FR2538658A1 - Method and device for coding a video signal for narrow pass-band transmission. - Google Patents

Abstract

The invention relates to methods making it possible to improve the images recorded on a video recorder. It consists in eliminating 103 every second line. Each remaining line is memorised 104, 105 at normal speed and played back at half speed, this reconstituting a continuous signal whose pass-band is a quarter of the original. After recording and play-back, the image is reconstituted by proceeding in reverse and by repeating 303, 308, 315 the transmitted lines in order to restore the missing lines. It makes it possible to obtain an image whose definition is substantially isotropic.

Description

METHOD AND DEVICE FOR CODING A VIDEO SIGNAL
FOR REDUCED BANDWIDTH TRANSMISSION
The present invention relates to a method, and to a device for implementing this method, of coding a video signal for reduced band transmission, with a view to keeping the best possible image despite the limitation of the bandwidth of the signal.

 The transmission, direct or via a recording which is then replayed, of a signal most often results in a limitation of its bandwidth and the addition of unwanted signals due to the filtering and noise of the devices used to the transmission. The effects on the restored signal can be more or less sensitive.

 In the case of a television video signal, it is known that whatever the standard, it represents a succession of images over time. Each image is made up of a succession of horizontal lines over time. Each line is itself represented by a succession over time of electrical signals which represent the points (known as pixels) constituting the line. The bandwidth of the video signal is roughly equal to the product of the number of frames per second by the number of lines in an image and the number of pixels in a line. It is customary to give the definition of the image an isotropic character, that is to say that on the screen the distance between two adjacent lines is the same as the distance between two adjacent pixels.

 This requirement results in particular in a minimum value of the bandwidth of the video signal, and the necessary bandwidth is generally respected in the classified transmission means.

 Newer means of transmission do not, however, make it possible to have the necessary bandwidth. This is particularly the case for consumer video recorders. There is then an anisotropic degradation of the image, which results in a horizontal blurring while in the vertical direction the resolution remains intact. In fact, the reduction in bandwidth is due to a limitation in high frequency (low-pass filtering) which primarily affects the speed of succession of pixels along the line, without affecting the succession of lines along the image. nor a fortiori the succession of images over time.

 Thus if we reduce in a ratio 2 the bandwidth of a video signal representing an image whose definition is isotropic, we reduce by two the number of pixels per line while obviously the number of lines, and therefore the vertical resolution, remains constant. However, the same bandwidth would make it possible to have an image having a reduced resolution only in a ratio W2 along each of the two axes if this image was analyzed according to a standard respecting the isotropy. The loss of definition is even greater in mainstream VCRs where the loss of bandwidth is very large.

 The object of the invention is to rebalance the isotropy of the image by distributing the effects of the loss of bandwidth both in the vertical direction and in the horizontal direction.

 For this, in the method according to the invention, a line is transmitted every n lines for the duration of n lines by eliminating the nl intermediate lines, n being defined to obtain a substantially isotropic image as a function of the passband of the transmission channel. , and the image is reproduced on reception by repeating the transmitted line during n consecutive lines.

 Other features and advantages of the invention will appear clearly in the description below presented by way of nonlimiting example and made with reference to the appended figures which represent: - Figure 1, the diagram of an analog coding system and decoding according to the invention; - Figure 5 the coding and decoding timing diagram of the method according to the invention; - Figure 3, the diagram of a variant of the system of Figure 1; - Figure 4, the diagram of a digital coding and decoding system according to the invention.

 The image of a commonly used television standard is 4/3 format and is analyzed on 625 lines at 25 frames per second.

Taking into account the losses, this corresponds to 576 useful lines of 766 useful pixels. The 766 pixels are analyzed in 52 microseconds, which corresponds to a bandwidth of 7.36 MHz.

 When the video signal representing such an image is recorded directly on a video recorder. general public, the horizontal definition drops to 200 pixels, a loss of a ratio 3.83 almost equal to 4, while the vertical definition remains constant.

 Unfortunately the viewer is essentially sensitive to the most degraded aspect, and the subjective aspect of the image - would not be significantly worse if the image had four times less lines, but then the bandwidth of the VCR would be overabundant.

 According to the invention, the degradation of the image is distributed in the vertical direction and the horizontal direction by deleting every other line when recording and by spreading the recording of the remaining line over the duration of the two lines. On reading each line is recompressed over its normal duration and repeated once to obtain a complete image.

