local primary synchronization sequence can be discarded if the number of sample points is not divisible when dividing equally.

  For example, in a TDD-LTE system, the local primary synchronization sequence has 128 bits (ie, 128 sample points). If the local primary synchronization sequence is divided into three equal parts, each part has 42 sample points, and the last two non-equal sample points are discarded.

  In step S202, the sequence of the received signal at the continuous sample points having the same length as the local primary synchronization sequence is divided by the same division method as that of the local primary synchronization sequence.

  Specifically, the sequence of received signals at consecutive sample points having the same length as the local primary synchronization sequence is equally divided into the same number as the number of divisions of the local primary synchronization sequence. Furthermore, the sequence numbers of the division points of the sequence in the received signal sequence are the same as the sequence numbers of the division points of the local primary synchronization sequence in the local primary synchronization sequence.

  For example, in a TDD-LTE system, if the local primary synchronization sequence has 128 bits (ie, 128 sample points) and is equally divided into three parts (throwing out the last two bits), it is 128 in the same manner. The sequence of received signals at a number of consecutive sample points can be equally divided into three parts (of which the last two sample points are discarded).

  In step S203, the partial cross-correlation value of each corresponding portion in the sequence of the received signal at the continuous sample points and the local primary synchronization sequence is calculated.

  Specifically, in each part of the sequence of received signals at consecutive sample points, the conjugate value of the point values at the sample points is multiplied with the point value at the corresponding part in the local primary synchronization sequence to calculate the sum of products. The partial cross-correlation value of the part.

  For example, in a TDD-LTE system, the local primary synchronization sequence has 128 bits, and the received signal includes 9600 sample points, and the local primary synchronization sequence and the sequence of received signals at consecutive sample points are both three. When equally divided, the partial cross-correlation value between the first part of the local primary synchronization sequence and the first part of the received signal sequence at successive sample points is given by equation (1).

C ₁ on the left side of the formula represents a partial cross-correlation value between the first part of the local primary synchronization sequence and the first part of the sequence of received signals at the continuous sample points, and m on the right side of the formula represents the sequence of received signals at the continuous sample points. Represents the start position starting in the received signal, m takes a value from 0 to 9599, r (n + m) represents the point value of the nth sample point after the start position m in the received signal, and r (n + m) ^* Represents the conjugate value of the point value, and PSS (id, n) represents the value of the nth sample point in the primary synchronization sequence (the type is indicated by id), of which three types are id Represents three types of local primary synchronization sequences, and n takes a value from 0 to 41.

Similarly, using equations (2) and (3), the partial cross-correlation value C ₂ between the second part of the local primary synchronization sequence and the second part of the received signal sequence at successive sample points, respectively, and the local primary A partial cross-correlation value C ₃ between the third part of the synchronization sequence and the third part of the sequence of received signals at successive sample points can be calculated.

  In step S204, the cross-correlation value between the received signal sequence and the local primary synchronization sequence at the continuous sample points is calculated based on the partial cross-correlation value calculation result.

  Specifically, the partial cross-correlation value of each part other than the last part is multiplied by the conjugate value of the partial cross-correlation value of the subsequent part to obtain the sum of products, and the square of the sum is further calculated at the continuous sample points. The cross-correlation value between the received signal sequence and the local primary synchronization sequence is used.

  For example, in a TDD-LTE system, the local primary synchronization sequence has 128 bits, and the received signal includes 9600 sample points, and the local primary synchronization sequence and the sequence of received signals at the continuous sample points are all three. In the case of equal division, the cross-correlation value between the received signal sequence and the local primary synchronization sequence at consecutive sample points of the same length as the local primary synchronization sequence can be calculated by Equation (4).

  Note that C (id, m) on the left side of Equation (4) is the same as the local primary synchronization sequence, and the start position in the received signal is m (the range where the value of m is taken is the same as Equation (1). It represents the cross-correlation value between the sequence of received signals and the primary synchronization sequence (the type of which corresponds to the parameter id) at a certain consecutive sample point.

  In this way, the cross-correlation value between the received signal sequence and the local primary synchronization sequence at consecutive sample points of the same length as the local primary synchronization sequence can be calculated.

  Returning to FIG. 1, in step S102, the cross-correlation value calculated using the point value of the sample point in the received signal is normalized. Specifically, the correlation value with the local primary synchronization sequence is calculated in step S101, and normalization is performed with the point value of the sample point in the received signal sequence at successive sample points.

  FIG. 3 is a schematic diagram showing normalization processing (S102 in FIG. 1) according to another embodiment.

  As shown in FIG. 3, in step S301, the received signal sequence at the continuous sample points is divided at the continuous sample points having the same length as the local primary synchronization sequence by the same division method as the local primary synchronization sequence division method. A sum of squares of the point values of each sample point in each part of the signal sequence is calculated, and a normalization factor is calculated based on the calculated sum of squares of the point values of the sample points of each part.

  For example, in the TDD-LTE system, when the received signal sequence at consecutive sample points is equally divided into three parts (of which the last two points are discarded), Equations (5) to (7) are used. Thus, the sum of squares of the point values of the sample points in each portion can be calculated.

