FR2593989A1 - Method of transmitting television colour difference signals, transmitter and receiver of colour television signals comprising a device for implementing this method, and colour television signal transmission system including a transmitter and/or a receiver of this type - Google Patents

Abstract

Colour television signal receiver comprising a decoding device receiving from the transmission channel, in sequential form and line by line, components of type U or of type V alternately and which consists of the following elements for processing these components: a. A demultiplexing circuit 400 routing towards one or the other of two processing paths the components of type U and of type V arriving sequentially; b. In the path for processing the components of type U: 1. A first selection circuit 520, 2. An interpolation circuit 530, 3. A second selection circuit 540; c. In the path for processing the components of type V, similar circuits 610 to 640; The said second selection circuits 540 and 640 being intended to allow the reception of components of type U and V either from a frame said to be reconstructed from the transmitted frames, or from a frame said to be interpolated from the reconstructed frame.

Description

METHOD FOR TRANSMITTING COLOR DIFFERENCE SIGNALS
IN TELEVISION, TELEVISION SIGNAL TRANSMITTER AND RECEIVER
IN COLORS INCLUDING A DEVICE FOR IMPLEMENTING THIS
METHOD AND SYSTEM FOR TRANSMITTING TELEVISION SIGNALS
IN COLORS INCLUDING A TRANSMITTER AND / OR A RECEIVER OF THIS TYPE
The present invention relates to a method for transmitting color difference signals in television comprising the following operations:
(a) on transmission, from the color difference signals U and V associated with each line of a frame of the starting image with odd frames and interlaced pairs, formation of a frame to be transmitted, called an intermediate and made up of so-called intermediate lines, by association with said intermediate lines of a U-type component and of a V-type component alternately, said U-type component associated with the intermediate line considered being made up for each odd frame or pair of a combination of the components U associated with the corresponding line of the odd frame or corresponding starting pair and with one or more lines of the same starting frame neighboring this corresponding line, and said component of type V associated with the following intermediate line of the same intermediate frame similarly consisting of a combination of the components V associated with the next line of the starting frame and one or more lines of the same starting frame neighboring this next line
(b) sequential transmission, line by line, of the alternately odd and even intermediate frames;
(c) upon reception, reconstruction of a final image.

 The invention also relates to a transmitter and receiver for color television signals comprising a device for implementing this method, as well as to any system for transmitting color television signals including a transmitter and / or a receiver of this type. .

 In certain current standards for transmitting video signals, such as the SECAM standard, as well as in the future European standard on the subject, known as MAC, the color difference signals U and V, which will be referred to below as chrominance signals, are transmitted sequentially line by line.

 As FIG. 1a indeed shows, the starting image, in the transmitter, contains the two components U and V at each line of each frame. Here we have successively shown lines 1, 3, 5, 7, 9, etc ... of an odd frame and lines 2, 4, 6, 8, 10, etc ... of an even frame , the complete image being made up of the interlacing of two successive odd and even fields shifted vertically by one line. This starting image, represented on the left of FIG. 1, corresponds on the right of the same figure, the information actually transmitted, namely, for the starting odd frame, successively a component of type U and a component of type V, formed respectively not directly of the real components U and V but of a combination of a certain number (in general the same as for U) of components V of the same frame. Similarly, to the starting pair frame corresponds a succession of type V and type U components obtained in a similar way. The aim of such vertical pre-filtering is to make the degradation of the signals during transmission as low as possible.

 Likewise, on reception, components U and V are reconstructed for each line of each frame from combinations respectively of several of the information U transmitted and of several of the information V transmitted, as shown in FIG. 1b, the left part of which shows the information transmitted and the right part the final image reconstituted in two interlaced frames with again a U component and a V component for each line of each frame.

 However, this transmission method, as defined above in its transmission and reception phases, has the following drawback: as one transmits only one component of type U out of two and only one component of type V over two, and that the reconstruction of the final image is done within the same frame, the vertical resolution, in chrominance, of this image is limited by the number of lines for which each component is transmitted in a single frame that is, half the number of lines in a frame.

