KR0124161B1 - Data generation apparatus for evaluating the performance of interlaced-progressive converter - Google Patents

Abstract

A data generator is provided which accurately estimates the performance of an interlaced-progressive scanning converter more easily. The data generator includes means for receiving a video signal and passing only a signal of low frequency domain in order to prevent signal overlap, means for interpolating data of a frequency domain which passed the data overlap preventing means with data of a predetermined domain using predetermined data, and means for resampling the interpolated data in a predetermined sampling period on the basis of the interpolated data and, when there is an error in the resampled data, correcting it.

Description

Data generation device for performance evaluation of a circuit-to-circulator

1 is a block diagram showing an embodiment of a data generating apparatus for performance evaluation of a converter according to the present invention.

2a to e are diagrams showing data results of respective parts of the block diagram shown in FIG.

* Explanation of symbols for main parts of the drawings

110: region pass filtering circuit 114: data reduction circuit

118: resampling circuit 122: data correction circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image data generating apparatus, and more particularly, to a data generating apparatus for evaluating the performance of a transducer for evaluating the performance of an interlaced-progressive scanning converter.

Digital video signal transmission / reception system converts image data using progressive scan method into forward scan data for compression encoding or decoding and other signal processing. Also, when system designer performs operation and performance test, etc. There are times when you need to convert data scanning. In the interlaced (or interlaced) scan method, when a frame is output or displayed on an electric screen, the odd field is first scanned and then the even field is first divided by dividing the field with the odd scan lines and the field with the even scan lines. On the other hand, the progressive (or sequential) scanning method scans one frame sequentially from the top to the bottom without skipping the scan line.

As stated above, if the designer or service engineer wants to evaluate the conversion performance of a converter that converts the scanning method of the data, conventionally the performance of the converter is improved because the result of conversion to forward scanning is not enough for the evaluation of the conversion. There was a problem that it is difficult to judge correctly.

Accordingly, an object of the present invention is to generate a data for performance evaluation of a scanning converter by applying data reduction, resampling, and data correction techniques, and to provide a data generating apparatus for performance evaluation of a permutation-circulating converter that can more easily and accurately evaluate its performance. To provide.

According to an embodiment of the present invention, the present invention provides a data generator for evaluating the performance of a perforation-scanning transducer more accurately and easily. Data overlapping prevention means for passing only a signal in the low frequency region, data contracting means for interpolating the data in the passed region to data in a predetermined region using preset data, and based on the reduced data. And resampling between the condensed data in a set sample period, and correcting data when an error occurs in the resampled data.

In addition, the data overlapping prevention means according to an embodiment of the present invention limits the bandwidth of the input signal to less than half the sampling frequency.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

FIG. 1 is a block diagram showing a preferred embodiment of a data generating apparatus for evaluating the performance of a perforation-circulating scan converter according to the present invention. FIG. 2 is a diagram showing the data conversion state on the time axis of each part shown in FIG. It is a figure which shows. 1 and 2, the data generating apparatus of the present invention includes a low pass filtering circuit 110, a data reduction circuit 114, a resampling circuit 118 and a data correction circuit 122. The low pass filtering (LPF) circuit 110 limits the bandwidth of the input signal to less than half the sampling frequency in order to prevent data aliasing when performing the data abbreviation described below by passing only the low frequency of the predetermined signal. Is a filter. This filter inputs an associative scanning image data string (see FIG. 2 (a)) through the line 109 to pass only the region below the predetermined low frequency as described above, and thus the data of the frequency domain on the time axis. A data string (Fig. 2 (b)) having the same location but different data values is generated on the line 111. To implement such a filter digitally, a finite impact response (FIR) filter having a predetermined number of taps and coefficients may be used in consideration of signal characteristics.

Data Decimation Circuit 112 is a known circuit that reduces the sampling rate by regularly shortening a portion of a sample of data obtained by performing data overlap prevention filtering. The circuit 112 samples the data string input through the line 111 (see FIG. 2 (b)) at a predetermined ratio to reduce the amount of information or to conform to the system scanning standard even in view of some degradation in image quality. This occurs on line 115 by reducing a portion of (see Figure 2 (c)).

Re-sampling circuit 118 is a known circuit that inputs abbreviated data into a preset frequency domain and resamples it to produce more data in the same region as the abbreviated data domain. This circuit 118 is a preset frequency to more accurately and easily evaluate the performance of the scanning transducer of the present invention with respect to the abbreviated image data (see FIG. 2 (c)) input coupled to line 115. Based on the region (i.e., the low pass filtered frequency region), it is resampled to a preset sampling rate (see FIG. 2 (d)) and occurs on line 119. FIG.

Finally, the Data Correction circuit 122 is a well-known circuit that corrects when an error occurs in the input data or the data is not in the desired area. This circuit 122 is coupled to line 119 to input the resampled data string (see FIG. 2 (d)) so that the data presence point is set identical to the resampled state so that the faulty data is corrected and the error is corrected. Is generated on the line 123 by outputting the data without the data, and generating a new data string that can accurately and easily evaluate the performance of the scan converter.

As described above, by using the resampling and data correction techniques known to generate data for evaluating the data scan converter, there is a great effect of easily and accurately evaluating the performance of the perforated-circuit scan converter.

Claims (1)

A data generating device for evaluating converter performance for more accurately and easily evaluating the performance of an interlaced-progressive scanning converter; A data overlapping prevention means for inputting a video signal of a parallel scan method to pass only signals in a predetermined local frequency domain in order to prevent signal overlapping, and limiting a bandwidth of the input signal to less than half of a sampling frequency; Data reduction means for shortening and outputting data at a predetermined ratio with respect to the data of the passed area; Resampling means for resampling between the condensed data at a predetermined sample period based on the condensed data; And data correction means for correcting an error in the resampled data.