NL8100788A - Noise suppression circuit for video signal - separates signal into high and low frequency components and has delay circuit with time delay when switched over - Google Patents

Abstract

In the circuit a video signal is separated into its high and low frequency components by a separating circuit (3). The signal at an output (15) of a delay circuit (17) is combined with the separated low frequency signal in a combining circuit (11) whose output is applied to the input (19) of the delay circuit. The time delay of this circuit is switched from field to field by means of a change-over switch (53) so that this time delay changes from field-to-field to a field period minus and a field period plus half a line period. The noise-suppressed low frequency output from the combining circuit (11) is added to the separated high frequency component in an adder circuit (25). In use such a noise suppression circuit produces no travelling noise patterns on a television display.

Description

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EHN 9958 1 N.V. Philips' Gloeilaitpenfahrieken in Eindhoven.

Sais suppression circuit for a video signal.

The invention relates to a noise suppression circuit for a video signal comprising a delay circuit with a delay of substantially a frame time and a coinciner circuit in which an output signal of the delay circuit with a input signal is combined.

A noise suppression circuit of the above-mentioned type is known from United States Patent Specification 4058836. Compared to a noise suppression circuit with a delay circuit having a delay of an image time, a considerable saving on circuit elements is obtained with only a little less noise suppression. However, such a noise suppression circuit has been found to cause displacing noise patterns in the image.

The object of the invention is to avoid these moving noise patterns.

A noise suppression circuit of the type according to the invention mentioned in the preamble is therefore characterized in that the delay time of the delay circuit can be switched between a frame time minus half a line time and a frame time plus 20 a during a subsequent frame scanning time. half line time.

By applying a delay circuit with a delay time alternating in the manner indicated, practically no moving noise patterns appear to occur in the image, while the noise reduction is almost equal to that obtained with a noise reduction circuit with a delay circuit with a delay of one second. picture time.

The invention will now be elucidated with reference to the drawing a few exemplary embodiments.

The drawing illustrates: FIG. 1 shows a block diagram of a noise suppression circuit according to the invention for a monochrome video signal or a color difference signal.

Fig. 2 soot a block diagram a noise canceling circuit 8 1 0 0 78 8

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PHN 9958 2 according to the invention for a composite N.T.S.C. video signal,

Fig. 3 with a block diagram a noise suppression circuit according to the invention for a composite P.A.L. video signal, and

Fig. 4 with a block diagram a modification of the noise X-5 pressure circuit of FIG. 1 for a signal that a frame time must be delayed for further processing.

In FIG. 1, a video signal is applied to an input 1 of a separating circuit 3. The separation circuit 3 separates this signal into a low-frequency component, for example up to about 1 MHz for a monochrome or up to about 500 kHz for a color difference signal, which becomes available at an output 5 and a high-frequency component which is available at an output 7.

The low-frequency component is fed from the output 5 of the isolating circuit 3 to an input 9 of a combining circuit 11 which has a further input 13 which is connected to an output 15 of a delay circuit 17. An input 19 of the delay circuit 17 is connected to an output 21 of the combining circuit which is further connected to an input 23 of a counting circuit 25.

The delay circuit 17 forms with the combination circuit 20 11 a noise suppression circuit which in this case acts only on the low-frequency component of the video signal. For example, this is usually sufficient for use in television receivers because the low-frequency noise is the most disturbing there.

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In the combining circuit 11, the delayed and the delayed low-frequency component of the inputs 9 and 13, respectively, are applied to an input 27 and 29 respectively of a subtracting circuit 31, of which an output 33 is connected to an input 35 of a circuit with a variable transfer factor 37. lies. The variable transfer factor circuit may be a non-linear circuit which transmits 30 small amplitude signals with greater attenuation than large amplitude signals, or it may be a circuit whose attenuation is controlled using a control signal, for example, by a motion detector the video signal or one of its components is obtained.

35 An output 39 of the variable transfer factor circuit is connected to an input 41 of the adder circuit 43, a further input 45 of which is connected to the input 13 and an output 47 to the output 21 of the combination circuit 11. The operation of the combining circuit 81 0 0 78 8 V EHN 9958 3 is known, for example, from US patent 4058836, so that this will not be further discussed.

In the delay circuit 17, the signal applied to the Input 19 is converted by an analog-digital converter 49 into a digital signal, on the one hand directly and, on the other hand, via a delay line 51 with a delay of a line time (L) which is supplied is controlled by a signal of the half-frame frequency ff) and which is in the drawn position during one frame scanning time and in the unsigned position during the next. Via 10 cm switch 53 the signal is fed through a delay line 55 with a delay of a frame time minus half a line time (R-L) and further via a digital-analog converter 57 to the output 15. As a result, the delay circuit alternates during the one raster a delay of a raster time minus half a line time (R-% L). and the next frame is a delay of a frame time plus a half line time (R + kL) which means the occurrence of moving interference patterns in a front image to be displayed with the video signal, while the noise reduction is still less than, for example, with a delay circuit with a delay time two grids would be obtained from two grating times so that a considerable saving on circuit elements can be achieved.