In Equations (5) to (7), R ₁ , R ₂ , and R ₃ represent the sum of squares of the point values of the first, second, and third part sample points of the received signal sequence at successive sample points, respectively. , M and the range of values are the same as in Equation (1), and n represents the position number of the sample point in the sequence of received signals at the continuous sample point.

  Further, the normalization factor can be calculated based on the sum of squares of the point values of the sample points of each part calculated.

  For example, in the TDD-LTE system, when the received signal sequence at consecutive sample points is equally divided into three parts (of which the last two points are discarded), Equations (5) to (7) are used. Then, after calculating the sum of squares of the point values of the sample points in each portion, the normalization factor N (m) can be further calculated using Equation (8).

  In Equation (8), N (m) represents a normalization factor for normalizing the cross-correlation value between the sample point sequence starting from the start position m and the local primary synchronization sequence in the received signal.

  In step S302, the cross-correlation value calculated in step S101 can be normalized using the calculated normalization factor. Specifically, normalization can be realized by dividing the cross-correlation value by the normalization factor.

  In the above, the specific processing steps of steps S101 and S102 shown in FIG. 1 according to the embodiment have been described with reference to FIGS. 2 and 3, respectively, but the present invention is not limited to this.

  Returning to FIG. 1, after the normalization process is completed, in step S103, an individual sequence of received signals at successive sample points (its start position is denoted by m, which is the same length as the local primary synchronization sequence, It is determined whether or not the cross-correlation value is calculated for the local primary synchronization sequence.

  If there is a cross-correlation value calculation that has not yet been completed, that is, if there is a sequence of received signals at consecutive sample points for which a cross-correlation value has not yet been calculated, the process returns to step S101, and the cross-correlation is still present. A cross-correlation value between the received signal sequence and the local primary synchronization sequence at consecutive sample points for which values are not calculated is calculated, and further normalized in step S102.

  If it is determined in step S103 that cross-correlation values have been calculated for individual sequences of received signals and consecutive local primary synchronization sequences at the continuous sample points having the same length as the local primary synchronization sequence, Enter step S104.

  In step S104, the position and type of the primary synchronization sequence in the received signal are determined based on the calculated maximum normalized cross-correlation value.

  Specifically, the start position (m) in the received signal at the first sample point of the sequence of received signals at the continuous sample point corresponding to the maximum normalized cross-correlation value is the start position of the primary synchronization sequence in the received signal, The primary synchronization sequence type (id) corresponding to the maximum normalized cross-correlation value is set as the primary synchronization sequence type in the received signal.

  Thus, the position and type of the primary synchronization sequence in the received signal can be detected by the method described above.

  Note that in order to avoid interference due to DC offsets that may be present in base station or terminal components, according to another embodiment, the above method reduces interference due to DC offsets in base station or terminal components. The method may further include an interference deletion step. Preferably, the interference cancellation step can be performed on the received signal before the step of calculating the cross-correlation value.

  FIG. 4 is a flowchart showing the interference deletion step.

  As shown in FIG. 4, in step 401, the received signal can be converted into a frequency domain signal. Preferably, the received signal can be converted from a time domain signal to a frequency domain signal by fast Fourier transform.

  Subsequently, at step 402, interference cancellation due to DC offset can be performed in the frequency domain. Since it is possible to intuitively find the frequency at which the interference due to the DC offset occurs in the frequency domain, it is possible to easily determine which is the frequency at which the interference due to the DC offset has occurred. Therefore, the frequency component in which the interference due to the DC offset directly occurs in the frequency domain and some frequency components around the frequency component are made zero, thereby completing the elimination of the interference due to the DC offset in the frequency domain.

  Subsequently, in step S403, the received signal can be converted back to a time domain signal. Preferably, it can be realized by inverse Fourier transform.

  Thus, the interference of the DC signal from the base station or the terminal component can be deleted from the received signal through the interference deletion step.

  Note that, according to the technical solution of the present invention, various factors, for example, uplink signals from other terminals interfere with the detection process, carrier frequency offset between the base station and the terminal interferes with the detection process, and / or Alternatively, interference in the detection process such as interference due to DC offset in components in the base station or terminal can be reduced. Specifically, for example, a technique for reducing carrier frequency offset interference by a technical means for partial calculation of a cross-correlation value, a technique for reducing interference of an uplink signal by a technical means for normalization, and deleting a DC offset occurrence point in the frequency domain It should be appreciated that the means can reduce interference due to DC offset.

  Since the influence of the carrier frequency offset and the interference of the uplink signal usually exist in the process of initial synchronization when the terminal is connected to the network, the method for detecting the primary synchronization sequence according to the above-described embodiment is the initial method when the terminal is connected to the network. It is preferably applied to the synchronization process.

  In another embodiment, a method for detecting a primary synchronization sequence in a TDD-LTE system is provided. Preferably, the method can detect a primary synchronization sequence in a received signal from an adjacent cell in a neighbor cell search process when the terminal is already connected to the network.

  Among them, the process of neighbor cell search can be divided into two situations: neighbor cell search when the terminal and the network communicate synchronously, and neighbor cell search when the terminal and the network communicate asynchronously. . Preferably, the method according to the embodiment of the present invention can be applied to a neighbor cell search in a situation where a terminal and a network perform synchronous communication.

