KR20050006397A - Apparutus and Method for detecting Pseudo Noise sequence in OFDM receiver - Google Patents

Abstract

PURPOSE: An apparatus and a method for detecting a pseudo noise sequence information in an orthogonal frequency division multiplexing(OFDM) receiver are provided to detect the pseudo noise sequence information utilizing as a synchronization signal in short time by using the characteristics of OFDM transmission signal. CONSTITUTION: An apparatus and a method for detecting a pseudo noise sequence information in an orthogonal frequency division multiplexing(OFDM) receiver a synchronization range setting unit(60) and a synchronization signal detection unit(70). The synchronization range setting unit detects the power amount of received OFDM signal and sets a region at which the detected power amount reaches to a predetermined level as a region at which the synchronization signal is positioned. The synchronization signal detection unit calculates the correlation value between the OFDM signal positioned at the set region and the predetermined reference signal. And, the synchronization signal detection unit detects the pseudo noise sequence information from the OFDM signals based on the calculated correlation value.

Description

Apparatus and Method for detecting Pseudo Noise sequence in OFDM receiver

The present invention relates to an FM receiver, and more particularly, to an apparatus and method for detecting pseudo noise sequence information capable of detecting pseudonoise sequence information used as a synchronization signal of an FM receiver at high speed.

Orthogonal Frequency Division Mutiplexing (OFDM) is a digital modulation method for improving transmission rate per bandwidth and preventing multipath interference.It divides the entire transmission band into multiple narrowband orthogonal subchannels. In addition, QAM (Quadrature Amplitude Modulation) is modulated for each subchannel and data is simultaneously transmitted. Accordingly, the UFDM method can increase the data transmission rate per unit time by converting the data to be transmitted into a plurality of parallel data and modulating it to different subcarriers and transmitting the data per unit time. The side may be less affected by the transmission delay due to the multipath.

On the other hand, in the data transmission according to the TDS (Time Domain Synchronous) -OFDM method, each data is largely composed of a synchronization signal and the OSF data. Pseudo noise sequence (PN) is used for the synchronization signal, and the receiving side incorporates the same pseudo noise sequence information as the pseudo noise sequence information transmitted from the transmitting side, and then synchronizes by calculating a correlation value between them. .

1 is a diagram schematically illustrating a frame structure of an OMD signal transmitted from a transmitting side to a receiving side.

Referring to the drawings, the OMD transmission signal is inserted between pseudo noise sequence information (PN), ODP data (data) used as a synchronization signal, and pseudo noise sequence information and OPM data (data). A guard interval is provided to prevent interference between the FM data. The OMD receiver (not shown) detects pseudo noise sequence information (PN) from the OMD transmission signal and performs frequency synchronization, symbol synchronization, and channel equalization based on the detected pseudo noise sequence information.

2 shows a block diagram of a conventional synchronization signal detection apparatus.

The illustrated synchronization signal detection device includes a tuner 10, an analog-to-digital converter (ADC) 20, and a synchronization signal detection unit 30.

The tuner 10 receives an OMD transmission signal of a desired channel from a transmitting side (not shown). The analog-to-digital converter (ADC) 20 converts the received OMD transmission signal into a digital signal through a process of sampling, quantization, and coding. The synchronization signal detector 30 detects pseudo noise string information PN, which is a synchronization signal, from the digital signal output from the analog-digital converter (ADC) 20.

Preferably, the synchronization signal detector 30 has a correlator 31 and a phase loop (DLL) 32.

The correlator 31 calculates a correlation value between the digital signal output from the analog-to-digital converter (ADC) 20 and the reference pseudo-noise string information R_PN preset on the receiving side. The correlation value is obtained by multiplying the digital signal and the reference pseudonoise string information R_PN by a predetermined range and then adding the respective multiplied values. The receiving side has reference pseudonoise string information R_PN having the same pattern as the pseudonoise string information PN transmitted from the transmitting side, and the correlation value when the phases of both are coincident is maximum. That is, when the correlator 31 tries to find pseudo noise sequence information PN, which is a synchronization signal, from the analog-digital converted digital signal, the reference pseudo noise sequence information R_PN until the correlation value becomes the maximum value. Calculate the correlation between and the digital signal.