The low-frequency component of the video signal in which the noise is suppressed appears at the input 23 of the adder circuit 25. The high-frequency component from the output 7 of the separating circuit 3 is supplied to a further input 59 of the adder circuit 25, so that a complete video signal in which the low-frequency noise is suppressed is again produced at an output 61 thereof.

With the indicated embodiment, in which the noise is suppressed only in the low-frequency component, a further saving of circuit elements is obtained because the analog-to-digital converter 49 now allows sampling at a rather low frequency and the delay lines 51 and 55 much less. need to contain memory elements than when the total video signal should be passed through it.

It will be clear that, if desired, a noise reduction can still be applied to the entire video signal.

It will further be clear that instead of a recursive noise suppression circuit as described here, an 8 1 0 0 78 8 EHN 9958 4 transverse may be used if desired.

In FIG. 2, the same reference numerals as in FIG. 1 are used for corresponding parts as they are referenced for description. Any conversions from analog to digital and 5 vice versa are not indicated.

The input 1 of the circuit is now directly connected to the input 9 of the cambling circuit. A composite N.T.S.C. video signal containing a brightness signal Y and a chrominance signal CHR ^ ^.

The delay circuit 17 is adapted to the processing of this signal and contains a delay line 63 connected to the input 19 with a delay of a frame time minus half a line time (R% L). An output 65 of the delay line 63 is connected, on the one hand, directly to an amp switch 67 and, on the other hand, via a delay circuit 69 in which the phase of the chrominance signal is adjusted. The output 65 of the delay line 63 is connected there to an input 71 of a separating circuit 73 which supplies the low-frequency component to an output 75 and the high-frequency component of the signal to its input 71 to an output 77.

The low-frequency component is applied alternately via a changeover switch 78 of the output 75 via a delay line 79 with a delay of a line time L and directly to an input 81 of a summing circuit 83.

The high-frequency component, which also contains the chrominance signal 25, is fed from the output 77 of the separating circuit 73 to an interpolation circuit which has a direct signal path to an input 85 of the adder circuit 87 and a signal path with a delay line 89 with a delay of two line times (2L). to a further input 91 of the adder circuit 87. This interpolation circuit keeps the phase of the chrominance signal equal to that at the input 19 of the delay line 63, but by interpolation makes a signal which further corresponds practically to the low-frequency in terms of the delay signal.

The adder circuit 87 has an output 93 which is connected via a switch 94 to an input 95 of the summing circuit 83 which halves the amplitude of the signal at the input 95 and adds this signal in half amplitude to the signal at the input 81 of it. The amswitch 67 is in the drawn position during the first three grating times 8100788 PHN 9958 5 r and the fourth grating time in the not shown.

The switch 78 is each time during the first and the third frame time in the not drawn and during the second and fourth frame time in the drawn position. The switch 94 is each time during the first and second grating times in the not shown and during the third and fourth grating time in the drawn position. This switching cycle is repeated every time after [_ raster times. As a result, the chrominance signal always has the correct phase.

The noise reduction in this circuit is thus effective on the total video signal. From the output 21 of the combining circuit 11, the signal in which the noise is suppressed is applied to the output 61 of the circuit.

The circuit 69 for adjusting the phase of the chrominance signal can also be designed differently, for example by replacing the 15 cm switch 67 with an adder which adds the output signals of two switch switches, one of which switches between the input and the output. of the delay line 79 and the other cm switch between the input and the output of the delay line 89 and wherein, for example, the latter cm switch 20 switches at half the grid frequency and thus takes a different position from frame to frame while the other cm switch each time during a frame of four successive grids in one and the other three grids are in the other position, and during this one frame of the four heath switches the terminals of the delay lines 79, 89 are connected to the adder.

In Fig. 3, the same reference numerals as in the previous figures have been used for corresponding parts.

A video signal with a brightness signal Y and a PAL chrominance signal CHRp ^ is now applied to input 1.

In the delay circuit 17, the input 71 of the separating circuit 73 is supplied with the signal from the input 19 via a delay line 99 with a delay of a frame time minus two and a half line times (11-2¾ of which an output 101, on the one hand, is connected directly to a half-raster frequency cm switch 103 and on the other hand via a delay line 105 with a delay of a line time (L). cm switch 103 is located at the input 71 of the isolating circuit 73.

At the output 75 of the isolating circuit 73, the low-frequency component of the video signal is generated, and at the output 77 the high-frequency with an alternating delay of a frame time minus two and a half line time and a frame time minus one and a half line time . The output 75 is applied via a delay line 105 with a delay of two line times (2L) to an input 107 of the summing circuit 109, an output of which is located at the output 15 of the delay circuit 17. Thus, the low-frequency component is delayed alternately by a frame time minus half a line time and a frame time plus half a line time.