  Specifically, the application environment of neighboring cell search in the situation of synchronous communication is that the terminal already has one service base station and is communicating synchronously with the service base station, and the service base station is also connected to the terminal. Synchronously communicate with neighboring cells that transmit information. Therefore, the clock frequency of the receiving terminal (that is, the terminal) and the clock frequency of the transmitting terminal (that is, the cell adjacent to the serving base station) match, and there is no carrier frequency offset between the base station and the terminal. Therefore, in such a situation, in the primary synchronization sequence detection process, the local primary synchronization sequence and the local primary synchronization sequence are not divided into the local primary synchronization sequence and the local primary synchronization sequence without dividing the received signal sequence at consecutive sample points of the same length. It is possible to calculate a correlation value with a sequence of received signals at consecutive sample points from adjacent cells having the same length as the primary synchronization sequence.

  In addition, since the clock frequency of the receiving terminal and the clock frequency of the transmitting terminal coincide with each other in the synchronization network, the position of the primary synchronization sequence in the received signal from the current service base station is known, and further, depending on the known position. The search window for searching for the primary synchronization sequence from the received signal received from the adjacent cell can be limited. Thus, the search range can be greatly reduced, and the calculation complexity can be reduced. In this case, since the position search range is greatly reduced, uplink interference can be avoided. This eliminates the need to normalize the correlation value of the sequence in the process of detecting the primary synchronization sequence.

  FIG. 5 is a flowchart for performing a primary synchronization sequence detection process in the above situation.

  In step S501, a search window for detecting a primary synchronization sequence is constructed by selecting a series of consecutive sample points from the received signal.

  For example, in a 10 km cell in a TDD-LTE system, a received signal received from an adjacent cell (hereinafter abbreviated as a received signal) based on the position of a known primary synchronization sequence in a received signal received from a current serving base station. ) To search for the primary synchronization sequence can be limited to a range of W / 2 (for example, 192) sample points before and after the same position as the known position. That is, the width of the search window is W point widths and W> 128. The position of the center point of the search window in the received signal is the same as the position of the known primary synchronization sequence in the received signal received from the current serving base station.

  Subsequently, in step S502, a cross-correlation value between the sequence at the continuous sample points in the search window and the primary synchronization sequence having the same length as the primary synchronization sequence is calculated.

  Specifically, in the situation of synchronous communication, for example, using Equation (9), the cross-correlation value between the local primary synchronization sequence and the sequence of received signals at consecutive sample points of the same length as the local primary synchronization sequence is calculated. To do.

In Equation (9), C ′ is the sequence of the received signal and the primary sync sequence (the type of which is represented by the parameter id) at successive sample points of the same length as the local primary sync sequence, starting at the start position m in the received signal. Represents the cross-correlation value, r (n + m) represents the point value of the nth sample point after the start position m in the received signal, r (n + m) ^* represents the conjugate value of the point value, and PSS is (id , N) represents the value of the nth sample point in the primary synchronization sequence (the type is indicated by id). However, the range of the value of m is W / 2 (for example, 192) points before and after the search window center point, that is, m∈ [MW / 2, M + W / 2], and M is the position of the search window center point. Represents.

  Subsequently, in step S503, individual sequences of received signals at consecutive sample points of the same length as the primary synchronization sequence at the selected sample points (the range of the value of the start position m is W before and after the search window center point W / 2 points) and whether the cross-correlation value is calculated for each primary synchronization sequence.

  If there is a sequence of received signals at consecutive sample points for which a cross-correlation value has not yet been calculated in the search window, the cross-correlation value calculating step S502 is repeated.

  If it is determined in step S503 that cross-correlation values with individual local primary synchronization sequences have already been calculated for all received signal sequences at consecutive sample points of the same length as the local primary synchronization sequence in the search window The process enters step S504.

  In step S504, the position and type of the primary synchronization sequence in the received signal are determined based on the calculated maximum cross-correlation value.

  Specifically, the position (m) in the received signal at the first sample point of the sequence of received signals at the continuous sample points corresponding to the maximum cross-correlation value is the start position of the primary synchronization sequence in the received signal, and the maximum The primary synchronization sequence type (id) corresponding to the cross-correlation value is the primary synchronization sequence type in the received signal.

  Similarly, according to another embodiment, it is preferable that the above method can further include an interference cancellation step. Through this interference cancellation step, it is possible to eliminate interference of DC signals from base station or terminal components in the received signal. Preferably, the interference removal step can be performed on the received signal before the step of selecting a point. The specific implementation of the interference deletion step is the same as that described above, and does not overlap here.

  In addition, according to the above technical solution, when the terminal performs synchronous communication with the network, it is possible to save time and efficiently detect the primary synchronization sequence from the received signals from the neighboring cells.

  In the case of asynchronous communication, the primary synchronization sequence can be detected from a received signal from an adjacent cell using the method shown in FIG. Specifically, by calculating the correlation value between the local primary synchronization sequence and the received signal sequence at the continuous sample points (the length is the same as the local primary synchronization sequence), and normalizing the correlation value Detect primary synchronization sequence.

