KR20050005047A - Apparatus and Method for detecting synchronization signal - Google Patents

Abstract

PURPOSE: A SYNC(SYNChronization) signal detecting apparatus and a method thereof are provided to detect exactly a SYNC signal included to a digital broadcasting signal although a phase of the digital broadcasting signal transmitted from a transmitter is changed by a channel interference and a multi-path fading. CONSTITUTION: The first correlator(60) calculates the first correlation value relating to a previously prepared standard pseudo noise stream information and a real number component of the digital broadcasting signal. The second correlator(70) calculates the second correlation value relating to a previously prepared standard pseudo noise stream information and a complex number component of the digital broadcasting signal. A correlation value calculating member(80) calculates sum about the square values of the first and second correlation values, removes a phase offset having the same phase included to the first and second correlation values and calculates the size of the correlation value relating to the standard pseudo noise stream information and a SYNC(SYNChronization) signal. A maximum value detecting member(90) produces a SYNC detecting signal at the position having the maximum value within a predetermined period among the calculated correlation values.

Description

Apparatus and Method for detecting synchronization signal

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a synchronization signal detection apparatus of a digital broadcast signal receiver, and in particular, a synchronization for accurately detecting a synchronization signal according to a main path even if a digital broadcast signal transmitted from a transmitter changes its phase due to channel interference and multipath fading. It relates to a signal detection device.

Digital broadcasting is gradually replacing traditional analog broadcasting. Digital broadcasting can provide a higher quality image than analog broadcasting, and has various additional functions in addition to the basic function of image and audio playback. Digital broadcasting mainly consists of the US-led Advanced Television Systems Committee (ATSC) method and the European-led DVB-T (Digiatal Video Broadcasting-Terrestiral) method. The ATSC method transmits MPEG-2 based broadcast signals on a single carrier. In the DVB-T method, a broadcast signal to be transmitted is modulated by a plurality of subcarriers, respectively, and then transmitted. Among them, the ATSC method applied in the US, Korea, and Canada is resistant to co-channel interference even in the simultaneous broadcast (Simulcast) environment with analog, and has the advantage of low cost receiver configuration because the hardware configuration is simpler than other methods. have. Recently, an ADTB-T (Advanced Digital Television Broadcasting-Terrestial) method similar to the ATSC method has been proposed in "Samsung Electronics". The ADTB-T standard supports single / hybrid transmission mode and uses OQAM (Offset Quadrate Amplitude Modulation) modulation.

1 is a block diagram schematically illustrating a process of transmitting and receiving a general digital communication.

As shown, the transmitting side modulates the transmission signal X (t) to be transmitted by the modulator 10 at the carrier frequency A · e ^jwt and transmits (A · e ^jwt ) X (t). Accordingly, the receiving side multiplies the (A · e ^jwt ) X (t) signal applied from the transmitting side by the demodulator 20 by the frequency e ^-jwt having a carrier frequency and an orthogonality and multiplies the transmission signal X (t). Get

2 is a block diagram illustrating a transmission and reception process when channel interference occurs between the transmission and reception systems illustrated in FIG. 1.

As shown, if the signal (A e ^jwt ) X (t) transmitted from the transmitting side is affected by the multipath signal or interfered by other broadcast signals in the vicinity, the signal transmitted from the transmitting side is in phase Will occur. That is, the signal transmitted from the transmitting side causes a phase shift by the phase offset θ, and has a form of (A · e ^{jwt + θ} ) X (t). Multiplying the frequency e ^-jwt by the demodulator 20 provided at the receiving side prevents the receiving side from obtaining the transmission signal X (t) to be received, and the receiving side is included in the transmission signal X (t) due to the phase offset. It is impossible to accurately track the position of the synchronization signal. In general, a digital broadcast signal includes a synchronization signal for notifying the start and end of a transmission signal in the transmission signal X (t). When the location of the synchronization signal is not known accurately, it is difficult to receive a normal digital broadcast signal. .

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a synchronization signal included in a digital broadcast signal even when the digital broadcast signal transmitted from a transmitter is changed in phase by channel interference and multipath fading. The present invention provides a synchronization signal detection apparatus capable of accurately detecting a.

1 is a block diagram schematically showing a system for transmitting and receiving a general digital broadcast signal;

2 is a block diagram illustrating a process of transmitting and receiving a digital broadcast signal when channel interference occurs between the transmission and reception systems of the digital broadcast signal shown in FIG. 1;

3 is a block diagram according to a preferred embodiment of the synchronization signal detection apparatus according to the present invention;

4A and 4B are views for conceptually explaining a process of calculating a correlation value between a first correlator and a second correlator shown in FIG. 3;

5 is a detailed block diagram of the maximum value calculator shown in FIG. 3, and

6 is a flowchart of a preferred embodiment of a synchronization signal detection method according to the present invention.