 The object of the invention is to propose a transmission method by which this drawback is avoided.

To this end, the invention relates to a process characterized in that
(d) on transmission, for the formation of a new intermediate frame from a starting frame of determined parity, said combination of components U also includes, for the considered intermediate line, the components U of one or more of several lines close to said intermediate line in one or more frames of any parity close to said starting frame, and said combination of components V also includes, for the same intermediate line, the components V of one or more lines close to this same intermediate line in one or more frames of any parity adjacent to said starting frame
(e) from the new intermediate frame thus formed, the intermediate frames to be transmitted consist successively of a part of an odd frame including on its lines of determined parity the U-type component of the lines of the same determined parity of said new intermediate frame and on its other lines of opposite parity the component V of the other lines of opposite parity of this same new intermediate frame and on the other hand of an even frame including on its lines of the same determined parity the component of type V of lines with the same parity of said new intermediate frame and on its other lines of opposite parity the U type component of other lines of opposite parity of this same new intermediate frame
(f) on reception, formation of the final image on the one hand from a frame of the same parity as said new intermediate frame and reconstituted from intermediate frames transmitted by an operation opposite to that executed to constitute said frames intermediaries transmitted, and secondly from a parity frame opposite to that of said new intermediate frame and reconstructed by interpolation from said frame of the same parity already reconstituted.

 With the method thus proposed, it is possible to reconstruct a final image having a vertical resolution twice as high as in the case of the previous embodiments cited using sequential line transmission of the color difference signals.

 Indeed, on transmission, the starting image contains information U and information V on each line.

This image formed of two interlaced frames, is first transformed into an intermediate non-interlaced image and therefore containing fewer lines, that is to say, in fact, an image consisting of a single frame. This intermediate frame is formed by vertical filtering, as in the previous embodiments, but also by weighting of several neighboring frames in which one or more of the neighboring lines of each line considered in said intermediate frame are considered.

 The non-interlaced image, or rather the intermediate frame thus obtained, contains fewer lines carrying color difference signals U and V than the starting image (two times less in the example described where the intermediate frame contains the same number of lines as the starting frames, without this being a limitation of the invention). It is therefore possible to transmit all these components U and V in the same time interval as in the case of the embodiments mentioned above, where one was forced to transmit only one U component out of two since the number of lines concerned was double.

 This transmission is then ensured by transmitting the signals U and V sequentially but by omitting one in two in the series of the signals U and one in two in that of the signals V. The other signals are transmitted in the same way during the next frame. Finally, on reception, the non-interlaced image, which had been obtained from the initial interlaced image, is reconstructed by a process exactly opposite to that which made it possible to pass from said non-interlaced image to the two transmitted frames, then, by interpolation, a final image is reconstructed, here in the same format as the starting image but which could of course have a different format.

For the implementation of this method, it is advantageous to have a transmitter comprising a coding device consisting of the following elements for the processing of the U components and for that of the V components
(a) 2n serial memories achieving successively delays on each component U of a frame minus half a line and a frame plus a half line, and 2n similar serial memories for the delay of each component V;
(b) a combination circuit receiving on its (2n + 1) inputs respectively the U component, or the V component, and the 2n output signals of the 2n corresponding memories;
(c) a switching circuit directing the output signal of said combination circuit alternately to a frame memory or to a selection circuit;
(d) the selection circuit ensuring the selection of the output of the switching circuit during one frame and that of the output of the frame memory during the next frame
(e) a multiplexing circuit intended to send to the transmission channel, at the output of the coding device, U or V type components alternately, in sequential form and line by line.