  In addition to the method for detecting the primary synchronization sequence from the received signal in the TDD-LTE system described above, according to the embodiment, the TDD-LTE system corresponding to the method further detects the primary synchronization sequence from the received signal. An apparatus is provided.

  FIG. 6 shows an apparatus for detecting a primary synchronization sequence from a received signal of a TDD-LTE system in one embodiment.

  As shown in FIG. 6, the primary synchronization sequence detection apparatus 600 for detecting the primary synchronization sequence from the received signal in the TDD-LTE system according to the present invention is configured to receive individual received signals at consecutive sample points having the same length as the local primary synchronization sequence. Correspondence using cross-correlation value calculation unit 601 arranged to calculate cross-correlation value between sequence and individual local primary synchronization sequence, using point value of sample point in individual sequence of received signal at continuous sample point Normalization unit 602 arranged to normalize individual cross-correlation values and thereby obtain a normalized cross-correlation value, and receive based on the calculated maximum normalization cross-correlation value A determiner 603 arranged to determine the position and type of the primary synchronization sequence in the signal; including.

  FIG. 7 shows a detailed structure of the cross-correlation value calculation unit 601 in FIG. 6 according to another embodiment.

  As shown in FIG. 7, the cross-correlation value calculation unit includes a first division unit 701 arranged to divide the local primary synchronization sequence, and individual received signals at consecutive sample points having the same length as the local primary synchronization sequence. A second division unit 702 arranged to divide the sequence of the second signal, and to calculate a cross-correlation value between an individual part of the individual sequence of the received signal at a continuous sample point and a corresponding part of the local primary synchronization sequence The cross-correlation value calculation unit 703 of the portion arranged in the above, the cross-correlation value of each part other than the last part and the cross-correlation value of the part after it, the received signal at the continuous sample points A sequence cross-correlation value calculation unit 704 that calculates a cross-correlation value between the sequence and the local primary synchronization sequence.

  Specifically, the first dividing unit 701 equally divides the local primary synchronization sequence into an appropriate number of parts. Among them, in a situation where it is not divisible when dividing equally, one or more non-divisible sample points can be discarded.

  For example, in a TDD-LTE system, the local primary synchronization sequence has 128 bits (ie, 128 sample points). When the local primary synchronization sequence is equally divided into three parts, each part has 42 sample points, and the last two undivided sample points are discarded.

  The second dividing unit 702 divides the received signal sequence at consecutive sample points whose length in the received signal is the same as that of the local primary synchronization sequence by the same dividing method as that of the local primary synchronization sequence.

  Specifically, the sequence of the received signal at the continuous sample points having the same length as the local primary synchronization sequence is equally divided into the same number as the number of parts of the local primary synchronization sequence. Furthermore, the sequence number of the division point of the sequence in the received signal sequence is the same as the sequence number of the division point of the local primary synchronization sequence in the local primary synchronization sequence.

  For example, in a TDD-LTE system, if the local primary synchronization sequence has 128 bits and is equally divided into three parts (throwing out the last two bits), the same manner, the 128 The received signal sequence at successive sample points may be equally divided into three parts (the last two points are discarded).

  The calculation unit 703 for calculating a partial cross-correlation value is arranged to calculate a cross-correlation value between each part of each sequence of the received signal at the consecutive sample points and a corresponding part in the local primary synchronization sequence.

  Specifically, in each part of the received signal sequence at consecutive sample points, the conjugate value of the point values at the sample points is multiplied by the corresponding point value in the local primary synchronization sequence to calculate the sum of products. Let it be a partial cross-correlation value of the part.

  For example, in a TDD-LTE system, the local primary sync sequence has 128 bits and the received signal contains 9600 sample points, and the local primary sync sequence and the sequence of received signals at consecutive sample points are both in three parts. The partial cross-correlation value calculation unit 703 can calculate the cross-correlation values between the respective parts based on the mathematical expressions (1) to (3).

  Sequence cross-correlation value calculation section 704 is arranged to calculate a cross-correlation value between the received signal sequence and the local primary synchronization sequence at successive sample points based on the partial cross-correlation value calculation result.

  Specifically, the partial cross-correlation value of each part other than the last part is multiplied by the conjugate value of the partial cross-correlation value of one part, and the sum of the products is obtained, and the square of the sum is continuously sampled. The cross-correlation value between the received signal sequence at the point and the local primary synchronization sequence.

  For example, in a TDD-LTE system, the local primary synchronization sequence has 128 bits and the received signal contains 9600 sample points, and each of the local primary synchronization sequence and the received signal sequence at successive sample points has three parts. Sequence cross-correlation value calculation section 704, based on Equation (4), the sequence of the received signal and the local primary synchronization sequence at the consecutive sample points of the same length as the local primary synchronization sequence are calculated. A correlation value can be calculated.

  FIG. 8 shows a detailed structure of the normalization unit 602 in FIG. 6 according to another embodiment.

  As shown in FIG. 8, the normalization unit calculates the sum of squares of the point values of the sample points in the individual parts of the sequence of received signals at the continuous sample points, and the sample points in the individual parts other than the last part. A normalization factor calculation unit 801 arranged to multiply the sum of squares of the point values by the sum of squares of the point values of the sample points in one part and to obtain the sum of the obtained products as a normalization factor, and normalization A normalization execution unit 802 arranged to normalize the cross-correlation value using a factor.

