KR20070024298A - Apparatus for detecting a guard interval in receiver of orthogonal frequency division multiplexed signals - Google Patents

Abstract

An apparatus for detecting a guard interval in a receiver of orthogonal frequency division multiplex signals is provided to enhance a signal receiving performance by detecting the guard internal of a transmission signal frame. In an apparatus for detecting a guard interval in a receiver of orthogonal frequency division multiplex signals, a correlation calculation unit(100) calculates correlation values of values of received signals in a frame. A transportation average unit(200) accumulates the correlation values within a certain region among the correlation values calculated by the correlation calculation unit(100). A peak detection unit(300) detects the values exceeding a certain reference over, generated from the transportation average unit(200). A guard interval detection unit(350) detects the guard interval by a peak interval generated from the peak detection unit(300).

Description

Apparatus for detecting a guard interval in receiver of orthogonal frequency division multiplexed signals}

1 is a configuration diagram showing a brief configuration of a transmission device of the DMB-T

2 is a diagram showing the structure of a frame of a signal transmitted by a DMB-T transmitting apparatus;

3 is a structural diagram showing a protection section of a signal by the Chinese terrestrial television transmission system;

4 is a structural diagram of an embodiment of a guard interval detector of an OFDM modulated signal receiving apparatus according to the present invention;

5 is a graph showing a correlation value output by a guard interval detector of an OFDM modulated signal receiving apparatus according to the present invention;

<Description of reference numerals for main parts of the drawings>

10: channel encoder 20: modulator

30: reverse DFT section 40: PN generation section

50: multiplexer 60: SRRC unit

70: RF transmission unit 100: correlation calculation unit

110: first buffer memory 120: correlation multiplier

200: moving average part 210: second buffer memory part

220: first operator 230: second operator

250: delay 300: peak detection unit

350: protective section detection unit

The present invention relates to a guard interval detector of an apparatus for receiving broadcast signals modulated by orthogonal frequency division multiplexing (hereinafter, referred to as OFDM) (hereinafter, referred to as an OFDM modulated signal receiving apparatus). A protection section detector of an OFDM modulated signal receiver according to the television standard.

Recently, Tsinghua University has proposed a new standard for terrestrial digital television (“Terrestrial DTV”) broadcasting to China. The proposal relates to a broadcast standard called Terrestrial Digital Multimedia / Television Broadcasting (DMB-T). In DMB-T, a new modulation scheme called Time Domain Synchronous OFDM (hereinafter referred to as TDS-OFDM) is used.

Data transmitted after being modulated at the transmitting end of the TDS-OFDM is applied with an Inverse Discrete Fourier Transform (IDFT) like the method used in the Cyclic Prefix OFDM (CP-OFDM) method.

However, a pseudonoise (PN) is inserted in the guard interval instead of CP and used as a training signal.

The above-described method can reduce overhead when transmitting a broadcast signal, improve channel usage efficiency, and improve performance of a synchronizer and a channel estimator of a broadcast signal receiver.

1 is a block diagram showing a brief configuration of a transmission apparatus of a DMB-T. Referring to FIG. 1, the operation of the transmitter of the DMB-T will be described.

The channel encoder 10 outputs a bit stream encoded by the channel in order to detect an error at the receiving end.

The modulator 20 receives the coded bit stream and modulates the bit stream using quadrature amplitude modulation (QAM) or the like of 4, 16, or 64 values.

The inverse DFT unit 30 modulates a signal modulated by the OFDM scheme in the frequency domain into an OFDM signal in the time domain. In particular, the DMB-T method converts a frequency domain signal of 3780 points of transmission data into a time domain signal.

The PN generator 40 generates a PN sequence to be used as a training signal of a broadcast signal to be transmitted.

The multiplexer 50 distributes the generated PN sequence and the OFDM signal converted by the IDFT unit in the time domain, and multiplexes and outputs the same.

The SRRC unit 60 outputs the bandwidth of the multiplexed DMB-T signal by limiting the bandwidth. In general, the roll-off factor α used for the bandwidth limit is 0.05.

In addition, the RF transmitter 70 up-converts the output signal of which the bandwidth is limited to an RF (Radio Frequency) transmission band of frequency fc to transmit a broadcast signal.

FIG. 2 shows a structure of a frame in which a guard interval is 1/9 of a frame of a signal transmitted by the DMB-T transmitting apparatus of FIG. 1. A transmission frame structure having a guard interval of 1/9 will be described with reference to FIG. 2.

The frame consists of frame sync and frame body.

The frame body is a place where data to be transmitted is a DFT block to which a Discrete Fourier Transform (DFT) is applied. In general, the DFT block includes 3780 stream data.

The frame sink is composed of a PN sequence, and the PN used for the frame sink may use a sequence having an order of 8 (m = 8). When m = 8, 255 different sequences can be generated. The sequences can be extended to preambles and postambles for use in guard intervals.

The preamble and the postamble are repetition sections of the PN sequence for cyclic extension of the PN sequence.

