KR100492467B1 - A segment and field sync recovery device - Google Patents

Abstract

A symbol correlator for correlating data segment synchronization with a preload signal of the PN511, a field counter for confirming that the maximum value of the correlator passes through one field, and the maximum value of the correlator includes one field. A count counter that counts up when it reaches its maximum value and counts down when its value is not the maximum value, and generates a prelock signal when the count value reaches a predetermined threshold, and finally again. Using a recording confirmation device to ensure the reliability of the recording once, a synchronization generator that generates a synchronization signal with the maximum count value obtained from the confidence counter, a maximum count value of the postlock signal and the confidence counter and a data input signal. Including a Foe sync generator for generating a Foe sync signal for determining whether the field is even or odd In addition, it is possible to optimize the hardware resources by using the Foe synchronization generator and the synchronization check device instead of the field synchronization generator and the PN comparator, and also to recover the segment and the field synchronization quickly and stably. To provide.

Description

Segment and field sync recovery device

The present invention relates to a segment and field synchronous recovery apparatus, and more specifically, it is possible to optimize hardware resources by using a Foe synchronization generator and a synchronization check apparatus instead of a field synchronization generator and a PN comparator, and also to recover segment and field synchronization. The present invention relates to a segment and field synchronization recovery apparatus capable of performing a fast and stable operation.

As shown in FIG. 1, the transmission data structure of the digital side TV (Vestigial Side Band, VSB) has 832 symbols forming one data segment, and these data segments are collected in 313 pieces. It consists of a form of one field.

The synchronization of the data segment is composed of the first four symbols (1, -1, -1,1) of every data segment.

The field synchronization is composed of the first data segment of every field. The structure of the field synchronization is four symbol SegSync and 511 symbol pseudo-random as shown in FIG. It consists of Pseudo-Random sequence (PN511), PN63, PN63 *, PN63, 24 symbols of VSB mode, 32 symbols of Reserved, and 12 symbols of PreCode.

The second (PN63 *) of the PN63 sequence inverts its value as each field changes.

The PN sequence for each is defined as in Equations 1 and 2 below.

1) PN511: X ⁹ + X ⁷ + X ⁶ + X ⁴ + X ³ + X + 1, Preload (-1,1, -1, -1, -1, -1, -1, -1, -One)

Equation 2) PN63: X ⁶ + X + 1, Preload (1, -1, -1,1,1,1)

The transmission data having the structure as described above is recovered by the segment and field synchronous recovery apparatus. The configuration of the conventional segment and field synchronous recovery apparatus, as shown in FIG. 13 symbol correlator 11 for the PN511 preload signal of the symbol, a field counter 16 for confirming that the maximum value of the correlator 11 passes through one field, and the correlator 11 When the maximum value passes through one field and reaches the maximum value, it counts up and counts down when the value is not the maximum value, and when the count value reaches a predetermined threshold value, the prelock signal (nPreLock) Compares the input signal and the reference field synchronization signal with a confidence counter 12 for generating a signal, a field synchronization generator 13 for generating the reference field synchronization patterns PN511 and PN63 using a prelock signal nPreLock, and To the PN comparator 14 which generates a postlock signal nPostLock and the synchronization generator 15 which produces an output synchronization signal using the maximum count value of the postlock signal nPostLock and the confidence counter 12. It is composed.

4 shows the structure of the PN511 generator 131 of the field synchronous generator 13 described above. The preload value is -1,1, -1, -1, -1, -1, -1, -1. Has -1

FIG. 5 shows the structure of the PN63 generator 132 of the field synchronous generator 13 described above. The PN63 generator 132 has a proload value of 1, -1, -1,1,1,1. Since the sequence is inverted, an inverter and a 2x1 multiplexer are further connected to produce a signal inverted every field using the Foe sync signal.

The operation of the conventional segment and field synchronization recovery apparatus having the structure as described above is performed as follows.

First, in the correlator 11, 13-symbol association is performed on the input signal data_in, 4-symbol data segment synchronization, and 9-symbol PN511 preload signal.

At the same time, the count is started for every symbol by the field counter 16 of 260416 (832 x 313), and the count value when the output value of the correlator 11 is maximized is stored.

Thus, the correlator 11 continuously associates the incoming input signal, and the field counter 16 resets after one field and starts counting again.

By repeating this process, the confidence counter 12 is counted up when the value of the field counter 16 for the maximum value coincides with the previously stored value and vice versa of the field counter 16 for the maximum value. When the value does not match the previously stored value, the confidence counter 12 is counted down. Therefore, the maximum count value is replaced with a new value.