  Specifically, the normalization factor calculation unit 801 equally divides the received signal sequence at the continuous sample points having the same length as the local primary synchronization sequence in the same manner as described above, and each part of the received signal sequence at the continuous sample points. The sum of squares of the point values of each sample point in is calculated.

  For example, in the TDD-LTE system, when the received signal sequence at 128 consecutive sample points is equally divided into three parts, the points of the sample points at each part using Equations (5) to (7) The sum of squares of values can be calculated.

  Furthermore, the normalization factor calculation unit 801 can calculate a normalization factor based on the sum of squares of the calculated point values of each part.

  For example, in the TDD-LTE system, when the sequence of received signals at consecutive sample points is equally divided into three parts, the square of the point values of the sample points at each part using Equations (5) to (7) After calculating the sum, the normalization factor can be further calculated using Equation (8).

  The normalization execution unit 802 can normalize the cross-correlation value calculated using the calculated normalization factor.

  Specifically, normalization can be achieved through dividing the cross-correlation value by the normalization factor.

  In addition, in order to avoid interference due to DC offset that may be present in base station or terminal components, the apparatus of the embodiment includes components in the base station or terminal before the cross-correlation value calculation unit 601. An interference deletion unit may be further included to reduce interference due to the DC offset.

  FIG. 9 is a schematic diagram of a configuration of an interference deletion unit according to another embodiment.

  As shown in FIG. 9, the interference cancellation unit 900 deletes a point affected by a DC offset in the frequency domain, and a transform unit 901 arranged to convert the received signal from a time domain signal to a frequency domain signal. And an inverse transformation unit 903 arranged to convert the signal back into a time domain signal.

  Specifically, the converter 901 can convert the received signal into a frequency domain signal. Preferably, the received signal can be converted from a time domain signal to a frequency domain signal via a fast Fourier transform.

  The interference deletion unit 902 can delete interference due to a DC offset in the frequency domain. Since it is possible to intuitively find the frequency at which the interference due to the DC offset occurs in the frequency domain, it is possible to easily determine which is the frequency at which the interference due to the DC offset has occurred. Therefore, the frequency component in which the interference due to the DC offset directly occurs in the frequency domain and some frequency components around the frequency are made zero, thereby completing the elimination of the interference due to the DC offset in the frequency domain.

  The inverse transform unit 903 can transform the received signal after removing the interference due to the DC offset into a time domain signal. Preferably, it can be realized by inverse Fourier transform.

  According to another embodiment, an apparatus for detecting a primary synchronization sequence in a TDD-LTE system is provided. Preferably, the apparatus can detect a primary synchronization sequence from received signals from other cells in the process of searching in neighboring cells in the situation of synchronous communication.

  FIG. 10 shows an apparatus 1000 for detecting a primary synchronization sequence in a TDD-LTE system according to one embodiment of the present invention. The corresponding device 1000 includes a selection unit 1001 arranged to configure a search window for selecting a series of continuous sample points from received signals from other cells and detecting a primary synchronization sequence, and in the search window A correlation value calculation unit 1002 arranged to calculate a cross-correlation value between each sequence of received signals and each local primary synchronization sequence at successive sample points of the same length as the primary synchronization sequence of And a determining unit 1003 arranged to determine the position and type of the primary synchronization sequence in the received signal based on the maximum normalized cross-correlation value.

  Specifically, the selection unit 1001 configures a search window that detects a primary synchronization sequence by selecting a series of consecutive sample points from the received signal.

  For example, in a 10-km cell in the TDD-LTE system, the primary synchronization sequence in the received signal received from the adjacent cell is detected based on the position of the known primary synchronization sequence in the received signal received from the current serving base station. The search window can be limited to a range of W / 2 (for example, 192) sample points before and after the same position as the known position. Thus, the width of the search window is W point widths, and W> 128. The position of the center point of the search window in the received signal from the adjacent cell is the same as the position of the known primary synchronization sequence in the received signal received from the current serving base station.

  Correlation value calculation section 1002 calculates a cross-correlation value between the received signal sequence and the local primary synchronization sequence at consecutive sample points having the same length as the primary synchronization sequence in the search window.

  Specifically, in the case of synchronous communication, the cross-correlation value between the local primary synchronization sequence and the received signal sequence at consecutive sample points having the same length as the local primary synchronization sequence is calculated using, for example, Equation (9). can do.

  The determining unit 1003 can determine the position and type of the primary synchronization sequence in the received signal based on the calculated maximum cross-correlation value.

  Specifically, the position (m) in the received signal at the first sample point of the sequence of received signals at the continuous sample point corresponding to the maximum cross-correlation value is set as the start position of the primary synchronization sequence in the received signal, and the maximum cross-correlation value is obtained. The primary synchronization sequence type (id) corresponding to the correlation value is set as the primary synchronization sequence type in the received signal.

