DE3930085A1 - METHOD FOR DIGITAL TRANSMISSION OF A SIGNAL - Google Patents

Description

The invention is based on a method for digital Transmission of a signal according to the generic term of Claim 1.

The conversion of an analog signal into a digital signal by a time-selective sampling process can be understood as a multiplication of the analog signal by a sampling signal. The analog spectrum is multiplied on carriers which occur at a multiple of the frequency of the scanning signal. If the frequency bandwidth of the analog signal is not limited to half the frequency of the scanning signal, there are disruptive overlaps in the frequency spectrum, which are referred to as alias interference. For this reason, pre-filtering of the analog signal with a low-pass filter is prescribed before an A / D conversion. The frequency bandwidth (f _g ) of the low-pass filter depends on the sampling frequency (f _s ).

After a digital transmission, which, for. B. also one digital signal processing or a magnetic Recording and playback operation can include takes place a reconstruction of the transmitted and D / A converted  Signals by post-filtering with another Low pass filter. Decisive for the cutoff frequency further Low pass filter is next to the sin (x) / x function of the D / A converter here too the frequency of the scanning signal.

According to the theory, a pass band is sufficient for the amplitude frequency response of the two low-pass filters, which runs in a straight line in the frequency range from 0 Hertz to the cut-off frequency (f _g ). Outside of the pass band, the two low-pass filters should block completely. In practice, such steep-sided low-pass filters cannot be produced with reasonable effort.

From the US magazine "SMPTE-Journal", Oct. 1981, pp. 949 to 955 is a method of improving the subjective Image quality of digital television signals known, in which several filters with different from the cutoff frequency declining amplitude frequency response in the transmission path are inserted. The different filter characteristics reduce disturbances in brightness jumps in TV signals, however, the filter effort is still considerably. In addition, this known method has the Disadvantage that with a series connection of several A / D and D / A converter the frequency response errors in the Passband of the filters can be added. This is true especially towards simple filters with a small atomic number, e.g. B. with Tschebycheff and Butterworth filters, whose Passband passes very steeply into the restricted area. These However, a greater ripple in the property Passband of these low-pass filters bought.

The present invention is based on the object Specify the method according to the type mentioned at the beginning, which the use of simple filters with larger ones Amplitude ripple allowed in the pass band.

This task is carried out in the characterizing part of the Features specified claim 1 solved.  

The inventive method with the characteristic Features of claim 1 has the advantage that simpler and therefore cheaper low-pass filters can be. Associated with that on the low pass filters usually downstream all-pass filter to smooth the Group runtime can be waived.

By the measures listed in the subclaims advantageous developments and improvements in Claim 1 specified method possible.

An embodiment of the invention is in the drawing shown and in the description below explained. Show it:

Fig. 1 is a block diagram of a digital transmission device,

Fig. 2 shows the normalized frequency response of a low pass filter for pre-filtering,

Fig. 3 shows the standardized frequency response of a low-pass filter for post-filtering and

Fig. 4 shows the resulting normalized frequency response of low-pass filters for pre- and post-filtering.

In the block diagram of FIG. 1, an analog signal for frequency band limitation is fed to a low-pass filter 2 via a terminal 1 . The cut-off frequency f _{g of} the low-pass filter 2 is designed so that the Shannon scanning law for spectra is observed. In the present case, the signal bandwidth determined by the cut-off frequency of the low-pass filter 2 and the sampling frequency f _{s of} a sampling signal fed to a terminal 3 should behave in accordance with the ratio 2 f _g <= f _s . The scanning signal supplied via terminal 3 is used to control an A / D converter 4 , which scans, quantizes and encodes the low-pass filtered analog signal in a time-selective manner.

It is assumed that the signal which can be taken off in digital form at the output of the A / D converter 4 is fed to a transmission link 5 which consists of the magnetic recording and reproducing channel of a digital video tape recorder. The digital signal received on the reproduction side is converted back into an analog signal with a D / A converter 6 and passed on to a low-pass filter 7 for post-filtering. The low-pass filter 7 is usually adapted to the transfer function of the D / A converter 6 and therefore has a sin (x) / x curve of the amplitude frequency response. At an output terminal 7 of the low-pass filter 7 , a reconstructed analog signal can be removed, which corresponds in frequency and time to the input-side analog signal when ideal low-pass filters with a rectangular transition between pass and stop band and linear amplitude and phase curve in the pass band are used.

As mentioned at the beginning, such ideal filters can be used reasonable effort can not be produced. Self elaborate low-pass filters have ripples in the pass band when copying video signals several times with a digital video magnetic tape recorder causing significant interference can lead in a reproduced television picture. Especially when editing video signals, in which for example 20 generations of an original video signal errors are accumulated, the cause of which is the ripple in the amplitude frequency response low-pass filter provided for pre- and post-filtering is.

According to the invention, the low-pass filters 2 and 7 provided for pre- and post-filtering are designed so that their atomic numbers (degrees) differ by 1. In the event that the low-pass filter 2 has an ordinal number of n = 4, the low-pass filter 7 is to be dimensioned such that its ordinal number is either n = 3 or n = 5. In addition, the normalized frequency of one of the low-pass filters is multiplied by a suitable factor k so that the "peaks" in the amplitude frequency response curve of one filter correspond to the "valleys" in the amplitude frequency response curve of the other filter.

The procedure is to ensure that the echo attenuation (ripple) of the the two filters are chosen essentially the same.

The normalized frequency responses indicated in FIGS. 2, 3 and 4 may clarify this fact. For this purpose, it is assumed that a Tschebycheff low-pass filter is selected for the pre-filtering from the book by G. Pfitzenmaier "Table book low pass", Siemens AG, Berlin, 1971, whose atomic number n = 4 and whose echo attenuation is 13 dB. A Tschebycheff filter with 13 dB echo attenuation is also selected as the low-pass filter 7 , but its atomic number is 5. In Figs. 2, 3 and 4, the amplitude attenuation are a _b plotted on the abscissa and the normalized frequency Ω on the ordinate. Fig. 2 shows the corresponding course of the ripple in the pass band of the low-pass filter provided for prefiltering 2 and Fig. 3 the corresponding Welligkeitsverlauf in the passband of the low-pass filter is provided for post-filtering. 7 By multiplying by the factor k = 1.14, the scaling of the standardized frequency response Ω for the low-pass filter 7 provided for post-filtering is expanded such that minima and maxima correspond to one another in the course of the ripples of the two filters 2 and 7 , so that the result is a smoothed one Transmission characteristics arise at the end of the transmission system. The resulting echo attenuation is only a few percent of the individual echo attenuations. The insertion loss associated with this compensation can be compensated for by linear amplification on the transmission link.

Claims (3)

1. Method for the digital transmission of a signal, in which an analog signal with a first low-pass filter is frequency-band-limited and converted into a digital signal with an A / D converter, and with which the digital signal with a D / A converter in an analog signal is converted back and subsequently filtered with a second low-pass filter, characterized by a first low-pass filter ( 2 ) with a first ordinal number (n) and a second low-pass filter ( 7 ) with a second ordinal number (n + 1 or n-1), which differs from the first atomic number (s) by 1. 2. The method according to claim 1, characterized in that a normalized frequency response curve of one of the filters ( 2 or 7 ) is multiplied by a factor (k) such that the minima and maxima in the echo attenuation curve of the two filters have a complementary curve to one another. 3. The method according to claim 1 and 2, characterized in that the low-pass filter ( 2 , 7 ) different ordinal number are used in a magnetic tape device for digital recording and playback of video signals.