The phase loop (DLL) 32 compares the pseudo-noise sequence information (PN) obtained from the correlator (31) with the digital signal output from the analog-to-digital converter (ADC) 20 to correlator ( Correct the phase error of the pseudo-noise sequence information PN obtained from (31).

As described above, in the conventional synchronization signal detecting apparatus, the pseudo-FM signal transmitted from the transmitting side must be obtained until the correlation value between the reference pseudo noise sequence information R_PN preset on the receiving side and the received digital signal becomes maximum. Noise column information (PN) could be detected. Accordingly, when the above-described synchronization signal detection apparatus is applied to the digital broadcasting receiver, the detection of the pseudo noise string information PN is not performed at an appropriate time point, so that the reproduction of the broadcasting signal is delayed for a predetermined time.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to detect and detect pseudo-noise sequence information of a TDS-OFDM receiver capable of detecting pseudo-noise sequence information used as a synchronization signal in a short time. In providing a method.

1 is a view schematically showing a frame structure of an OMD signal transmitted from a transmitting side to a receiving side;

2 is a block conceptual diagram of a conventional synchronization signal detecting apparatus;

3 is a schematic block diagram of an apparatus for detecting pseudo noise thermal information according to the present invention;

4 is a diagram conceptually illustrating a power distribution of an OFM signal output from an analog-digital converter;

5A and 5B are waveform diagrams for explaining a method in which the synchronization signal detector detects pseudo noise string information;

6A and 6B are views for explaining a phase correction process of a phase loop, and

7 is a flowchart of a preferred embodiment of the method for detecting pseudo-noise string information of the OMD receiver of the present invention.

* Description of the symbols for the main parts of the drawings *

40 tuner 50 analog-to-digital converter

60: synchronization range setting unit 70: synchronization signal detection unit

80: phase loop

According to the present invention, the synchronization range setting unit detects the amount of power of the received OMD signal, and sets an area where the detected amount of power reaches a predetermined level as an area where pseudo noise string information as a synchronization signal is located; And a synchronization signal detector for calculating a correlation value between the OMD signal located in the set region and a preset reference signal and detecting pseudo noise string information from the OMD signal based on the ODM signal.

Preferably, the method further includes a phase loop for correcting a phase error of the pseudo noise sequence information detected by the synchronization signal detector by comparing the received OMD signal with the pseudo noise sequence information detected by the synchronization signal detector.

Preferably, the phase loop performs phase correction from the front end of the area detected by the synchronization signal detector.

Preferably, the synchronization signal detector calculates the correlation value from the front end of the area set by the synchronization range setting unit.

Preferably, the pseudo noise string information has a power value different from the average power of the OSMD signal.

The correlation value may be obtained by multiplying an OFM signal located in the set area with the preset reference signal.

The preset reference signal is preferably a signal of the same pattern as the predetermined noise noise sequence information.

According to an aspect of the present invention, there is provided a method for detecting power amount of a received OMD signal, setting an area where the detected amount of power reaches a predetermined level as an area in which pseudo noise string information as a synchronization signal is located. Computing a correlation value between the OMD signal located in the set region and the preset reference signal and detecting pseudo noise string information from the OFM signal based on the calculated value.

Preferably, the step of detecting pseudo noise string information from the OMD signal comprises comparing the received OMD signal with the pseudo noise string information detected by the synchronization signal detector to determine the pseudo noise string information. Correcting the phase error further.

In the correcting of the phase error, it is preferable to perform phase correction from the front end of the area detected by the synchronization signal detector.