  In the case of asynchronous communication, for example, the primary synchronization sequence can be detected from the received signal from the adjacent cell using the apparatus shown in FIG. Specifically, by calculating the correlation value between the local primary synchronization sequence and the sequence of received signals at continuous sample points (the length is the same as the local primary synchronization sequence), and normalizing the correlation value Detect primary synchronization sequence. It can be seen that the apparatus shown in FIGS. 6 to 10 can implement the methods shown in FIGS. Therefore, for the sake of brevity, the specific operation process when the apparatus shown in FIGS. 6 to 10 performs the corresponding method is not described here.

  Each component module and unit in the above apparatus can be arranged by software, firmware, hardware, or a combination thereof. The specific means or methods that can be used in the arrangement are familiar to those skilled in the art and will not be mentioned here. When implemented by software or firmware, a program constituting the software is installed from a storage medium or a network to a computer having a general-purpose hardware structure (for example, the general-purpose computer 1100 shown in FIG. 11). Various functions can be realized when being performed.

  In FIG. 11, a central processing unit (CPU) 1101 performs various processes according to a program stored in a read-only memory (ROM) 1102 or a program loaded from a storage unit 1108 into a random access memory (RAM) 1103. The RAM 1103 also stores data necessary when the CPU 1101 performs various processes as necessary. The CPU 1101, ROM 1102, and RAM 1103 are connected to each other via a bus 1104. An input / output interface 1105 is also connected to the bus 1104.

  The following components: an input unit 1106 (including a keyboard and a mouse), an output unit 1107 (including a monitor such as a cathode ray tube (CRT), a liquid crystal monitor (LCD) and a speaker), a memory unit 1108 (a hard disk and the like) Communication unit 1109 (including a network interface card such as a LAN card, a modem, etc.) is connected to the input / output interface 1105. The communication unit 1109 performs communication processing on a network such as the Internet. The driver 1110 may also be connected to the input / output interface 1105 if necessary. The removable medium 1111 can be attached to the driver 1110 so that the computer program to be read is installed in the memory unit 1108 if necessary. The removable medium 1111 may be, for example, a disk, a compact disk, a magnetic disk, a semiconductor memory, or the like.

  When executing the above-described series of processing via software, a program constituting the software can be installed from a network or from a storage medium. The network is, for example, the Internet, and the storage medium is, for example, a removable medium 1111.

  It should be understood by those skilled in the art that the storage medium is not limited to the removable medium 1111 in which the program is stored as shown in FIG. 11 and distributed separately from the device and provided to the user. Absent.

  Examples of removable media 1111 include disks (including flexible disks), compact disks (including compact disk read-only memory (CD-ROM) and digital video display (DVD)), and magnetic disks (minidisk (MD) (registered) Trademark)) and semiconductor memory. Alternatively, the removable medium may be a ROM 1102, a hard disk included in the memory unit 1108, etc., in which a program is stored and distributed to the user together with a device including them.

  The disclosure of the present specification includes a program product in which an instruction code that can be read by a certain device such as a computer is stored. When the instruction code is read and executed by the apparatus, it causes the apparatus to execute the method according to the above embodiment.

  A storage medium in which a program product in which an instruction code readable by the above apparatus is stored is also included in the disclosure content of this specification. The storage medium includes, but is not limited to, a flexible disk, a compact disk, a magnetic disk, a memory card, a memory stick, and the like.

  Finally, it is necessary to explain that the terms “including”, “having” or any other variant is meant to encompass the inclusion of non-exclusiveness, thereby including a sequence of elements, methods, An article or facility not only includes these elements, but also includes other elements not explicitly shown, or includes elements unique to this type of process, method, article or facility. In the absence of further restrictions, an element defined by “including” in the sentence does not exclude the presence of another identical element in the process, method, article, or facility that includes the element.

  Although the embodiments of the present invention have been described in detail with reference to the drawings, the embodiments described above are merely used for explaining the disclosed method and apparatus, and the disclosed method and apparatus are used in the embodiment. It should be understood that it is not limited. For those skilled in the art, various modifications and changes can be made to the embodiments without departing from the spirit and scope of the disclosed method and apparatus. As such, the scope of the disclosed methods and apparatus is limited only by the appended claims and their equivalent implications.

  The following additional notes are further disclosed with respect to the embodiment including the above examples.

(Appendix 1)
A primary synchronization sequence detection method for detecting a primary synchronization sequence from a received signal in a TDD-LTE system,
Calculating a cross-correlation value between an individual sequence of received signals at successive sample points of the same length as the local primary synchronization sequence and an individual local primary synchronization sequence;
Calculating a normalized cross-correlation value by normalizing the calculated individual cross-correlation values by utilizing the point values of the sample points in the individual sequences of received signals at consecutive sample points. When,
Determining the position and type of the primary synchronization sequence in the received signal based on the calculated maximum normalized cross-correlation value;
A method comprising the steps of:

(Appendix 2)
In the primary synchronization sequence detection method according to attachment 1, the step of calculating the cross-correlation value includes:
Dividing the local primary synchronization sequence;
Dividing the sequence of received signals at successive sample points at the same division point as the division point of the local primary synchronization sequence;
Calculating a partial cross-correlation value between an individual part of the received signal sequence at the divided consecutive sample points and a corresponding part of the divided local primary synchronization sequence;
Calculating a cross-correlation value between a sequence of received signals at the continuous sample points and the local primary synchronization sequence based on the partial cross-correlation value;
A primary synchronization sequence detection method including:

(Appendix 3)
In the primary synchronization sequence detection method according to attachment 2, the normalizing step includes:
Calculating a normalization factor using the point values of the sample points in individual portions of the sequence of received signals at the divided continuous sample points;
Normalizing the cross-correlation value using the normalization factor;
A primary synchronization sequence detection method including:

(Appendix 4)
The primary synchronization sequence detection method according to appendix 2, wherein the local primary synchronization sequence is divided equally.