 In the diagram of FIG. 1, a normal video signal VE is applied to an encoder which delivers this coded signal to a video recorder 200 whose bandwidth is substantially a quarter of that of VE. After recording then reading, the video recorder delivers the coded signal to a decoder which reproduces a video signal with reduced bandwidth VS.

The signal VE is applied to a separator 101 which makes it possible to separate the chrominance signal, the bandwidth of which is sufficiently small to allow direct recording. The transmission of - all this signal is necessary in the SECAM type standards to avoid loss of color. The luminance signal at the output of the separator 101 is applied to a low-pass filter 102 which cuts the frequencies above
FF being the higher frequency of the video signal VE. This filtering and those
2 ', which will be described below, make it possible to eliminate signals of too high frequency, which are unnecessary and which risk giving rise to annoying intermodulation products.

The signal at the output of filter 102 is applied to a switch 103 which alternately directs it to two analog registers with CCD 104 and 105. This switch switches to the frequency FL / 2, FL being the line frequency, so that it feeds one of the registers with a
complete line, then the other register with the next second line, the
intermediate line being lost. This sequence is represented on the timing diagram of FIG. 2 where we see in the first line the signal VE composed of a succession of lines lj to 19, in the second line the input signal of register 104 composed of lines 11, 15 , and lg, and in the fourth line the input signal from register 105 composed of lines 13 and 17.

 To control the filling of the registers, these are supplied alternately by a clock H l at the frequency B, which is applied to them by two switches 106 and 107 which switch alternately at the frequency FL / 2 so as to respect the desired sequence. The frequency B is defined by the number of cells in the registers and the duration of a line. The number of cells is itself defined by the number of pixels necessary to have the desired definition as a function of the bandwidth, for example 400 in the example described.

 When a register is filled, the switch which delivers the clock toggles to apply a clock H2 of frequency B / 2 to it. Thus the register is emptied for the duration of the two lines which follow that which filled it, by delivering a signal whose useful bandwidth is F / 4.

During the second half of this time the other register is filled, so that it can be emptied when the first is empty. The timing diagram of FIG. 2 represents this sequence in line three where we see lines 11 and 15 spread over the duration respectively of lines 12, 13 and 16, 17, as well as in line five where we see the lines 13 and I spread over time
7 respectively of lines 14, 15 and 18, read
The outputs of the two registers are applied to a switch 108 which switches at the frequency FL / 2 to collect the series of output signals from the registers, which are represented on line 6 in FIG. 2 where we see the uninterrupted succession of lines ll, 13, lg 17 spread over the duration of lines ll to 19.

 The output of switch 108 is connected to a filter 109 which cuts frequencies above F / 4.

 The filter 109 feeds a mixer 110 which receives the chrominance signal coming from the separator 101 and delivers at the output of the coder a signal suitable for being recorded on the video recorder 200.

 In reading the video recorder 200 delivers a signal substantially identical to the output signal of the encoder and represented on line 6 of FIG. 2. This signal is applied at the input of the decoder to a separator 301 which separates the chrominance signal and delivers the signal of luminance to a filter 302 which cuts frequencies higher than F / 4.

 The signal at the output of filter 302 is applied to two switches 303 and 315 which supply alternately two CCD registers 304 and 305 identical to registers 104 and 105. These switches switch at the frequency FL / 2 to successively supply one of the registers with one line (spread) of the VCR playback signal and then the other register with the next line. This sequence is represented in lines 7 and 9 of FIG. 2 where we see the input signals of registers 304 and 305 respectively, firstly comprising lines 11, 15 and 13, 17 spread out.

 To control this filling, the registers alternately receive a clock H3, identical to HZ via switches 306 and 307 which switch at the frequency FL / 2.

 When these switches toggle they supply the registers by a clock H4 identical to H1 which allows them to be emptied successively at frequency B. There are thus available at the output of the registers of the lines of the image, compressed to have a normal duration again.

 In order not to have a blank between two successive lines, corresponding to the lines deleted at registration, the outputs of the registers are looped over their inputs by means of switches 303 and 315. Thus they are filled with the output signal which is recycled, which makes it possible to reread a second time the contents of a register and to have at the exit of this one same line repeated twice. We see in Figure 2 in lines 8 and 10 lines 11, 15 and 13, 17 repeated twice, at the output of the registers, and in lines 7 and 9 these same lines recycled at the input of the registers at a speed double that corresponding to the filter scrtie 310.