Of the 255 PN sequences of the frame sync, the first 115 PNs of the PN sequence are added as a postamble to the end of the 255 PN sequence, and the last 50 PNs of the PN sequence are added as preambles before the 255 PN sequence. To expand.

The polynomial of the PN sequence is P (x) = x ⁸ + x ⁶ + x ⁵ + x + 1, and the generated phase varies from 0 to 254 according to the initial state of the PN sequence.

When the guard interval is 1/9, the preamble and the postamble are added to the 255 PN sequences before and after to form a frame sink including 420 data. In other words, 420 data, which is 1/9 of 3780 data of the DFT block, are used for frame sync. One OFDM frame is composed of a frame sink of 420 data and a frame body of 3780 data.

On the other hand, if the guard interval is 1/4, the latter 525 data of the 3780 data included in the DFT block are added again before the 3780 data of the DFT block (this is called a cyclic prefix). .

In some cases, the 525 data sections may be padded with zeros.

In general, 945 data, which is 1/4 of 3780 data of a DFT block, are used for frame sync.

The structure of the data frame may vary depending on the protection period, and the number of data distributed in each frame may also be distributed differently.

In addition, the protective section may be defined as 1/4 or 1/9, in addition to the 1/6 protective section may be used, and thus, the length of the protective section may be formed differently depending on the standard forming the system.

The guard interval detection of the broadcast signal of the OFDM method must be preceded by the broadcast signal receiver of the OFDM method. This is because the PN sequence code of the synchronization unit and the frequency error compensation of the signal can be obtained only by detecting the guard period.

An object of the present invention is to provide a guard interval detector of an OFDM modulated signal receiver capable of efficiently finding a guard interval in the above-described Chinese terrestrial television transmission system (DMB-T).

In order to achieve the above object, the present invention provides a guard interval detector of a device capable of receiving a modulated signal using orthogonal frequency division multiplexing using a PN (Pseudo noise) sequence as a training signal in a guard interval. A correlation calculation unit comprising: a correlation calculation unit for calculating a correlation value of a value of an in-frame received signal; A moving average unit accumulating a correlation value for a predetermined period among the correlation values output by the correlation calculation unit; A peak detector for detecting a predetermined reference or more of a correlation value output by the moving average unit; And a guard section detector for detecting a guard section at a peak interval output by the peak detector.

The correlation calculation unit may include a first buffer memory unit for storing the received signal in the frame and delaying and outputting the received signal; And a correlation multiplier for correlating the original signal with the delayed signal output by the first buffer memory.

The number of signals stored in the first buffer memory unit is preferably the number of PN sequences in the guard period.

The moving average unit comprises: a second buffer memory unit configured to delay and output a correlation value output by the correlation multiplier for a predetermined period; A delayer for delaying the correlation values output by the correlation multiplier for one period; A first operator accumulating a correlation value output by the delay multiplier and the correlation multiplier; and a second calculator calculating a difference between an accumulated correlation value output by the first calculator and a correlation value output by the second buffer memory. Can be.

Preferably, the maximum number of correlation values stored in the second buffer memory unit is the sum of the number of preamble PN sequences of the PN sequence and the number of postamble PN sequences in the protection period.

The guard interval detector may detect the guard interval by comparing the interval of peaks detected by the peak detector with a length of a set frame.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described.

3 shows a structure of a protection section of a terrestrial television transmission system for China, before explaining a protection section detector of an OFDM modulated signal receiving apparatus according to the present invention. Referring to FIG. 3, a portion of the PN sequence portion that cross-corresponds to detect the guard interval will be described with reference to FIG. 3.

For 255 PN sequences, the last 50 sequences A of the sequence extend before the PN sequence and the first 115 sequences B after the PN sequence.

In the following description, the last 50 sequences A used for extension of the PN sequence are referred to as PN preambles, and the first 115 sequences B are referred to as PN postambles.

In the protection period of FIG. 3, the first consecutive PN preamble and the PN postamble have the same value as the last consecutive PN preamble and the PN postamble. Therefore, when cross correlation is taken, peak values of the cross correlation values can be obtained.

In addition, the cross-correlation value of the other section has a value of 0, which is very small than the peak value, due to the characteristics of the PN sequence.

4 shows the structure of an embodiment of a guard interval detector of an OFDM modulated signal receiving apparatus according to the present invention. An embodiment of a guard interval detector of an OFDM modulated signal receiver according to the present invention includes a correlation calculation unit 100, a moving average unit 200, a peak detector 300, a guard interval detector 250.

The correlation calculation unit 100 preferably includes a buffer memory unit 110 and a correlation multiplier 120.

The moving average unit 200 may include a second buffer memory unit 210, a delay unit 250, and a plurality of operators 220 and 230.

Referring to Figure 4 describes the operation of an embodiment of the guard interval detector of the OFDM modulated signal receiving apparatus according to the present invention.

The first buffer memory unit 110 may store as many as the number of PN and delay and output the same (r (n) + N _PN ). The PN sequence output by the first buffer memory unit 110 may be output in the order of the first input PN sequence of the first buffer memory unit 110.