In the detecting of the pseudo noise string information, the correlation value may be calculated from a front end of an area set as an area in which the pseudo noise string information is located.

Preferably, the pseudo noise string information has a power value different from the average power of the OSMD signal.

The correlation value may be obtained by multiplying an OFM signal located in the set area with the preset reference signal.

The preset reference signal is preferably a signal of the same pattern as the predetermined noise noise sequence information.

Hereinafter, the present invention will be described in detail with reference to the drawings.

3 shows a schematic block diagram of an apparatus for detecting pseudo noise column information according to the present invention.

The illustrated pseudo noise sequence information detecting apparatus includes a tuner 40, an analog-digital converter 50, a synchronization range setting unit 60, a synchronization signal detection unit 70, and a phase loop 80.

The tuner 40 receives an OMD transmission signal of a desired channel from a transmitting side (not shown). The analog-to-digital converter (ADC) 50 converts the received OMD transmission signal into a digital signal through a process of sampling, quantization, and coding.

The synchronization range setting unit 60 calculates the amount of power of the received OMD transmission signal, and sets the area where the calculated amount of power reaches a predetermined level as the area where the pseudo noise string information PN is located. The OMD transmission signal sent from the transmitting side (not shown) is largely divided into ODP DM data and pseudo noise string information (PN), which is a synchronization signal, and the pseudo noise string information (PN) is about 6 decibels compared to the OMD data. (db) has a high power value. The synchronization range setting unit 60 continuously calculates the power value of the OMD transmission signal by using this characteristic of the OMD transmission signal, and the calculated power value is a region higher than a predetermined level higher than the ODP transmission data. Set to the position where the pseudo noise column information (PN) is located.

The synchronization signal detection unit 70 applies preset reference pseudonoise string information R_PN from the front end of the area set in the synchronization range setting unit 60 to obtain a correlation value with the digital signal output from the analog-to-digital converter 50. It calculates, and detects the point where the calculated correlation value becomes the maximum, and outputs the synchronization detection signal sync. The correlation value is a value obtained by multiplying the ODP transmission signal located at the front end of the area set by the synchronization range setting unit 60 with the reference pseudo noise string information on the receiving side after a predetermined range, and the maximum value is The number of symbols constituting the pseudo noise sequence information PN included in the transmission signal is obtained. The method of obtaining the correlation value will be described later in detail.

The phase loop 80 corrects the phase error of the pseudo noise string information PN obtained by the synchronization signal detector 70 by referring to the digital signal output from the analog-digital converter 50. At this time, the phase loop 80 performs phase correction from the front end of the area detected by the synchronization signal detector 70 to reduce the time required for phase correction.

4 conceptually illustrates a power distribution of an OFM signal output from an analog-digital converter.

As shown, when the data of the OMD transmission signal (OFDM) has a power value of 11 decibels, it can be seen that the pseudo-noise sequence information (PN) has a power value of 17 decibels. The reason why the power noise value PN is larger than that of the FM data in the OMD system is to facilitate the detection of the pseudo noise string information PN, which is a synchronization signal. This characteristic of the OMD transmission signal is used to find an approximate area where the pseudo noise string information PN included in the ODP transmission signal is located. On the other hand, the pseudo noise sequence information (PN) included in the OMD transmission signal is defined to have a power value of 6 decibels greater than the ODP data (OFDM), but the pseudo noise sequence information (PN) and the power value of the data are defined. It is not specified as shown in this figure, it is only necessary that the pseudo-noise sequence information PN is 6 decibels larger than the power value of the data.

5A and 5B show waveform diagrams for explaining how the synchronization signal detection unit 70 detects pseudo noise string information PN.

FIG. 5A illustrates a signal corresponding to a front end of an area set by the synchronization range setting unit 60 among digital signals output from the analog-digital converter 50, and FIG. 5B illustrates preset reference pseudo noise string information R_PN. Indicates. In the figure, a state in which both phases are completely matched is shown.

