Abstract:
The present invention concerns a processing method for a video signal coded in the form of blocks of K words, this signal being written to or read from two frame memories (FM1, FM2) each including an input port, a high speed output port and a low speed output port. According to this method, the input digital video signal is formed by sets of M&#39; blocks with N&#39; block containing luminance data (Y1, Y2 . . . ) and M&#39;-N&#39; blocks containing chrominance data (C1, C2 . . . ), the blocks containing the chrominance data (C1) are written in the first memory (FM1) and the blocks containing luminance data (Y1) are written in the second memory (FM2). Then the blocks containing the luminance data and the blocks containing the chrominance data are read simultaneously on the high speed output port of each memory, the memories being inverted at each frame, and the data eventually being processed to obtain video data in output that presents a compression ratio M/N with M&gt;N.

Description:
This application is a continuation of application Ser. No. 08/130,412, filed on Oct. 1, 1993, now abandoned, which is a continuation of application Ser. No. 07/726,336, filed on Jul. 5, 1991, now abandoned 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention concerns a video signal processing method, more specifically a processing method which makes it possible to display a 4/3 format image on a 16/9 format television tube. 
     2. Discussion of the Background 
     Tubes with a 16/9 format image have only recently existed on the market. These tubes were developed for high definition applications. However, today we plan to equip televisions with this type of tube, namely television sets whose architecture was designed to be compatible with future standards. Yet, all currently broadcasted programs are in 4/3 format. To display a 4/3 format video image on a 16/9 tube, it is therefore necessary to process this image to eliminate distortion or anamorphosis problems during the display. 
     Different techniques have been developed to display a 4/3 image on a 16/9 format television tube. Hence, in the German P 37 22 172.8 patent application, techniques based on a combination of image vertical size variation (by changing the amplitude of the vertical deflection current) and by changing the horizontal image size with electronic means are used. 
     SUMMARY OF THE INVENTION 
     The present invention concerns a new processing method based on the use of picture frame memories as a means of storage. 
     Consequently, the object of the present invention is a processing method for a video signal coded in the form of blocks of K words, this signal being written to or read from two picture frame memories which each have an input port, a high speed output port and a low speed output port, characterized by the fact that the input digital video signal is formed by sets of M&#39; blocks with N&#39; blocks containing luminance data and M&#39;-N&#39; blocks containing chrominance data, and by the fact that the blocks containing chrominance data are written in the first memory and the blocks containing luminance data are written in the second memory, the memories being inverted at each frame and the blocks containing luminance data and the blocks containing chrominance data are read simultaneously on the high speed output port of each memory, the memories being inverted at each frame, and the data possibly being processed to obtain video data in output that presents a compression ratio of M/N with M&gt;N. 
     According to a specific realization mode, M=4 and N=3. Moreover, the input port of the frame memory operates at a 13.5 Mhz clock frequency while the high speed output port operates at a 27 Mhz frequency. Because of this fact, we obtain luminance data as output which are directly usable for display on the 16/9 television tube, while chrominance data can be used after storage in a buffer memory making it possible to obtain the desired sampling frequency. 