(Appendix 5)
In the primary synchronization sequence detection method according to appendix 1,
Before calculating the cross-correlation value,
The method further includes the step of converting the received signal from a time domain signal to a frequency domain signal, removing a frequency component affected by a DC offset in the frequency domain, and then converting the received signal to a time domain signal. Primary synchronization sequence detection method.

(Appendix 6)
A primary synchronization sequence detection method for detecting a primary synchronization sequence from a received signal from an adjacent cell in a neighboring cell search process when synchronous communication is performed in a TDD-LTE system, the method comprising:
Configuring a search window for selecting a series of consecutive sample points from the received signal to detect a primary synchronization sequence;
Calculating a cross-correlation value between an individual sequence of received signals at successive sample points in the search window and an individual local primary synchronization sequence having the same length as a primary synchronization sequence;
Determining a position and type of a primary synchronization sequence in the received signal based on the calculated maximum cross-correlation value;
Including a primary synchronization sequence detection method.

(Appendix 7)
In the primary synchronization sequence detection method according to appendix 6,
A series of consecutive sample points of the received signal from the adjacent cell, which is centered on the same position as the position of the primary synchronization sequence in the received signal from the current serving base station, is selected as a sample point constituting the search window. A primary synchronization sequence detection method characterized by the above.

(Appendix 8)
In the primary synchronization sequence detection method according to appendix 6,
Before selecting a series of consecutive sample points to construct a search window, the received signal is converted from a time domain signal to a frequency domain signal, and frequency components that are affected by a DC offset in the frequency domain are removed before time A primary synchronization sequence detection method further comprising the step of converting into a region signal.

(Appendix 9)
A primary synchronization sequence device that detects a primary synchronization sequence from a received signal in a TDD-LTE system,
A cross-correlation value calculating unit for calculating a cross-correlation value between each sequence of received signals at continuous sample points having the same length as the local primary synchronization sequence and each local primary synchronization sequence;
Normalizing to calculate a normalized cross-correlation value by normalizing the calculated individual cross-correlation values by utilizing the point values of the sample points in the individual sequences of the received signal at the consecutive sample points And
A determination unit for determining a position and type of a primary synchronization sequence in the received signal according to the calculated maximum normalized cross-correlation value;
Including a primary synchronization sequence device.

(Appendix 10)
In the primary synchronization sequence device according to attachment 9, the cross-correlation value calculation unit,
A first dividing unit for dividing the local primary synchronization sequence;
A second dividing unit that divides the sequence of received signals at the continuous sample points at the same division point as the division point of the local primary synchronization sequence;
A partial cross-correlation value calculating unit for calculating a partial cross-correlation value between an individual part of the received signal sequence at the divided continuous sample points and a corresponding part in the divided local primary synchronization sequence;
A sequence cross-correlation value calculation unit that calculates a cross-correlation value between the sequence of the received signal at the continuous sample points of the received signal and the local primary synchronization sequence based on the partial cross-correlation value;
Including a primary synchronization sequence device.

(Appendix 11)
In the primary synchronization sequence device according to appendix 10, the normalization unit includes:
A normalization factor calculation unit that calculates a normalization factor using the point values of the sample points in individual parts of the sequence of received signals at the divided continuous sample points;
A normalization execution unit that normalizes the cross-correlation value using the normalization factor;
Including a primary synchronization sequence device.

(Appendix 12)
The primary synchronization sequence device according to appendix 10, wherein the local primary synchronization sequence is divided equally.

(Appendix 13)
In the primary synchronization sequence device according to appendix 9, further including an interference deletion unit before the cross-correlation value calculation unit,
The interference deletion unit
A converter for converting the received signal from a time domain signal to a frequency domain signal;
An interference removal unit for removing a frequency component affected by a DC offset in the frequency domain;
An inverse transform unit for transforming the received signal into a time domain signal;
Including a primary synchronization sequence device.

(Appendix 14)
A primary synchronization sequence device that detects a primary synchronization sequence from a received signal from a neighboring cell in a search process of neighboring cells when synchronous communication is performed in a TDD-LTE system,
A selection unit that configures a search window for detecting a primary synchronization sequence by selecting a series of consecutive sample points from the received signal;
A cross-correlation value calculating unit for calculating a cross-correlation value between an individual sequence of received signals at consecutive sample points in the search window and an individual local primary synchronization sequence having the same length as a primary synchronization sequence;
A determination unit for determining a position and type of a primary synchronization sequence in the received signal based on the calculated maximum cross-correlation value;
Including a primary synchronization sequence device.

(Appendix 15)
The primary synchronization sequence device according to appendix 14, wherein the selection unit is a series of consecutive received signals from the adjacent cell, with the same position as the primary synchronization sequence position in the received signal from the current serving base station as a central point. A primary synchronization sequence device, wherein a sample point is selected as a sample point constituting the search window.