Next, when the confidence count value is greater than the threshold value, the pre-lock signal nPreLock is output to the field synchronization generator 13 in a low state.

The field synchronization generator 13 has a preload value of the PN511 generator 131 shown in FIG. 4 and a preload value of the PN63 generator 132 shown in FIG. 5 when the prelock signal nPreLock becomes low. After loading, the reference sequence is generated in the order of PN511, PN63, and PN63 * and output to the PN comparator 14.

The PN comparator 14 compares the incoming input signal with the reference field sync sequence and outputs a postlock signal nPostLock to the sync generator 15 in a low state.

The synchronization generator 15 generates a synchronization signal such as nDSSync, nFSync, nSyncLock, Foe, etc. with the maximum count value obtained from the confidence counter 12 when the postlock signal nPostLock falls low.

As shown in Fig. 5, the Foe sync signal is used to invert the second PN63 * sequence in every field. Since the PN comparator 14 shown in Fig. 3 is initially locked in the even field, the Foe sync signal is changed from the next field. Toggle using the nFSync signal.

However, although the field sync generator 13 and the PN comparator 14 of the conventional segment and field synchronous recovery apparatus play an important role in increasing the reliability of the sync lock signal, they are efficient in terms of hardware resources. There is a problem. In addition, in order to generate a postlock signal (PostLock), there is a problem in that an additional time delay occurs by comparing 700 symbols.

An object of the present invention is to solve such a conventional problem, and it is possible to optimize hardware resources by using a Foe synchronization generator and a synchronization device in place of the field synchronization generator 13 and the PN comparator 14, and further, segmentation. And a segment and field synchronization recovery apparatus capable of performing a fast and stable recovery of field synchronization.

As a means for achieving the above object, the configuration of the present invention provides a symbol correlator for performing correlation between data segment synchronization and a preload signal of the PN511, and for confirming that the maximum value of the correlator passes through one field. The field counter and the correlator count up when the maximum value of the correlator passes through one field and reaches the maximum value again, and counts down when the value is not the maximum value, and the count value reaches a predetermined threshold value. A synchronization counter that generates a pre-lock signal when used, a synchronization check device that ensures the reliability of the recording once again, a synchronization generator that generates a synchronization signal with the maximum count value obtained from the confidence counter, and a post-lock Determining whether the field is even or odd using the maximum count value of the signal and the confidence counter and the data input signal It comprises a Foe sync generator for generating a Foe sync signal.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings in order to describe in detail enough to enable those skilled in the art to easily carry out the present invention. . Other objects, features, and operational advantages, including the object, operation, and effect of the present invention will become more apparent from the description of the preferred embodiment.

For reference, the embodiments disclosed herein are only presented by selecting the most preferred examples to help those skilled in the art from the various possible examples, the technical spirit of the present invention is not necessarily limited or limited only to this embodiment. However, various changes and modifications are possible within the scope without departing from the technical spirit of the present invention, as well as other equivalent embodiments.

As shown in Fig. 6, the configuration of the segment and field synchronization recovery apparatus according to the embodiment of the present invention includes 13 symbol correlators 21 for 4 symbol data segment synchronization and 9 symbol PN511 preload signals. When the field counter 23 for confirming that the maximum value of the correlator 21 passes through one field and the maximum value of the correlator 21 have the maximum again after passing one field, Count up and count down when the value is not the maximum value, and record the record again with the Confidence Counter 22 which generates a pre-lock signal (PreLock) when the count value reaches a predetermined threshold. A synchronization recorder 25 for generating a synchronization signal such as nDSSync, nFSync, nSyncLock, etc. with the maximum count value obtained from the confidence counter 12, and a post-lock signal P and a Foe sync generator 26 for generating a Foe sync signal for determining whether the field is even or odd using the maximum count value of the ostLock and the confidence counter 12 and the data input signal data_in.

That is, the conventional PN comparator 14 and the field synchronous generator 13 are omitted, and the structure is replaced with the recording confirmation device 24 and the Foe sync generator 26 which are much simpler and more effective.

With the above configuration, the operation of the segment and field synchronization recovery apparatus according to the embodiment of the present invention is as follows.

In the 13 symbol comparator 1, the 4 symbol data segment synchronization and 9 symbol PN511 preload signals are associated with the input signal. In this case, the maximum value is obtained when the incoming signal sequence matches 13 symbols.