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

50: demodulation unit 60: first correlator

70: second correlator 80: correlation value calculation unit

90: maximum value detection section 91: comparison section

91a: comparator 91b: first memory

92: counter 93: synchronization signal generator

93a: second memory 93b: third memory

93c: index comparator 93d: signal generator

According to the present invention, in the synchronization signal detecting apparatus for detecting a synchronization signal from the received digital broadcast signal, the first correlation value for the preliminary reference noise sequence information and the real component of the digital broadcast signal is calculated. A first correlator, a second correlator for calculating a second correlation value for the complex pseudo component of the digital broadcast signal, and the reference pseudo-noise string information, and a sum of squares of the first correlation value and the second correlation value; A correlation value calculator for removing a phase offset of the same phase included in the first correlation value and the second correlation value, and calculating a magnitude of a correlation value for the reference pseudo-noise sequence information and a synchronization signal; It is achieved by a maximum value detector for generating a synchronization detection signal at a position having a maximum value within a predetermined period among the calculated correlation values.

Preferably, the maximum value detection unit, according to the comparison unit for sequentially comparing adjacent correlation values among the correlation values sequentially calculated by the correlation value calculation unit, a counter for counting by a predetermined period unit, and the comparison result, Stores the count value of the counter corresponding to the correlation value having the largest value within a predetermined period among the correlation values, and generates the sync detection signal when the stored count value is generated a predetermined number of times or more in the predetermined period unit. And a synchronization signal generator.

The comparator includes a first memory for storing a correlation value of the digital broadcast signal applied in a previous step, and a comparator for comparing a value stored in the first memory with a correlation value output from the correlation value calculator. desirable.

Preferably, the first memory is reset when the count period of the counter expires.

The synchronization signal generation unit may compare a second memory for storing the count value, a third memory for storing a count value of a previous state, and a value stored in the second memory and the third memory according to a comparison result of the comparator. And the index comparator for determining whether the same coefficient value and the determination result of the index comparator are equal to a predetermined number of times, preferably, the signal generator for generating the synchronization detection signal.

Preferably, the third memory is updated with a value stored in the second memory when the count period of the counter expires.

According to the present invention, in the synchronization signal detection method for detecting a synchronization signal from a received digital broadcast signal, the first correlation value for the preliminary reference noise sequence information and the real component of the digital broadcast signal is calculated. Calculating a second correlation value for the reference pseudo-noise string information and the complex component of the digital broadcast signal, obtaining a sum of squares of the first correlation value and the second correlation value, and calculating the sum of squares of the first correlation value and the second correlation value. Removing a phase offset of the same phase included in the correlation value and the second correlation value, calculating a magnitude of a correlation value for the reference pseudo-noise information and the synchronization signal, and a predetermined magnitude of the calculated correlation values Is achieved by generating a synchronization detection signal at a position having a maximum value within a period.

The generating of the synchronization detection signal may include comparing the magnitudes of the calculated correlation values sequentially with each other and corresponding correlation values having the largest value among the calculated correlation values according to the comparison result. And generating the sync detection signal when a predetermined position is repeated a predetermined number of times at the same position.

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

Figure 3 shows a block diagram according to an embodiment of a synchronization signal detection apparatus according to the present invention.

The illustrated synchronization signal detecting apparatus includes a demodulator 50, a first correlator 60, a second correlator 70, a correlation value calculating unit 80, and a maximum value detecting unit 90.

The demodulator 50 removes the carrier frequency of the digital broadcast signal transmitted from the transmitting side to obtain the transmission signal X (t). That is, the digital broadcast signal applied to the demodulator 50 is A · e^jwt· In the form of X (t), e^-jwtThe frequency of is multiplied by the digital broadcast signal to obtain a transmission signal X (t) having an amplitude of A. At this time, the digital broadcast signal transmitted from the transmitting side is interfered by the peripheral channel, or the phase offset is generated by the multipath signal, and the digital broadcast signal changes the phase by the phase offset θ (A · e^{jwt + θ}) Digital broadcast signal A · e having a phase shift in the form of X (t)^jwtE provided in X (t) and demodulator 50^-jwtThe result of the multiplication of is not represented by the transmission signal X (t). As a result, the phase-changed digital broadcast signal and the frequency e provided in the demodulator 50^-jwtThe multiplication result of is expressed as a real component and a complex component, and is applied to the first correlator 60 and the second correlator 70, respectively. Here, the complex component represents a phase offset.