 The outputs of the two registers are applied to a switch 308 which switches at the frequency FL / 2 to collect the series of output signals from the registers, which are represented on line 11 in FIG. 2 where we see the uninterrupted succession of lines li, 15, 17 repeated each and having a normal duration.

 The output of switch 308 is connected to a filter 309 which cuts frequencies above Flue. Indeed, by having recompressed the lines so that they have a normal duration, the bandwidth of the video signal has been doubled, which therefore represents the desired 400 pixels.

 This filter 309 feeds a mixer 310 which receives the luminance signal from the separator 301 and delivers the output signal VS from the decoder, which has the desired characteristics, that is to say a substantially isotropic definition and divided by 2 with respect to to the original VE signal.

 An improvement of the process consists, instead of repeating each odd line to replace the next even line which is missing, to synthesize this even line by making the geometric mean of the two lines which surround it. For this, a CCD register 311 is inserted (FIG. 3) between the switch 308 and the filter 309. This register is identical to the others and is permanently supplied by the clock H4. It is doubled in parallel by a direct line coming from the switch 308. Between this direct line and the output of the register 311 two resistors 312 and 313 of the same value in series make it possible to obtain at their junction the desired average between the direct signal and that delayed by one line. A switch 314 connected on the direct line on the one hand, and on the junction of the resistors on the other hand, switches to frequency FL / 2 and makes it possible to successively obtain the odd line direct and the synthesized pair line. The output of this switch is connected to the input of filter 309.

 Another improvement consists, by means of a switching system which is easy to implement, of inverting from one frame to the next the rank of the lines deleted, ie first of all the even lines, then odd lines, and so on. This improves the spatial analysis of the image, at least for the parts that move slowly.

 The use of a frame memory would also make it possible to have even and odd lines in real time and to obtain an almost total recovery of the original definition.

 These improvements are particularly interesting in the case of standards with interlaced analysis, which are of general use, because it is then possible to regularly have pairs of contiguous lines of the original image and the loss of vertical definition is then almost zero.

 In the case of semi-professional video recorders, of the type for example "U-Matic" (Registered trademark) for which the reduction in bandwidth is only half that of the original image, we can thus find practically the original definition of the image.

 It is necessary to have two registers in the coder and in the decoder because these analog devices operate at the rate of the clock which they receive and cannot simultaneously empty themselves more slowly than they fill up. This limitation is avoided in the case of the digital device used in the system represented in FIG. 4 without the color for the simplicity of the drawing.

 The signal VE is filtered at F / 2 in a low-pass filter 102, it is then sampled and digitized at 400 samples per line in circuits 402 and 404. A switch 103 which switches at the frequency FL / 2 makes it possible to eliminate every other line. This switch directs the remaining lines to a memory 405 of the FIFO type which can be written at the normal arrival speed of the samples, and read at half speed. The necessary speed conversion is thus carried out and the remaining lines are naturally aligned, without a hole between them, at the output of the memory.

The memory output signal is then converted to analog in a circuit 406 and then filtered low-pass to F / 4 in a filter 109.

 This signal thus coded is recorded and then read in a video recorder 200.

 The decoder includes a low-pass filter at F / 4 302 followed by a sampler 40i with 400 samples per extended line and a digitizer 408. The digitized signal is written to a memory of the FIFO 409 type which is read at double speed . This reading is repeated twice to obtain the two successive lines. There is therefore no need for any particular switching here. The memory output signal is converted to analog in a circuit 410, then filtered to F / 2 in a filter 309, which delivers the output signal VS.

 Of course all the disturbances described in the analog system apply to the digital system.

 It may be noted that in the case of use with a video toscope, a large part of the elements, in particular the registers and the memories, can be used for coding and decoding since the recording and the reading are not simultaneous.