Likewise, the receiver includes a decoding device consisting of the following elements for processing these components
(a) a demultiplexing circuit intended to direct to a processing channel of the U-type components or to a processing channel of the V-type components the U-type and V-type components arriving sequentially, line by line, at the input of the decoding device;
(b) in the processing of U type components:
(1) a first selection circuit, the output of which is connected either directly to the output of the demultiplexing circuit or to this same output via a frame memory
(2) an interpolation circuit whose inputs are connected respectively to the output of the demultiplexing circuit and to that of the frame memory;
(3) a second selection circuit, the output of which is connected either to that of the first selection circuit or to that of the interpolation circuit to alternately deliver the U-type component from the lines of the frame reconstructed from the transmitted frames or the U-type component of the frame interpolated from said reconstructed frame
(c) in the V-type component processing channel, similar circuits for alternately delivering the V-type component of the lines of the frame reconstructed from the transmitted frames or the V-type component of the frame interpolated from said reconstructed frame, said first selection circuits being intended to simultaneously select either a U component of the first transmitted frame and a V type component of the second transmitted frame, or vice versa, for the next line of the reconstructed frame, a U type component of the second transmitted frame and a type V component of the first transmitted frame, and said second selection circuits being intended to allow reception of the U and V type components either of the frame reconstructed from the transmitted frames, or of the frame interpolated from the reconstructed frame.

The features and advantages of the invention will now appear more precisely in the description which follows and in the appended drawings, given by way of nonlimiting examples and in which
- Figures la and lb describe a method of transmitting color difference signals according to the prior art
- Figures 2a and 2b describe the method of transmitting color difference signals according to the invention;
- Figures 3 and 4 show embodiments, according to the invention, respectively of a coding device for transmitter and a decoding device for receiver in which is implemented said transmission method.

The transmission method according to the invention comprises, as indicated in FIGS. 2a and 2b, four separate operations, which will be examined in detail successively
(a) on transmission, formation, from a starting image consisting of a frame, for example pair T and of the following odd frame T + 1, of a frame called here new intermediate frame NTI with respect to the previous description of the known process
(b) transmission of all the color difference signals associated with the lines of this new intermediate frame;
(c) reconstruction, on reception, of said new intermediate frame from the transmitted signals;
(d) formation of a final image by interpolation from said new reconstituted intermediate frame.

 The first operation is as follows. On transmission, from the color difference signals U and V which surround a determined line with a determined frame T in the same determined frame and in the neighboring frames, a frame called the new intermediate frame is formed.

More precisely, for this determined line, the U-type component of the corresponding line of the new intermediate frame consists (see FIG. 2a) of a combination
(1) of the component U associated with said determined line (line denoted L1 in FIG. 2a);
(2) of the component or components U associated with one or more lines of the same frame adjacent to said determined line (here, two components U, associated with two lines denoted L2 and L3 in FIG. 2a);
(3) of the component (s) U associated with one or more neighboring lines of said determined line in one or more neighboring frames of said determined starting frame (here, two U components associated with the two lines denoted 4 and L5 of the preceding frame and two components U associated with the two lines denoted L6 and L7 of the following frame).

 Similarly, for this same determined line, the V-type component of the corresponding line of the new intermediate frame is made up of a similar combination of the V components associated with the same lines sampled in the same way from the determined frame and the neighboring frames. .

In order not to overload the figure, this combination is shown for another line of the new intermediate frame. The components thus obtained for each line of the new intermediate frame thus formed are called type U and type V because they no longer represent any of the original U or V signals, but are a combination thereof, by vertical filtering and weighting of several frames in the present case.

 The second operation, represented on the left-hand side of FIG. 2b, is that of the transmission of the signals U and V associated with the lines of the new intermediate frame NTI thus formed. As in the case of the previous embodiments, an odd frame comprising alternately a U-type component and a V-type component is transmitted successively, or vice versa, and an even frame comprising alternately a V-type component and a U-type component, or Conversely, but whereas, in the case of these previous embodiments, the signals of said transmitted odd and even intermediate frames were formed from the signals of two starting frames, this constitution is here now operated from a single frame, the new intermediate frame formed during the first operation. As a result, a quantity of information twice as large can be transmitted, in the case of an intermediate frame with the same number of lines as the starting frames.