The first correlator 60 calculates a correlation value with respect to the digital broadcasting signal reference noise series R_PN output from the demodulator 50. In this case, the first correlator 60 calculates a first correlation value for the real component of the digital broadcast signal output from the demodulator 50 and the reference pseudo-noise string information R_PN. Here, the reference pseudo-noise sequence information R_PN is a signal having the same pattern as the synchronization signal included in the broadcast signal transmitted from the transmitter, and has a correlation value at the same position as the synchronization signal included in the digital broadcast signal transmitted from the transmitter. In the calculation, a value equal to the number of symbols constituting the synchronization signal is calculated. Similarly, the second correlator 70 calculates a second correlation value for the complex component of the digital broadcast signal output from the demodulator 50 and the reference pseudo-noise string information R_PN.

The correlation calculation unit 80 takes a square of each of the first and second correlation values calculated by the first correlator 60 and the second correlator 70, and sums the respective values of the squared values. For example, the cos wt + θ component and the sin wt + θ output from the first correlator 60 outputting the correlation value for the real component and the second correlator 70 outputting the correlation value for the complex component, respectively. When the components are squared and summed, they have a size of "1". Accordingly, the correlation value calculator 80 can remove the phase offset generated in the process of being transmitted from the transmitting side to the receiving side. Also, by calculating the magnitude of the final correlation value from the first correlation value and the second correlation value having real and complex components, the maximum magnitude of the correlation value finally obtained by the correlation value calculation unit 80 is " Number of symbols constituting ", and a correlation value larger than an absolute value of a multipath signal having a smaller signal size than a digital broadcast signal transmitted from a transmitter to a receiver through a main path is calculated. Accordingly, the correlation value obtained by the correlation value calculator 80 is not a synchronization signal included in a digital broadcast signal whose signal size is attenuated due to multipath fading, channel interference, and Doppler effects occurring in a mobile environment. Only the synchronization signal included in the (main path) can be effectively detected.

The maximum value detector 90 detects the position of the correlation value having the maximum value within a predetermined period among the correlation values calculated according to the digital broadcast signal according to the main path in the correlation value calculator 80, A sync detection signal sync is generated at the detected position. As described above, the correlation value calculating unit 80 calculates a correlation value with reference pseudo-noise sequence information R_PN provided on the receiving side of the digital broadcast signal transmitted from the transmitting side, but the correlation value in units of a predetermined number of symbols. To calculate. The calculation of the correlation value is performed continuously until the synchronization signal is detected. When the synchronization signal included in the digital broadcast signal transmitted from the transmitting side coincides with the phase of the reference false noise information provided on the receiving side, the maximum The value (number of symbols constituting the synchronization signal) is calculated. Here, the detection period of the maximum value detector 90 is determined in accordance with the period of the signal format of the digital broadcast signal transmitted from the transmitting side. For example, when the digital broadcast signal transmitted from the transmitter is transmitted in units of 836 symbols, the maximum value detector 90 generates a synchronization detection signal sync at a point where the correlation value is the maximum among the count cycles of the 836 symbols.

4A and 4B are diagrams for conceptually explaining a process of calculating correlation values between the first correlator 60 and the second correlator 70 illustrated in FIG. 3.

First, FIG. 4A illustrates a process of calculating a correlation value between an area "A" of a digital broadcast signal applied in the order of A and B from a transmitting side and reference pseudonoise string information R_PN, and FIG. 4B shows a digital broadcast signal. Most of the " A " region and a portion of the " B " As shown, the correlation value calculation of the first correlator 60 and the second correlator 70 is obtained by sequentially multiplying a digital broadcast signal by a predetermined symbol (for example, 511 symbols) and then adding the multiplied values. In this case, the digital broadcast signal is newly applied every time.

FIG. 5 shows a detailed block diagram of the maximum value detector 90 shown in FIG.

The illustrated maximum value detector 90 has a comparator 91, a counter 92, and a synchronization signal generator 93.

The comparison unit 91 compares the phase values in continuously applied from the correlation value calculation unit 80 with the correlation values of the previous state, and when the newly applied correlation values in are larger than the correlation values of the previous state. The update signal w_en is generated.

The counter 92 counts a predetermined number of times in the same period as the period of the preset symbol. For example, a digital broadcast signal transmitted from a transmitting side is transmitted in units of 836 symbols. When the period of each symbol is 5us, 836 symbols are counted at 5us intervals.