5A and 5B, the OMD transmission signal is represented by two logic levels corresponding to a +1 value and a −1 value. As shown, when the signal corresponding to the leading end of the area set by the synchronization range setting unit 60 and the phase of the reference pseudo noise string information R_PN provided on the receiving side coincide with each other, When multiplying the pulse and the subpulse, the result of the multiplication is all +1. Accordingly, after multiplying the pseudo noise sequence information PN shown in FIG. 5A by the reference pseudo noise sequence information R_PN of the receiving side having the same pattern, and adding it, the reference pseudo noise sequence information preset on the receiving side is added. The same value as the number of symbols is calculated. For example, if the pseudo-noise sequence information PN consists of 512 symbols, a correlation value of +512 is obtained. As described above, the process of calculating the correlation value is performed in the region set by the synchronization range setting unit 60, that is, near the position where the pseudo noise string information PN included in the OMD transmission signal is located. In order to find the pseudo-noise sequence information PN included in the OMD transmission signal simply by continuously calculating the correlation value between the reference pseudo-noise sequence information R_PN and the digital signal output from the analog-digital converter 50. It can be detected at a higher speed.

6A and 6B illustrate a diagram for describing a phase correction process of the phase loop 80.

6A illustrates a waveform of pseudo noise string information PN output from the analog-digital converter 50, and FIG. 6B illustrates a waveform of pseudo noise string information PN output from the synchronization signal detector 70. As shown, the phase of the pseudo-noise sequence information PN shown in FIG. 6B is delayed by a predetermined time than the pseudo-noise sequence information PN shown in FIG. 6A. Here, although the phases of the pseudo-noise sequence information (PN) shown in FIGS. 6A and 6B do not exactly coincide with each other, the maximum value for the correlation value may come out when calculating the correlation values at points A, B, and C. can see. The phase loop 80 performs timing recovery using a delayed lock loop (DLL) or a taurther loop (TDL) so that the phases of the waveforms shown in FIGS. 6A and 6B completely match.

7 is a flowchart of a preferred embodiment of the method for detecting pseudo-noise string information of the OMD receiver of the present invention.

First, the amount of power of the received OMD transmission signal is detected (S100). The OMD transmission signal can be largely divided into OMD data and a synchronization signal. The OMD data refers to video and audio signals, and the synchronous signal refers to pseudo noise string information having a power distribution of about 6 decibels higher than that of the data so as to be easily detected by the receiver. In the present invention, the approximate location of the pseudo-noise sequence information (PN) included in the OMD transmission signal is found by detecting the amount of power by using the characteristics of the OMD transmission signal.

Next, a section in which the power distribution is about 5 to 6 decibels higher than the detected power value distribution is set as an area in which the pseudo noise string information PN is located (S200). Next, a correlation value between the OMD transmission signal located at the front end of the set area and the reference pseudo noise string information R_PN provided on the receiving side is calculated (S300). The correlation value is preset at the receiving side, and is obtained by multiplying the reference pseudo-noise sequence information R_PN having the same waveform as that transmitted from the transmitting side by the OMD transmission signal after a predetermined range and adding the multiplied result. The maximum value of the correlation value is equal to the number of symbols constituting the pseudo-noise string information (PN) included in the OMD transmission signal. In this case, the correlation value is performed in a place where the distribution of the detected power value is higher than or equal to a predetermined level, that is, in an area in which pseudo noise string information (PN) is located about 5 to 6 decibels higher than the surrounding power value distribution. Detection of pseudo noise sequence information (PN) included in a signal can be performed very quickly. Next, it is determined whether the calculated correlation value is the maximum value (S400). As a result of the determination, if the correlation value is the maximum value, the phase noise is corrected by comparing the pseudo noise string information PN obtained from the OMD transmission signal with the ODP transmission signal (S500). Phase error correction is applied DLL (Delayed Lock Loop) or TDL (Tau Dither Loop), and the phase error according to time delay of pseudo noise sequence information obtained by calculating correlation value based on OPM transmission signal. Will be corrected. At this time, the correction of the phase error starts at the tip of the area set according to the power value distribution. As described above, the present invention sets the approximate position of pseudo-noise string information having a power value of 5-6 decibels high in the OMD transmission signal, and then calculates a correlation value in the set area, thereby making a pseudo-noise as a synchronization signal. After obtaining the thermal information and performing phase error correction, when transmitting a high-definition broadcast signal with the OMD transmission signal, the receiving side can receive the video signal after performing synchronization in a short time.