Next, the confidence counter 22 receives the output of the correlator 21 to find the maximum value using the past value and the present value, and the count value of the field counter 23 is the maximum count value (max_count). Is output as At the same time, the maximum count value max_count is stored as a past maximum count value.

After counting for the first field, repeat the same thing in the second field, and if the second maximum count value matches the past maximum count value, increase the confidence count value up to a predetermined maximum limit value and do not match. If not, reduce it to the minimum limit specified.

The repeater counter 22 outputs a prelock signal when the confidence count value is greater than or equal to a predetermined threshold value after repeating the above process. The threshold value here has the opposite effect on the time and reliability of synclock. In other words, the smaller the value, the less time it takes to synclock, but the reliability is less. On the other hand, the larger the value, the opposite is the effect.

The field counter 23 repeatedly counts for one field symbol 832 x 313.

The recording confirmation apparatus 24 finally guarantees the reliability of the recording once again. If it is assumed that the input signal is fixed at a constant value, the value of the correlator 21 is always constant, and this value becomes the maximum value, thereby increasing the confidence count value. May occur. To prevent this, the DSSync symbol is found with the prelock signal (PreLock) and the maximum count value (field synchronization start point), and compared with the actual DSSync symbol (1, -1, -1,1) to finally lockconfirm signal (LockConfirm). Create

The synchronization generator 25 uses the maximum count value to generate an nDSSync signal that remains low for DDsync 4 symbol intervals and an nFSync signal that remains low for FSync 832 symbol intervals. In addition, the lock confirmation signal LockConfirm is received from the recording confirmation device 24 to generate a recording signal nSyncLock which is kept low during the recording.

The Foe generator 26 finds the starting point of the PN63 or PN63 * sequence using the maximum count value (max_count), and then uses the preload values (1,1,1, -1, -1, -1) of the PN63. To determine whether the field is even or odd.

As described above, in the embodiment of the present invention, by using the Foe sync generator and the sync check device instead of the field sync generator and the PN comparator, hardware resources can be optimized, and the recovery of the segment and the field sync can be made quickly and stably. It is possible to provide a segment and field synchronization recovery apparatus having an effect that can be performed. This effect of the present invention can be applied to various applications within the scope of the technical idea of the present invention in the field of segment and field synchronous recovery.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the structure of the transmission data in the residual sideband of a digital television.

Fig. 2 is a diagram showing the structure of the field synchronization segment of transmission data in the residual sideband of digital television.

3 is a block diagram of a conventional segment and field synchronization recovery apparatus.

4 is a block diagram of a field synchronization generator of a conventional segment and field synchronization recovery apparatus.

5 is a block diagram of a field synchronization generator of a conventional segment and field synchronization recovery apparatus.

6 is a block diagram of a segment and field synchronization recovery apparatus according to an embodiment of the present invention.

Explanation of symbols on main parts of the drawing

21: Correlator 22: Confidence Counter

23: field counter 24: copper record check device

25: Sync generator 26: Foe sync generator

Claims (2)

A correlator for correlating an input signal with a data segment sync symbol and a symbol of a PN511 preload signal; A field counter that repeatedly counts for each symbol for each of the plurality of fields; The maximum value of each field is detected from the output signal of the correlator, and the maximum counter value of the previous field and the maximum counter value of the current field are determined by setting the counter value provided from the field counter as the maximum counter value at the time when the maximum value is detected. If there is a match, the coffee redundancy counter value is increased to a predetermined limit value; otherwise, the coffee redundancy counter value is reduced to a predetermined minimum limit value, and when the coffee redundancy counter value is more than a predetermined threshold value, a prelock signal is generated. A coffee redundancy counter; The data segment sync symbol of each field is detected using the prelock signal and the maximum counter value output from the coffee redundancy counter, and the lock confirm signal is compared with the detected data segment sync symbol and the actual data segment sync symbol. A recording record generating device; Generates a data segment sync signal maintaining a constant level during the data segment sync symbol period using the maximum counter value output from the coffee redundancy counter, and generates a field sync signal maintaining the level during the field sync symbol period. And a synchronization generator for generating a recording signal for maintaining the level during the recording period according to the lock confirm signal; And A start point of a PN63 or PN63 * sequence is detected using the maximum counter value output from the coffee redundancy counter, and then a Foe synchronization signal is generated by determining whether the current field is even or odd using the preload value of the PN63. A Foe sync generator; Segment and field synchronization recovery device comprising a delete