The correlation multiplier 120 correlates the sequence output by the first buffer memory unit 100 with the original sequence and applies it to the moving average unit 200.

The moving average unit 200 stores the correlated values in the second buffer memory 210 and delays and outputs the correlated values by the capacity of the second buffer memory 210.

The moving average unit 200 may add the correlated values for a certain period. As illustrated in the description of FIG. 3, since the sequence of the PN preamble and the PN postamble is repeated in the frame sync in the TDS-OFDM, the second buffer memory 200 may determine the number of the PN preambles (FIG. 4). It is preferable to delay the correlation by the sum of N _pre ) and the number of PN postambles (N _post in FIG. 4).

The first operator 220 adds the correlation values output by the correlation multiplier 120 and outputs the sums to the delay unit 250 until the correlation values are delayed and output from the second buffer memory 210. Since the correlation values temporarily stored and output are returned to the first calculator 220 and summed, the correlation values may accumulate for a predetermined period.

If the second buffer memory 210 delays the correlation value by the sum of the number of PN preambles and the number of PN postambles, and outputs the second operator 230, the second operator 230 may determine the sequence accumulated by the first operator 220. The correlation values of the sequence delayed by the sum of the number of PN preambles and the number of PN postambles are subtracted from the correlation values and output.

Accordingly, the moving average unit 200 outputs correlation values of a predetermined section with respect to the PN sequence, and the output correlation values correspond to correlation values corresponding to sections in which the PN sequence is delayed one by one.

The peak detection unit 300 may receive a peak reference value determined as a peak among correlation values, and detect a peak value exceeding the reference value among correlation values output by the moving average unit 200.

The guard section detector 350 receives the peak value output from the peak detector 300 to determine the guard section. The guard interval detector 350 may determine a mode by comparing the interval of the peak generated by the peak detector 300 with the length of a predetermined frame. Therefore, in order to distinguish between the 1/4 guard interval mode and the 1/9 guard interval mode, the frame length is set to the length corresponding to the number of symbols between the 1/4 guard interval and the 1/9 guard interval, respectively. It is desirable to decide.

And the guard interval detection process can be applied on the same principle even if there are guard intervals of different lengths.

5 is a graph showing the performance of the guard interval detector of the OFDM modulated signal receiving apparatus according to the present invention. The horizontal axis (X axis) of Figure 5 represents the number of symbols, the vertical axis (Y axis) represents the correlation value calculated by the guard interval detector according to the present invention.

Among the correlation values shown in FIG. 5, a correlation value of a light green color is a correlation value of a mode having a 1/4 protection period, and a correlation value of a mode having a 1/9 protection period is a red correlation value.

In the mode having the 1/4 guard interval, the peak of the correlation value appears every 945 + 3780 symbols, and the mode having the 1/9 guard interval shows the peak of the correlation value every 420 + 3780 symbols.

Although the peak reference value is set as the correlation value 2000 through the result of FIG. 5, it can be seen that the guard interval detector according to the present invention can accurately detect the peak of the correlation value.

It is easy for a person skilled in the art to change or modify the present invention from the present specification. Thus, although an embodiment of the present invention has been described above clearly, various modifications thereof should be made without departing from the spirit and scope of the invention.

The effect of the guard interval detector of the OFDM modulated signal receiving apparatus according to the present invention described above is as follows.

According to the guard interval detector of the OFDM modulated signal receiver according to the present invention, it is possible to efficiently find the guard interval of the transmission signal frame, thereby improving the signal reception performance.

Claims (6)

In the guard interval detector of a device capable of receiving a modulated signal by orthogonal frequency division multiplexing using a PN (Pseudo noise) sequence as a training signal in the guard interval, A correlation calculation unit for calculating a correlation value of the value of the received signal in the frame; A moving average unit accumulating a correlation value for a predetermined period among the correlation values output by the correlation calculation unit; A peak detector for detecting a predetermined reference or more of a correlation value output by the moving average unit; And And a guard section detector for detecting a guard section at a peak interval output by the peak detector. The method of claim 1, The correlation calculation unit may include a first buffer memory unit for storing the received signal in the frame and delaying and outputting the received signal; And And a correlation multiplier that correlates the delayed signal output from the first buffer memory unit with the original signal. The method of claim 2, The number of signals stored in the first buffer memory unit is a guard interval detector, characterized in that the number of PN sequences in the guard interval. The method of claim 1, The moving average unit comprises: a second buffer memory unit configured to delay and output a correlation value output by the correlation multiplier for a predetermined period; A delayer for delaying the correlation values output by the correlation multiplier for one period; A first operator for accumulating a correlation value output by the delay unit and the correlation multiplier; And a second calculator configured to calculate a difference between a cumulative correlation value output by the first calculator and a correlation value output by the second buffer memory. The method of claim 4, wherein The maximum number of correlation values stored in the second buffer storage unit is a guard interval detector, characterized in that the sum of the number of preamble PN sequence of the PN sequence in the guard interval and the number of PN sequence of the postamble (postamble). The method of claim 1, The guard interval detector detects the guard interval by comparing the interval of peaks detected by the peak detector with a set length of the frame.

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