 The organization of these transmitted signals is as follows. the transmitted odd frame includes on its lines of a first determined parity, for example on its odd lines, the U-type component of the lines of the same determined parity of the new intermediate frame NTI and on its other opposite parity lines, on its even lines in the example chosen, the type V component of the other opposite parity lines of this same new intermediate frame. The transmitted even frame symmetrically includes the other signals, not yet transmitted, of the new intermediate frame, c ' ie includes on its lines of the same determined parity the component of type V of the lines of same determined parity of the new intermediate frame and on its other lines, of opposite parity, the component of type U of the other parity lines opposite of this same new intermediate frame. It can be seen that in this way all the signals of the new intermediate frame are transmitted.

The third operation, represented on the central part of figure 2b, and the fourth operation, represented on the right part of figure 2b, are carried out at the reception and contribute to reform 11 final image in the following way
(a) third operation: a TMP frame known as having the same parity as the new intermediate frame NTI is reconstituted, from the odd and even intermediate frames transmitted, by an operation exactly opposite to that - the second operation - executed to constitute said intermediate frames odd and even transmitted;
(b) fourth operation: a TPO frame of opposite parity is reconstructed by interpolation of each of its lines from the lines of the frame which has just been reconstructed during the third operation. The complete final image is now reformed, with, as indicated previously for the example described, a vertical resolution twice greater than what was known until now.

 For the implementation of the method which has just been described, an example of a system for transmitting color difference signals will now be presented, with, in the transmitter of the system, a coding device such as that shown in the FIG. 3 and, in the receiver, a decoding device such as that shown in FIG. 4.

We know that in terms of color television it appeared interesting, to define with the luminance signal Y the components of the colors to be reproduced, to use the signals, denoted here U and V, of color difference. We will not be interested here in the way in which these signals Y, U, V are obtained, the documents on this subject being very numerous (see for example the work "Color television", collection "Electronic Techniques", Masson et Cie éditeurs, 1967). We will simply assume that the signals U and
V are available, the invention relating only to a method for processing them on transmission, with a view to their transmission and processing on reception allowing a reconstruction of a final image, as well as the coding and decoding devices. allowing the transmission and reception of these treatments.

 The coding device shown in FIG. 3 first comprises two memories 100 and 101 in series. The first memory 100 receives the signal U present on a first input connection and delays it by a frame minus a semi-line so that at the input and at the output of this memory are present simultaneously two consecutive lines in the picture. The second memory 101 receives the output signal from the first memory 100 and delays it by one frame plus a half line so that the input of memory 100 and the output of memory 101 are ultimately present the signals corresponding at each instant to lines of the same position but belonging to two consecutive images. A combination circuit 110 whose inputs, here three, are connected respectively to the input and to the output of the memory 100 as well as to that of the memory 101 performs the combinations of components U described above under the name of first operation, these combinations leading to the determination of the frame qualified as a new intermediate frame NTI.

The presence of similar circuits 200, 201, 210 for the processing of the signal V present on a second input connection of the coding device finally makes it possible to have, at the output of the circuits 110 and 210, components of the U and V type of said new intermediate frame
NTI. A switching circuit 120 selects the U type components which will be transmitted in the current frame (for example a first odd frame) and those which will be temporarily stored in a third memory 130 so as to be transmitted only during the frame (pair) following this current frame. Similarly, a switching circuit 220 performs the same function vis-à-vis the components V, using a memory 230, and by selecting a component of type V to be stored in memory 230 when the corresponding U-type component is transmitted in the current frame and, conversely, a V-type component to be transmitted in the current frame when the corresponding U-type component is stored in memory 130.

 These circuits 120 and 220 are followed respectively by selection circuits 140 and 240 which select the components to be transmitted: during the first odd frame, called the current frame above, the U and V type components transmitted come from the switching 120 and 220 respectively, while during the second, even frame following the current frame, the V-type and U-type components transmitted come from memories 130 and 230 respectively. It is therefore the second operation, defined previously in the description of the process according to the invention, which is carried out here using circuits 120 to 140 and 220 to 240, a multiplexing circuit 300 finally taking the output signals from the switching circuits 140 and 240 to present them in sequential form, line by line, at the output of the coding device.