(Appendix 16)
In the primary synchronization sequence device according to appendix 14, further including an interference deletion unit before the cross-correlation value calculation unit,
The interference deletion unit
A converter for converting the received signal from a time domain signal to a frequency domain signal;
An interference removing unit for removing a frequency component affected by a DC offset in the frequency domain;
An inverse transform unit for transforming the received signal after removing the frequency component affected by the DC offset into a time domain signal;
Including a primary synchronization sequence device.

(Appendix 17)
A computer program that includes an instruction that can be executed by an information processing apparatus, and that causes the information processing apparatus to execute the primary synchronization sequence detection method according to any one of appendices 1 to 8 when executed by the information processing apparatus.

(Appendix 18)
A storage medium,
A computer program readable by an information processing device is stored in the storage medium, and the computer program is executed by the information processing device, whereby the primary synchronization sequence detection method according to any one of appendices 1 to 8, Causing the information processing apparatus to execute;
A storage medium characterized by that.

600 Primary synchronization sequence detection device 601 Cross-correlation value calculation unit 602 Normalization unit 603 Determination unit

Claims (9)

A primary synchronization sequence detection method for detecting a primary synchronization sequence from a received signal,
Calculating a cross-correlation value between an individual sequence of received signals at successive sample points of the same length as the local primary synchronization sequence and an individual local primary synchronization sequence;
Calculating a normalized cross-correlation value by normalizing the calculated individual cross-correlation values by utilizing the point values of the sample points in the individual sequences of received signals at consecutive sample points. When,
Determining the position and type of the primary synchronization sequence in the received signal based on the calculated maximum normalized cross-correlation value;
Including a primary synchronization sequence detection method. The step of calculating the cross-correlation value includes
Dividing the local primary synchronization sequence;
Dividing the sequence of received signals at successive sample points at the same division point as the division point of the local primary synchronization sequence;
Calculating a partial cross-correlation value between an individual part of the received signal sequence at the divided consecutive sample points and a corresponding part of the divided local primary synchronization sequence;
Calculating a cross-correlation value between a sequence of received signals at the continuous sample points and the local primary synchronization sequence based on the partial cross-correlation value;
The primary synchronization sequence detection method according to claim 1, comprising: The normalizing step includes:
Calculating a normalization factor using the point values of the sample points in individual portions of the sequence of received signals at the divided continuous sample points;
Normalizing the cross-correlation value using the normalization factor;
The primary synchronization sequence detection method according to claim 2, comprising: Before calculating the cross-correlation value,
The method further includes the step of converting the received signal from a time domain signal to a frequency domain signal, removing a frequency component affected by a DC offset in the frequency domain, and then converting the received signal to a time domain signal. The primary synchronization sequence detection method according to claim 1. A primary synchronization sequence detection method for detecting a primary synchronization sequence from a received signal from an adjacent cell in a search process of neighboring cells when synchronous communication is performed,
Configuring a search window for selecting a series of consecutive sample points from the received signal to detect a primary synchronization sequence;
Calculating a cross-correlation value between an individual sequence of received signals at successive sample points in the search window and an individual local primary synchronization sequence having the same length as a primary synchronization sequence;
Determining a position and type of a primary synchronization sequence in the received signal based on the calculated maximum cross-correlation value;
Including a primary synchronization sequence detection method.   A series of consecutive sample points of the received signal from the adjacent cell, which is centered on the same position as the position of the primary synchronization sequence in the received signal from the current serving base station, is selected as a sample point constituting the search window. The primary synchronization sequence detection method according to claim 5, wherein:   Before selecting a series of consecutive sample points to construct a search window, the received signal is converted from a time domain signal to a frequency domain signal, and frequency components that are affected by a DC offset in the frequency domain are removed before time 6. The primary synchronization sequence detection method according to claim 5, further comprising a step of converting into a region signal. A primary synchronization sequence detection device for detecting a primary synchronization sequence from a received signal,
A cross-correlation value calculating unit for calculating a cross-correlation value between each sequence of received signals at continuous sample points having the same length as the local primary synchronization sequence and each local primary synchronization sequence;
Normalizing to calculate a normalized cross-correlation value by normalizing the calculated individual cross-correlation values by utilizing the point values of the sample points in the individual sequences of the received signal at the consecutive sample points And
A determination unit for determining a position and type of a primary synchronization sequence in the received signal according to the calculated maximum normalized cross-correlation value;
A primary synchronization sequence detection apparatus comprising: A primary synchronization sequence detection device for detecting a primary synchronization sequence from a received signal from an adjacent cell in a search process of neighboring cells when synchronous communication is performed,
A selection unit that configures a search window for detecting a primary synchronization sequence by selecting a series of consecutive sample points from the received signal;
A cross-correlation value calculating unit for calculating a cross-correlation value between an individual sequence of received signals at consecutive sample points in the search window and an individual local primary synchronization sequence having the same length as a primary synchronization sequence;
A determination unit for determining a position and type of a primary synchronization sequence in the received signal based on the calculated maximum cross-correlation value;
A primary synchronization sequence detection apparatus comprising:

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