SK34293A3 - Decoding of composite television signals - Google Patents

Abstract

A broadcast system is provided in which the effects of differential distortions on composite television signals are reduced. At predetermined intervals, the broadcast signal includes a test signal having high frequency components at at least three average video signal levels. In a suitably equipped receiver, following demodulation by the receivers vision demodulator (20), a test signal is identified by a test signal detector (34). Measurement apparatus (24) then measures the distortion of the test signal at a number of different average video signal levels, calculates the correction required to minimise the effect of distortion at each measured signal level, and stores the corrections in a memory (28) at address locations derived from the demodulated signal by a filter circuit (32). The stored corrections are applied to an interpolator (40) which derives further corrections for other average video signal levels, the derived corrections being applied to subsequently received television signals by a controllable equaliser (38). <IMAGE>

Description

The present invention relates to the field of composite television signal transmission systems, and in particular to a method and apparatus for reducing the effect of differential distortion of demodulated broadcast video signals.

BACKGROUND OF THE INVENTION

A known problem of PAL, NTSC and other similar systems transmitting a composite TV signal is that the broadcast signal is often subjected to amplitude or phase distortion. These distortions are usually introduced into the signal as a result of modulating the signal to a high-frequency carrier signal before transmitting and demodulating the transmitted signal at the receiver. Several factors contribute to the distortion of the video signal, which are influenced by the average level of the modulated signal carrier, with the result that when the new signal is demodulated, the distortions become both differential and distortions that change with the average signal level.

While these distortions are taken into account when designing known composite TV receivers, using delay line decoders and color saturation control in PAL system receivers, and using color and saturation control in NTSC receivers, these measurements only allow for average correction. In order to improve the quality of the signal to be transmitted by existing terrestrial television systems and in new television systems that use the methods of producing composite coded signals, it is necessary to provide improved receivers that use more accurate distortion correction methods.

SUMMARY OF THE INVENTION

This object is achieved by a method of reducing the effect of differential distortion of demodulated composite television signals according to the invention, which comprises the steps of transmitting a test signal at predetermined intervals, wherein the test signal comprises a component at least one level of an average video signal. a receiver, wherein the receiver is adapted to perform the steps of measuring video signal distortion at said at least one average video signal level, deriving a desired correction at said signal level, and applying said derivative requested correction to the next received video signals at said signal level.

According to the invention, there is also provided a test signal for use in the above method, which consists of a single line composite television signal having an identification portion for identifying itself as a test signal and having high frequency components at at least three levels of the average video signal.

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The test field signal or after the test signals may be longer, the transmitted period of time should be spaced a few or so once, in the following seconds.

The method of the invention may comprise the step of measuring the amplitude and phase distortion of a series of average test signal levels and the derivation of the correction to be applied to the subsequent received signals for each such distortion at each measured average video signal level. Thus, if the levels of demodulated color difference or chrominance are substantially reduced at higher levels of the average signal (i.e., close to the white tip) by signal distortion at modulation, transmission and demodulation, the effect of these distortions can be corrected by increasing chrominance gain when the signal level is high. These corrections are preferably used in the signal in its composite form also to allow correction of the level of high-frequency brightness (image detail). The correction can be derived and applied at many different frequencies to improve the accuracy of the timing correction.

The derivative corrections may be interpolated or extrapolated to derive the correction to be used at an average video signal level other than the component levels of the test signal.

Preferably, the corrections are applied to. subsequently receiving signals at closely distant signal levels to achieve a smooth correction change that adds invisible distortion to the transmitted signal.

The aforesaid task is further accomplished by a receiver adapted to receive and demodulate a composite television signal according to the invention, comprising a detector for detecting a test signal transmitted at predetermined intervals, a measuring device adapted to determine the level of differential amplitude and / or phase distortion ο

a received test signal in at least one average video signal level and to derive a correction necessary to reduce distortion at that signal level or levels, a memory connected to receive a derivative desired correction or corrections, and a signal processing apparatus adapted to apply the desired correction or corrections to the subsequently received television signals at the level or levels of the average video signal for which the correction has been or has been derived.

The receiver is designed to perform derivation and apply corrections or corrections as described above. The device may be incorporated into an analog or digital circuitry wherein the receiver comprises a high-speed computer, and certain device operations may be incorporated into the Software.

The invention also relates to a broadcast system comprising a transmitter adapted to modulate and transmit a composite television signal comprising a test signal, and at least one receiver of the type described above. In these broadcast systems, the differential distortions of the transmitted signals can be corrected much more accurately than with the average correction methods known and used hitherto.