The synchronization signal generator 93 stores the count value counted by the counter 92 in response to the update signal w_en from the comparator 91, and synchronizes when the stored count value coincides more than a predetermined number of times for every 836 symbols. Generate a detection signal sync. For example, assuming that the maximum value is calculated at the 293th symbol among the counts of the 836 symbol in the counter 92, the maximum value is calculated at the 293th symbol even when the counter 92 finishes counting the 836 symbol and counts the 836 symbol again. If so, the sync detection signal sync is generated at the 293th position. That is, the synchronization signal generator 93 generates a synchronization detection signal sync at a count value corresponding to a position where the maximum value occurs at the same position at predetermined intervals.

Preferably, the comparator 91 is composed of a comparator 91a and a first memory 91b.

The comparator 91a compares the correlation value stored in the first memory 91b with the correlation value in applied from the correlation value calculator 80, and the correlation value in applied from the correlation value calculator 80. When larger than the correlation value stored in the first memory 91b, the update signal w_en is generated.

The first memory 91b stores the correlation value in applied from the correlation value calculator 80 in response to the update signal w_en generated by the comparator 91a. Accordingly, the first memory 91b stores the largest correlation value until the update signal w_en is generated from the comparator 91a.

Preferably, the synchronization signal generator 93 has a second memory 93a, a third memory 93b, an index comparison unit 91, and a signal generator 93d.

The second memory 93a stores the count value index applied from the counter in response to the update signal w_en generated by the comparator 91a. The third memory 93b is a count value index stored in the second memory 93a in response to a carry value generated at the time when the counter 92 is reset after the counting for the predetermined period is completed. Save it. Accordingly, the third memory 93b updates the pre-stored count value with the count value stored in the second memory 93a for each transmission unit (for example, 836 symbols) of the digital broadcast signal transmitted from the transmitting side.

The index comparison unit 91 compares the count value stored in the second memory 93a with the count value stored in the third memory 93b and compares the count value stored in the previous step with the count value applied in the current step. . As a result of the comparison, the count value corresponding to the point where the maximum correlation value of the previous step has occurred is the same as the point where the maximum correlation value of the current step has occurred, and the synchronization signal included in the digital broadcast signal transmitted from the transmitting side is at It means that it occurs. The index comparison unit 91 generates a detection signal when the same count value is applied for a predetermined number of times (for example, three times), and the signal generation unit 93d responds to the detection signal to detect the synchronization signal. )

6 is a flowchart of a preferred embodiment of a synchronization signal detection method according to the present invention.

First, the demodulator 50 removes the carrier frequency of the digital broadcast signal transmitted from the transmitting side to obtain the transmission signal X (t). That is, the frequency of the transmitted signal e ^-jwt having an amplitude of A multiplied by the digital broadcast signal X (t) in the case where the digital broadcast signal applied to the demodulator 50 in the form of A · e ^jwt X (t) Get At this time, the digital broadcast signal transmitted from the transmitting side is interfered by the peripheral channel, or a phase offset is generated by the multipath signal, and the digital broadcast signal causes a phase change by the phase offset θ (A · e ^{jwt + θ} ) X ( In the case of t), the result of the multiplication of the phase-changed digital broadcast signal A e ^jwt X (t) and e ^-jwt provided in the demodulator 50 is not represented by the transmission signal X (t). Accordingly, the multiplication result of the frequency- ^evolved digital broadcast signal and the frequency e ^-jwt provided in the demodulator 50 is represented by a real component and a complex component, and is applied to the first correlator 60 and the second correlator 70, respectively. . Here, the complex component represents a phase offset.

Next, the first correlator 60 calculates a first correlation value for the real noise component of the digital broadcasting signal demodulated by the demodulation unit 50 and the pseudo-noise sequence information R_PN provided on the receiving side (S100). . Here, the pseudo noise sequence information R_PN is a signal having the same pattern as the synchronization signal included in the digital broadcast signal transmitted from the transmitting side, and the correlation value obtained when the pseudo noise sequence information R_PN and the synchronization signal have the same phase. Is calculated as the number of symbols constituting the synchronization signal. Next, the second correlator 70 calculates a second correlation value for the complex noise (imaginary) component of the pseudo-noise sequence information R_PN provided on the receiving side and the demodulation unit 50 demodulated. (S200). Next, the correlation value calculating unit 80 takes a square of each of the first correlation value and the second correlation value, and adds each square value (S300). Accordingly, the sum of the square values of the first correlation value and the second correlation value including the real component and the complex number component is "1". For example, the cos wt + θ component and the sin wt + θ output from the first correlator 60 outputting the correlation value for the real component and the second correlator 70 outputting the correlation value for the complex component, respectively. Each squared component adds up to an absolute value of "1". Accordingly, the correlation value calculator 80 can remove the phase offset generated in the process of being transmitted from the transmitting side to the receiving side. Also, by calculating the magnitude of the final correlation value from the correlation values of the real and complex components, the maximum magnitude of the correlation value finally obtained by the correlation value calculation unit 80 is "1 x number of symbols constituting the synchronization signal." A correlation value is defined and a correlation value having a value greater than an absolute value of a multipath signal having a smaller signal size than a digital broadcast signal transmitted from a transmitter to a receiver through a main path may be calculated. Accordingly, the correlation value obtained by the correlation value calculator 80 is not a synchronization signal included in a digital broadcast signal whose signal size is attenuated by multipath fading, channel interference, and Doppler effects occurring in a mobile environment. Only the synchronization signal included in the main path can be effectively detected.