As described above, the present invention can detect pseudo-noise sequence information used as a synchronization signal of the transmitting and receiving side in a short time by using the characteristics of the OMD transmission signal, and when receiving the high-quality broadcast signal, the receiving side within a short time After synchronization, video signal can be received.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the present invention is not limited to the specific embodiments of the present invention without departing from the spirit of the present invention as claimed in the claims. Anyone of ordinary skill in the art can make various modifications, as well as such changes are within the scope of the claims.

Claims (14)

A synchronization range setting unit for detecting a power amount of the received OMD signal and setting an area where the detected power amount reaches a predetermined level as an area in which pseudo noise string information as a synchronization signal is located; And A synchronization signal detector for calculating a correlation value between the OPM signal located in the set region and a preset reference signal and detecting pseudo noise string information from the OFM signal based on the OFM signal; An apparatus for detecting pseudo noise thermal information of a receiver. The method of claim 1, And a phase loop for compensating the phase error of the pseudo noise sequence information detected by the synchronization signal detector by comparing the received OMD signal with the pseudo noise sequence information detected by the synchronization signal detector. Pseudo-noise train information detection device of the FM receiver. The method of claim 2, The phase loop, And a phase noise correction device performing phase correction from the front end of the area detected by the synchronization signal detector. The method of claim 1, The sync signal detector, And an apparatus for detecting pseudo noise string information of an OMD receiver, wherein the correlation value is calculated from a front end of an area set by the synchronization range setting unit. The method of claim 1, The pseudo noise column information, And a power value different from the average power of the OPM signal. The method of claim 1, The correlation value is, And an apparatus for detecting pseudo noise string information of an OMD receiver, which is obtained by multiplying an OFM signal located in the set region with the preset reference signal. The method of claim 1, The preset reference signal is, And an apparatus for detecting pseudo noise sequence information of an OMD receiver, wherein the pseudo noise sequence information is a signal having a predetermined pattern. Detecting an amount of power of the received OMD signal; Setting an area where the detected amount of power reaches a predetermined level as an area in which pseudo noise string information as a synchronization signal is located; Calculating a correlation value between the OFM signal located in the set region and a preset reference signal and detecting pseudo noise string information from the OFM signal based on the OFM signal; Method for detecting false noises The method of claim 8, Detecting pseudo noise string information from the OFM signal, Compensating the phase error of the detected pseudo-noise sequence information by comparing the received OMD signal and the pseudo-noise sequence information detected by the synchronization signal detection unit of the OMD receiver Pseudo-noise train information detection method. The method of claim 9, Correcting the phase error, And performing phase correction from the leading edge of the area detected by the synchronization signal detector. The method of claim 8, Detecting the pseudo noise string information, And calculating the correlation value from a front end of an area set as an area in which the pseudo noise string information is located. The method of claim 8, The pseudo noise column information, And a power value different from the average power of the OPM signal. The method of claim 8, The correlation value is, And a method for detecting pseudo noise string information of an OMD receiver, which is obtained by multiplying an OFM signal located in the set region with the preset reference signal. The method of claim 8, The preset reference signal is, And a pseudo noise sequence information detecting method according to claim 4, wherein the pseudo noise sequence information is a signal having a predetermined pattern.