Drawing overview {

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the accompanying drawings, in which: FIG. 1 shows a schematic diagram of the steps of the correction derivative and the application of the receiver according to the invention, FIG. 2A and 2B show suitable shapes of a test signal according to the invention; and FIG. 3 is a schematic diagram of the stages of the receiver of FIG. 1 incorporated into the digital circuitry.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 2 shows two suitable test signal shapes according to the invention. Both signals used to correct for color difference or chrominance errors are in the form of a transmitted line signal containing high frequency components, which can be measured at at least three different levels of the average video signal. First signal 10A. shown in FIG. 2A, is in the form of a television line function and a second signal 10B. shown in FIG. 2B is in the form of a television staircase function. The two signals shown are augmented by the subcarrier.

Signals of this type are readily detectable and are identified by upstream chrominance separation 12, lasting at least 20 m cross-seconds.

The circuitry measuring the distortion of the test signal and deriving the corrections necessary to minimize its effect includes a correction memory to allow their use for the subsequent received television signals. This is the case when a test signal that adjusts the stored corrections needs to be transmitted often enough to ensure that there is no apparent delay in obtaining a good picture after the TV viewer has changed the channel or after the quality of the received signal has changed as a result of signal path changes for distribution, transmission or reception. Thus, although the test signal may be transmitted once per field, smaller repetition rates may be used than once per second or once every 10 seconds.

A receiver circuitry that derives and performs the desired amplitude and phase distortion correction affecting a single frequency (color subcarrier) of the signal at various video signal levels is shown in FIG. First

A television broadcast signal containing a test signal at periodic intervals is received and demodulated by the video demodulator 20 of the receiver. The demodulated signal 22 is fed to the measuring device 24, which measures the difference between the chrominance level of the received (distorted) signal and the expected chrominance level of the transmitted test signal and derives or derives a correction that minimizes the effect of the distortion. The differentiated corrections 26 are then stored in the memory 28 at the address memory locations 30 determined by the average brightness level of the demodulated signal 22. The average brightness level, and therefore the address memory locations 30, are derived by passing the demodulated signal 22 through a suitable low-pass filter 32.

To ensure that only the corrections derived from the received test signal are stored in the memory 28, a test signal detector 34 is provided. When a test signal is received, marked as such by a previous chrominance separation 12 lasting 20 microseconds (FIG. 2), the detector 34 generates a write signal 36 that allows derivative corrections to be written to the memory 28 for the duration of the test signal.

The stored corrections are then applied to the further received television signals by the controllable equalizer 38. The control of the equalizer 38 can be performed in a number of ways.

The stored corrections pass through the interpolator 40 before being fed to the equalizer 38. The interpolator 40 further derives the desired corrections to be usable at average video signal levels other than those for which the measuring device 24 measured the test signal distortion. The use of the interpolator 40 allows the use of corrections at closely spaced levels of the average video signal to produce a smooth variation correction that adds no visible additional distortion to the video signal.

A more detailed embodiment of the receiver circuitry is shown in Fig. 3. In the circuit arrangement shown, the distortion is measured and the corrections derived from the test signal of FIG. 2A (television line function). The output from the receiver image demodulator 20 is digitized by an analog to digital converter 42; this allows the subsequent determination of the measurement and correction steps by known digital operations, although it should be noted that some of these steps may be performed in analog circuits.

The digitized output from the A / D converter 42 is fed to both the chromium-plated demodulator 44. This chrominance demodulator 44, which could be a normal receiver demodulator, is shown in Fig. 3 for clarity as a separate demodulator.

The demodulated chrominance components U, V are fed to the measuring device 24. The amplitude of the demodulated signal is calculated by the programmable burner 24A (PROM) as the root of the sum of squares of the two demodulated color components U, V. ) as the inverse tangent ratio of both demodulated color components U, V. These two measurements of 26ft. 26P. which determine the corrections to be applied to the next received signal e are then stored in the memories 28A. 28P amplitude and phase correction.

As described above, corrections are stored in address memory locations 30 derived from the average brightness level of the demodulated signal by the low pass filter 32. As described, these corrections can only be stored if the write signal 36 from the test signal detector 34 indicates the presence of the test signal. signal.

After interpolation with appropriate amplitude and phase interpolators 40A. 40P, corrections are applied to controllable equalizer 38. This compensator 38 is an adjustable transverse compensator with a signal input 50 for a demodulated broadcast video signal and a separate control symmetric input 52 and a control unbalanced input 54. The amplitude correction signal is applied to the symmetrical control input 52; The amplitude correction is achieved by changing the magnitude of the signal coefficients symmetrically around the center of the filter. The phase correction signal is applied to the unbalanced control input 54; The phase correction is achieved by changing the magnitude of the signal coefficients asymmetrically around the center of the filter.

To reduce the sensitivity of the circuitry to disturbances that may affect the received test signal, it is possible to adjust the averaging circuits (not shown) around the correction memories 28A. 28P. These averaging circuits may perform averaging of successive test signals before measuring the distortion, or may averaging successively derived corrections for a given average video signal level.