Next, an index value corresponding to a position where a maximum value occurs within a predetermined period (for example, 836 symbol periods) among the sum of the plurality of square values calculated by the above process is calculated (S400). The index value means a count value at a point where the counter 92 has a maximum sum of squares among the coefficients in a predetermined period (for example, 836 symbol periods). Next, when the same index value occurs more than a predetermined number of times (for example, three times) (S500), it is determined that a synchronization signal has been detected at a predetermined cycle to generate a synchronization detection signal (S600). As described above, the method of detecting the synchronization signal effectively prevents the synchronization detection error due to the synchronization signal from the multipath whose signal size is relatively smaller than that of the main path or the synchronization signal due to the Doppler effect generated in the mobile environment. Can be reduced.

As described above, the present invention can minimize the influence of the phase offset included in the digital broadcast signal transmitted from the transmitter to the receiver by the multipath or Doppler effect, and the synchronization signal included in the main path. Only bays can be detected effectively.

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 (8)

In the sync signal detecting apparatus for detecting a sync signal from the received digital broadcast signal, A first correlator for calculating a first correlation value for the reference pseudo-noise string information and the real component of the digital broadcast signal; A second correlator for calculating a second correlation value for the reference pseudo-noise sequence information and the complex component of the digital broadcast signal; A sum of squares of each of the first correlation value and the second correlation value is obtained to remove a phase offset having the same phase included in the first correlation value and the second correlation value, and the reference pseudo-noise information A correlation value calculator for calculating a magnitude of a correlation value with respect to the synchronization signal; And And a maximum value detector configured to generate a synchronization detection signal at a position having a maximum value within a predetermined period among the calculated correlation values. The method of claim 1, The maximum value detector, A comparison unit sequentially comparing adjacent correlation values among correlation values sequentially calculated by the correlation value calculation unit; A counter that counts in a predetermined period unit; And According to the comparison result, and stores the coefficient value of the counter corresponding to the correlation value having the largest value within a predetermined period of the correlation value, when the stored coefficient value is generated more than a predetermined number of times in the predetermined period unit, And a synchronization signal generator for generating the synchronization detection signal. The method of claim 2, The comparison unit, A first memory for storing a correlation value of the digital broadcast signal applied in a previous step; And And a comparator for comparing a value stored in the first memory with a correlation value output from the correlation value calculator. The method of claim 3, The first memory, And resetting when the count period of the counter expires. The method of claim 3, The synchronization signal generator, A second memory for storing the count value according to a comparison result of the comparator; A third memory for storing the count value of the previous state; An index comparison unit comparing the values stored in the second memory and the third memory to determine whether the same coefficient value exists; And And a signal generator for generating the synchronization detection signal when the determination result of the index comparison unit is equal to a predetermined number of times. The method of claim 5, The third memory, And when the count period of the counter expires, update to a value stored in the second memory. A synchronization signal detection method for detecting a synchronization signal from a received digital broadcast signal, Calculating a first correlation value of the reference pseudo-noise string information and the real component of the digital broadcast signal; Calculating a second correlation value for the reference pseudo-noise sequence information and the complex component of the digital broadcast signal; The sum of the squared values of the first correlation value and the second correlation value is obtained to remove phase offsets of the same phase included in the first correlation value and the second correlation value, and are synchronized with the reference pseudo-noise string information. Calculating a magnitude of a correlation value for the signal; And And generating a sync detection signal at a position having a maximum value within a predetermined period of the calculated correlation values. The method of claim 7, wherein Generating the sync detection signal, Sequentially comparing adjacent sizes of the calculated correlation values; And Generating the synchronization detection signal when a position corresponding to the correlation value having the largest value among the calculated correlation values is repeated a predetermined number of times or more at the same position according to the comparison result; Signal detection method.