Conversely, the decoding device provided in the receiver and represented in FIG. 4 comprises a demultiplexing circuit 400 which receives the sequence of the signals U and
V transmitted alternately, line by line for each odd frame then even, and switches these signals according to whether they are of type U or of type V. The components of type U present at the output of this circuit 400 are first sent to a memory 510 making it possible to delay the U-type component pending the arrival of the second transmitted frame, then directly to a terminal T of a selection circuit 520 when the signals of said second frame arrive. Similarly, the type V components present on the other output of the circuit 400 are sent either to a memory 610 or to the terminal T of a selection circuit 620.

 The selection circuits 520 and 620, controlled in synchronism at the line frequency, then carry out the third operation of the method, that which consists in reassociating for each line of the reconstituted odd frame a component of type U and a component of type V. As indicated in FIG. 4, the selection circuits 520 and 620 here comprise a switch whose movable contacts both occupy their upper position, in this case for selecting a U-type component from the first frame transmitted, stored temporarily in memory 510, and a type V component of the second frame transmitted, this component arriving directly from the demultiplexing circuit 400. Once this selection has been made, the mobile contacts move simultaneously to their lower position, to select this time, conversely , a U-type component of the second frame, arriving directly from circuit 400, and a V-type component of the first trans frame setting, temporarily stored in memory 610. the reconstructed odd frame is thus available on the TRI outputs of the selection circuits 520 and 620.

 The fourth operation, which aims to form an even frame to be associated with the odd frame thus reconstructed, is carried out using the interpolation circuits 530 and 630. Each of these two circuits performs, the first for the U type components and the second for the V type components, a vertical linear interpolation which allows the reconstruction of the U and V signals corresponding to the lines of the second, even, frame of the 'final image. The selection circuits 540 and 640 then make it possible to select the signals of the reconstructed odd frame, by connection with the output of circuits 520 and 620, or to select the signals of the interpolated even frame, by connection with the output of circuits 530 and 630, the association of this odd frame and this even frame giving a final image of the same format as the starting image.

 Of course, the present invention is not limited to the embodiments described and shown, from which variants can be proposed without thereby departing from the scope of the invention.

 For example, it was considered in the previous description that we transmitted an odd frame, then an even frame, but it could be the opposite. Furthermore, vertical filtering inside a same frame can involve a any number of lines in the same frame, even if you preferably choose to use only the lines immediately preceding and following the current line considered (that is to say the upper and lower lines). On the other hand, the weighting between frames can, similarly, involve a number of previous or following frames greater than two, and not only a previous frame and a next frame as in the embodiment described in FIG. 3 If it is desired, for example, to carry out a weighting on two preceding frames and two following frames, it is necessary, with respect to said exemplary embodiment, to double the number of the memories in series and to provide four memories for the processing of the U components and four memories for that of the V components. This last variant does not involve any modification of the circuits on reception.

 Finally, the invention clearly relates to any television signal transmission system comprising a transmitter and / or a receiver equipped with coding and / or decoding devices as defined in the above embodiments or their variants.

Claims (5)