Obviously, a new television signal receiver is provided which includes means for improving the quality of the received television signal and which comprises a wide variety of power circuits. According to the invention, means for improving the quality are provided which do not require a substantial increase in the number of receiver circuits.

It should be noted that where the receiving device comprises a high-speed computer, the method of the invention may be incorporated into the Software. In this case, the schematic diagrams of FIG. 1 and 3 to be considered as flow charts representing degrees of Software performing decoding and correction.

The decoding and correction circuits according to the invention may also include means for correcting static losses in the receiver to compensate for the effects of multiple transmission, the response of the receiver and / or the transmitter, and the low frequency tuning effects.

Claims (25)

A method for reducing the effect of differential distortion of demodulated composite television signals, comprising the steps of transmitting a test signal at predetermined intervals, wherein the test signal comprises a component at least one level of an average video signal, receiving the test signal at the receiver; adapted to perform the steps of measuring video signal distortion at said at least one average video signal level, deriving a desired correction at this signal level, and applying said derivative requested correction to subsequent received video signals at said signal level. The method of claim 1, wherein the test signal comprises components at least three levels of an average video signal, and wherein the desired correction is differentiated for each level. The method of claim 2, wherein the test signal distortion measured values are interpolated or extrapolated to derive the desired correction by a signal level other than the average video signal level of the measured components of the test signal. The method of claim 1, wherein the desired derivative and applied correction comprises correcting phase and amplitude distortion in the demodulated television signal. The method of claim 1, wherein the desired correction is derivative and applied at several different frequencies. The method of claim 1, wherein the successive test signals are stored and averaged with the previous test signal, and the desired correction is derived from the measured bias of the averaged test signal. The method of claim 1, wherein the successive derivative corrections for a given average video signal level are averaged, and the correction subsequently applied to the transmitted video signals is an average correction for that average video signal level. The method of claim 1, wherein each desired correction is applied to the video signal in its composite form. The method of claim 2, wherein the average image signal levels to which the desired corrections are applied are so closely spaced that they do not add any visible additional distortions to the signal. The test signal for use in the method of claim 1, characterized in that it consists of one line of a composite television signal having an identification portion for identifying it as a test signal and having high frequency components at at least three levels of the average video signal. Test signal according to claim 10, characterized in that it comprises a chrominance separation upstream of its high-frequency component. 12. The test signal of claim 11, wherein the chrominance separation lasts at least 20 microseconds. * 13. A composite television signal comprising, at predetermined intervals, a test signal according to claim 10. 14. A receiver adapted to receive and demodulate a composite television signal, comprising a detector for detecting a test signal transmitted at predetermined intervals, a measuring device adapted to determine the level of differential amplitude and / or phase distortion of the received test signal in at least one an average video signal level, and to derive the correction necessary to reduce distortion at that signal level or levels, the memory connected to receive the derivative desired correction or corrections, and the signal processing apparatus adapted to apply the desired correction or corrections to the subsequent received television signals at the level or levels the average video signal for which the correction has been or has been derived. 15. The apparatus of claim 14, wherein the signal processing apparatus comprises an interpolator arranged to derive a desired correction level of an average video signal other than at least one level of the average video signal at which the distortion is determined by the measuring device, and the corrections are applied to the following received television signals by the signal processing apparatus. 16. The apparatus of claim 14, wherein the measuring device is adapted to determine the level of distortion of the received test signal at at least three levels of the average video signal, and to determine the desired correction for each level of the signal. 17. The apparatus of claim 14, comprising an analogue to digital converter for passing a received test signal in which a measuring device and a memory are incorporated in the digital circuits. Device according to claim 17, characterized in that the measuring device consists of a programmable burning device. 19. The apparatus of claim 14, wherein the memory is comprised of a memory device for storing the derivative desired correction or corrections in address memory locations determined by the average brightness level of the received test signal. 20. The apparatus of claim 19, comprising at least one filter for passing an analog test signal to derive its brightness level. 21. The apparatus of claim 14, further comprising a memory adapted to store a received test signal, to compare a subsequent received test signal with a stored test signal, and to derive an average test signal and 2 therethrough, wherein the measuring device is adapted. to determine the level of distortion of the average test signal. 22. The apparatus of claim 14, further comprising an additional memory for comparing the following derivative correction of said average video signal level with the stored average video signal level, wherein the signal processing apparatus is adapted to apply the average derivative correction to the next received signal. television signals. 23. A receiver adapted to receive and demodulate a composite television signal, comprising a high-speed array of computer circuits programmed to influence the correction effect of the differential distortion of the demodulated signal by the method of claim 1. 24. A composite television transmitter, comprising composite television means for modulating and transmitting a composite television signal according to claim 13. 25. A composite television broadcasting system comprising a transmitter according to claim 24 and at least one receiver according to claim 14.