Claims (10)

 1. Method for coding a video signal (VE) for transmitting it by a broadcasting channel (200) having a bandwidth reduced by a factor k compared to the bandwidth of the original video signal, characterized in that 'It comprises the following steps: - n being an integer, at least equal to 5 closest to deletion (103) in the video signal of the parts representing nl lines every n lines; - spreading (104-108) in time of the signal representing each remaining line over the duration corresponding to itself and to the deleted lines which separate it from the next remaining line; - filtering (109) of the signal resulting from this spreading to limit it to the reduced bandwidth of the transmission channel; - after transmission (200), compression (303-308, 315) in time of the signal representing a spread line, over the duration of an original line; - synthesis (303-308, 315) of the lines missing after a transmitted line, from at least this transmitted line, which reform a video signal (VS) with reduced bandwidth representing an image conforming to the initial standard and having a substantially isotropic definition.  2. Method according to claim 1, characterized in that the synthesis (303-308, 315) of the missing lines between a first and a second transmitted line is done by repetition of the first transmitted line.  3. Method according to claim 1, characterized in that the synthesis (303-308, 315) of the missing lines between a first and a second transmitted line is done by linear combination (311-314) of these two lines.  4. Method according to any one of claims 1 to 3, characterized in that from one frame to the next, the rank of the lines transmitted is dragged by one step to transmit all the lines over the duration of n frames.  5. Method according to claim 4 characterized in that one stores in addition the n-l frames transmitted previously to simultaneously dispose of all the original lines composing an image.  6. Method according to any one of claims 1 to 5, characterized in that the chrominance signal is extracted (101) before coding, that it is reintroduced (110) in the coded signal before transmission, that it is extracted (301) after transmission, and that it is reintroduced (310) in the decoded signal.  7. Method according to any one of claims 1 to 6, characterized in that n = 2.  8. Device for implementing the method according to claim 7, characterized in that it comprises: - a first separator (101) for removing the chrominance of the original video signal (VE); - a first low-pass filter (102) connected to the luminance output of the first separator (101); - a first switch (103) connected to the low-pass filter; - two first registers with CCD (104, 105) to receive from the first switch respectively one out of two of the lines to be transmitted - a second and a third (106, 107) switches to supply the first registers respectively by a first clock (H1) of filling and a second emptying clock (H2) having a frequency half of the first clock; - a fourth switch (108) for collecting the outputs of the first two registers; - a second low-pass filter (109) connected to the third switch to limit the bandwidth of the signal to that of the transmission channel; - a first mixer (110) connected to the second filter and to the chrominance output of the first separator to deliver the signal to be transmitted to the transmission channel; - a second separator (301) connected to the output of the transmission channel to remove the chrominance of the transmitted signal; - a third low-pass filter (302) connected to the luminance output of the second separator; - two second CCD registers (304, 305) to receive one in two respectively of the lines transmitted ;; - a fifth and a sixth switches (303, 315) for alternately applying to the input of each second register the output of the third filter or a recycling output of the register itself - a seventh and an eighth switches (306, 307 ) to supply the second registers respectively with a third clock (H3) for filling and a fourth clock (H4) for emptying and recycling having a frequency half of the third clock; - a ninth switch (308) for collecting the outputs of the two second registers; - a fourth low-pass filter (309) connected to the ninth switch - a second mixer (310) connected to the fourth filter and to the chrominance output of the second separator to deliver the decoded signal (VS) representing a substantially isotropic image.  9. Device according to claim 8, characterized in that it further comprises: - a third CCD register (311) connected to the output of the ninth switch (308) for delaying the transmitted signal by one line; - two resistors (312, 313) of equal values connected in series between the output of the ninth switch and the output of the third register to deliver on their junction the synthesis signal representing the missing line; - A tenth switch (314) connected to the output of the ninth switch and to the junction of the two resistors to successively select the transmitted line and the synthesized line and deliver these to the fourth filter (309).  10. Device for implementing the method according to claim 7, characterized in that it comprises: - a first low-pass filter (102) for filtering the original video signal (VE); - first means (402, 404) for digitizing the signal filtered by the first filter; - a switch (103) connected to the digitizing means, to delete every other line; - a first memory (405) of FIFO type for receiving from the switch each of the lines to be transmitted and restoring them in a time twice as long ;, - a first digital-analog converter (406) connected at the output of the memory; ; - a second low-pass filter (109) connected to the analog digital converter to limit the bandwidth of the signal to that transmission channel; - a third low-pass filter (309) connected to the output of the transmission channel (200); - second means (407-408) for digitizing the signal filtered by the third filter; - a second memory (409) of FIFO type for restoring twice successively at normal speed the lines received from the second digitization means; - a second digital-analog converter (410) connected at the output of the memory; - a fourth low-pass filter (309) connected to the second digital-analog converter for delivering the decoded signal (VS) representing a substantially isotropic image.