The high-frequency component is split from the output 77 via two comb flashes with two delay lines 113, 115 each with a delay of two line times and two sorer circuits 117, 119 into a chrominance signal CHR which is connected to an output 121 of the summing circuit 117 and a high-frequency heroherden signal. That 15 arises at an output 123 of the throttling circuit 119. Both these signals correspond to a corresponding signal which is delayed two line times relative to the signal at the output 77 of the isolating circuit 73. The phase of the chrominance signal at the output 121 of the summing circuit 117 is now further mirrored by a modifier 125. The mirrored chrominance signal * CHR is applied via a band filter 127 to an input 129 of the summing circuit 109 and the high-frequency brightness signal to an input 131 thereof. At the output 111 of the summing circuit 109 a signal now arises which corresponds to a signal which is alternately a frame time minus plus a half a line time delayed with respect to the signal applied to the input 19 of the delay circuit 17 and in which the phase of the chrominance signal has been corrected so that it can be combined in the combining circuit 11 with the real-time signal at input 1.

In this case, the delay circuit 17 can, if desired, be replaced by a delay line of a frame time minus two and a half line times (R ^ L) followed by a parallel connection of a high-frequency and a low-frequency signal path with a switchable delay with a high-frequency signal path. repeating cycle of consecutively in consecutive grids four, four, zero four and zero line times (4L, 4L, 0, 4L, 0 ,.) and in the low-frequency signal path an interruptible delay a repeating cycle of successively in consecutive grids two and three line times (2L, 3L, ...).

8100788 PHN 9958 7 * m

In FIG. 4, corresponding parts have the same reference numerals as in FIG. 1. Some parts are arranged differently than in Fig. 1, making the circuit suitable for further signal processing for which a delay of, for example, a frame time minus half a line time is required, such as, for example, for a comb filter circuit for a PAL signal to separate the chrominance and luminance signal components thereof.

The separating circuit 3 is now included after the output 33 of the subtracting circuit 31. The input 1 of the circuit is located at the input 9 of the combining circuit 11.

The low-frequency output 5 of the separating circuit 3 is now at the input 35 of the circuit with the variable transfer factor 37.

Furthermore, the adder circuit 25 is included in front of the output 15 21 of the combine circuit 11. Its input 23 is now only at the output 27 of the adder circuit 33 and its output 61 at the output 21 of the combine circuit 11.

The input and the output of the delay line with a delay of a frame time minus half a line time 55 are connected to an output 135 and 137 of the circuit, for example, which can be connected to inputs of a comb filter circuit for separating the chrominance and luminance signal components. PAL signal when a PAL signal is applied to input 1.

The delay circuit 17 must then be suitable to pass through the entire frequency range of the PAL signal.

The high-frequency part of the signal at the input 1 is passed via the subtracting circuit 31, the output 7 of the separating circuit 11 and the adder circuit 25 to the input 19 of the delay circuit 17. This high-frequency part is again transmitted via the delay circuit 17 at the input 13 of the combining circuit, but because it is then fed in opposite directions via the subtracting circuit 31, the adding circuit 43 and the adding circuit 25 to the output 21 of the combining circuit 11, it has become zero there. There is therefore no delayed high-frequency part at that output 21.

35 The low-frequency part of the signal at input 1 is applied via the subtractor circuit 31, the circuit with variable transfer factor 37r to the adder circuit 43 and the adder circuit 25 to the input 19 of the delay circuit 17 and appears delayed 81 0 0 78 8 • PHN 9958 8 V v at the input 13 of the combining circuit 11. Hence, it is fed directly and via the subtracting circuit 33 and the circuit with the variable transfer factor 37 to the adder circuit 43 so that it is amplified depending on the transfer factor of the circuit 37. 5 tude returns to input 19 of delay circuit 17. As a result, noise reduction occurs in the low-frequency part.

Thus, at the outputs 135 and 137 of the delay circuit 17, a frame time minus half a line time (R-L) with respect to delayed PAL signals occurs in which the noise is suppressed in the low-frequency part 10. Interfering components in the chrominance and luminance signals can be suppressed by means of a comb filter of which the said delay forms part.

It is assumed that the further processing on the digital signals at the outputs 135, 137 takes place. Obviously, this can be done on analog signals if desired by connecting the output 135 to the input of the analog-to-digital converter 49 and the output 137 via a digital-to-analog converter to the output of the delay line 155.

It will further be apparent that the circuit of FIG. 4 20 can also be used for other signals which still have to undergo an operation which requires a delay of approximately one frame time minus half a line time.

25 30 35 8100788

Claims (3)

2. A noise suppression circuit according to claim 1, characterized in that the circuit comprises a separating circuit for separating a high-frequency and a low-frequency component of the video signal from each other. 3. Rejection suppression circuit according to claim 2, for a PAL signal, characterized in that the separation circuit is included after a delay line circuit with a raster-to-raster switchable delay time of a frame time minus two and a half line time and a frame time minus one and a half: line time . Noise-canceling circuit according to claim 2, characterized in that the separating circuit is included after a subtracting switch 20 whose inputs are coupled, an input of the noise-canceling circuit and an output of the delay circuit, respectively, while a high-frequency output of the separating circuit is coupled to an input of an adder circuit whose further input is coupled via a further adder circuit and a variable transmission factor circuit to a low-frequency output of the isolation circuit while a further input of the further adder circuit is coupled to the output of the delay circuit. 30 35 6100788