1. Method for transmitting color difference signals in television comprising the following operations  (a) on transmission, from the color difference signals U and V associated with each line of a frame of the starting image with odd frames and interlaced pairs, formation of a frame to be transmitted, called an intermediate and consisting of so-called intermediate lines, by association with said intermediate lines of a U-type component and of a V-type component alternately, said U-type component associated with the intermediate line considered being constituted for each odd or even frame of a combination of the components U associated with the corresponding line of the odd frame or corresponding starting pair and with one or more lines of the same starting frame close to this corresponding line, and said component of type V associated with the intermediate line following of the same intermediate frame similarly consisting of a combination of the components V associated with the next line of the starting frame and with one or more lines of the same starting frame neighboring this next line;  (b) sequential transmission, line by line, of alternately odd and even intermediate frames  (c) on reception, reconstruction of a final image characterized in that:  (d) on transmission, for the formation of a new intermediate frame from a starting frame of determined parity, said combination of components U also includes, for the considered intermediate line, the components U of one or more of several lines close to said intermediate line in one or more frames of any parity close to said starting frame, and said combination of components V also includes, for the same intermediate line, the components V of one or more lines close to this same intermediate line in one or more frames of any parity adjacent to said starting frame  (e) from the new intermediate frame thus formed, the intermediate frames to be transmitted consist successively of a part of an odd frame including on its lines of determined parity the U-type component of the lines of the same determined parity of said new intermediate frame and on its other lines of opposite parity the component V of the other lines of opposite parity of this same new intermediate frame and on the other hand of an even frame including on its lines of the same determined parity the component of type V of lines with the same parity of said new intermediate frame and on its other lines of opposite parity the U type component of other lines of opposite parity of this same new intermediate frame  (f) on reception, formation of the final image on the one hand from a frame of the same parity as said new intermediate frame and reconstituted from intermediate frames transmitted by an operation opposite to that executed to constitute said frames intermediaries transmitted, and secondly from a parity frame opposite to that of said new intermediate frame and reconstructed by interpolation from said frame of the same parity already reconstituted. 2. Transmitter of color television signals composed of a luminance signal Y and two color difference signals U and V, characterized in that it comprises, for the implementation of the method according to claim 1, a coding device consisting of the following elements for the processing of U components and for that of V components  (a) 2n memories in series producing successively delays on each component U of a frame minus half a line and of a frame plus a half line, and 2n similar serial memories for the delay of each component V  (b) a combination circuit receiving on its (2n + l) inputs respectively the component U, or the component V, and the 2n output signals of the 2n corresponding memories;  (c) a switching circuit directing the output signal of said combination circuit alternately to a frame memory or to a selection circuit  (d) the selection circuit ensuring the selection of the output of the switching circuit during one frame and that of the output of the frame memory during the next frame;  (e) a multiplexing circuit intended to send to the transmission channel, at the output of the coding device, U or V type components alternately, in sequential form and line by line. 3. A color television signal transmission system comprising a television signal transmitter according to claim 2. 4. Receiver of color television signals characterized in that it comprises, for the implementation of the method according to claim 1, a decoding device receiving from the transmission channel, in sequential form and line by line, components of type U or type V alternatively and consisting of the following elements for the treatment of these components  (a) a demultiplexing circuit intended to direct to a processing channel of the U-type components or to a processing channel of the V-type components the U-type and V-type components arriving sequentially, line by line, at the decoding device input ;;  (b) in the processing of U-type components  (1) a first selection circuit, the output of which is connected either directly to the output of the demultiplexing circuit or to this same output via a frame memory;  (2) an interpolation circuit whose inputs are connected respectively to the output of the demultiplexing circuit and to that of the frame memory;  (3) second selection circuit, the output of which is connected either to that of the first selection circuit or to that of the interpolation circuit to alternately deliver the U-type component from the lines of the frame reconstructed from the transmitted frames or the component U type of the frame interpolated from said reconstructed frame  (c) in the V-type component processing channel, similar circuits for alternately delivering the V-type component of the lines of the frame reconstructed from the transmitted frames or the V-type component of the frame interpolated from said reconstructed frame; said first selection circuits being intended to simultaneously select either a U component of the first transmitted frame and a V type component of the second transmitted frame, or vice versa, for the next line of the reconstructed frame, a U type component of the second transmitted frame and a type V component of the first transmitted frame, and said second selection circuits being intended to allow reception of the U and V type components either of the frame reconstructed from the transmitted frames, or of the interpolated frame from the reconstructed frame. 5. A color television signal transmission system comprising a receiver according to claim 4.