     According to another characteristic of the present invention, the blocks containing luminance data and blocks containing chrominance data are read simultaneously on the low speed output port of each memory, the memories being inverted at each frame, to obtain an output video data delayed by one image. Because of this, data issued from the low speed output ports can be reinjected as input into the video signal pre-processing circuit to obtain noise reduction for example. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     Other characteristics and advantages of the present invention appear after reading the description given hereunder of a preferential realization mode of the video signal processing method compliant with the present invention as well as a device for implementation of the aforesaid method, the description refers to drawings in the appendix where: 
     FIG. 1 is a synoptic diagram of a frame memory used in the present invention; 
     FIG. 2 is a timing diagram representing the contents of different frame memories in function of time; 
     FIGS. 3, 4 and 5 are timing diagrams representing the different control signals of frame memories at the levels of the input port and two output ports respectively; 
     FIG. 6 is a synoptic diagram of a device used for implementation of the processing method in compliance with the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In FIG. 1, we have schematically shown a type of frame memory which can be used in the context of the present invention. This representation is not limiting. The aforesaid memory is a video memory. As shown in FIG. 1, the video memory essentially includes a memory part 1 controlled by horizontal counters 2 and vertical counters 3 piloted by a control circuit 4. More specifically, the horizontal counters 2 are composed of three internal pointers HP1, HP2, HP3 while the vertical counters are composed of three internal pointers VP1, VP2, VP3. Pointers VP1 and HP1 point to the block where input data must be written, pointers VP2 and HP2 point to the block which must be read at serial output A level, while pointers VP3 and HP3 point to the block which must be read on serial output B. Interface 5 is between the input and output registers and the memory FIG. 1. It also includes a serial shift register 6 piloted by a clock HA and which serves as a buffer register for input port A and output port A. This serial shift register 6 is linked to interface 5 by means of write 7 and read 8 maintenance circuits. FIG. 1 also includes a serial shift register 9 piloted by clock HB which serves as a buffer register for output port B and which is connected to interface circuit 5 by means of a read maintenance circuit 10. In this case, the clock frequency of the two input ports and output port A is identical while the clock frequency of the second output port, i.e. port B, is an integer multiple of the clock frequency at input port A. Each port can be addressed by an assembly of two counters, i.e. a counter for columns and a counter for rows. The three available counter assemblies are completely independent as indicated in FIG. 1. In general, one cannot access the memory itself word by word because the access time would be much too long. Because of this, we access the memory by blocks of K words, K being chosen as equal to 12 in the represented realization mode. Thus, when the horizontal counter is incremented by one, we access a new block of 12 words. The incrementation of each counter is controlled in an external fashion by circuit 4. This video memory is used to store a digitized video signal. Consequently, the data contained in the frame memory are constituted by luminance signal samples and chrominance signal samples. Traditionally, chrominance has a sampling frequency lower than that of luminance. In the context of the present invention, the data blocks include either luminance data, or chrominance data, and three blocks of luminance data are interlaced with each block of chrominance data, as explained hereunder with reference to the different timing diagrams. 
     We will now describe in reference to FIGS. 2 to 6 a realization mode of the video signal processing method which allows display of a 4/3 format signal on a 16/9 format television tube in compliance with the present invention. This processing method applies to a case where the system uses two frame memories. As shown in FIG. 2 each frame F1, F2, F3, F4, F5, F6 has a duration of 20 ms. In the case of a color image, the sampling frequency is divided between the luminance components Y1, Y2, Y3, Y4, Y5, Y6 and chrominance components C1, C2, C3, C4, C5, C6. The luminance sampling frequency is 10.125 Mhz and the chrominance sampling frequency is 3.375 Mhz, (see FIG. 2) which makes it possible to obtain a 13.5 Mhz sampling frequency, i.e., the clock frequency of input port A of a frame memory in the represented realization mode. The organization of data in each frame memory FM1 and FM2 is shown in this FIG. 2. We can see that the video components Y1 and C1 are written separately in the two frame memories. 
     As shown in FIG. 3, the video signal has been digitized and put into the form of 12 sample blocks. The data formatted at input successively include three samples of luminance data Y followed by a sample of chrominance data C, this sequence is repetitive. In compliance with the present invention&#39;s method, in the first frame memory FM1, we first write the luminance data. Incrementation of the horizontal counter of FM1 is performed as shown in FIG. 1. At the first counter incrementation we write the Y luminance data block. The counter of FM1 is then incremented but write is not authorized. The input datum is then a chrominance datum, which is not written into frame memory FM1, but is written into frame memory FM2 as shown in FIG. 3. The same is true for all blocks constituting a frame, for example frame F2 in FIG. 2. During the next frame we invert the which memory is enabled to, and does store data, so that luminance and chrominance data are stored in separate memories, and thus write the chrominance data in the memory of frame FM1, these data being represented by C3 in FIG. 2, and the luminance data in the memory of frame FM2, these data being represented by Y3 in FIG. 2. Thus, in compliance with the present invention, one of the frame memories first stores the luminance components of a frame sampled at 10.125 Mhz, while the other frame memory stores the U and V chrominance components of the same frame which are at 3.375 Mhz. When we read the data on the output port B of each frame memory, we thus obtain, for the written data compliant with the diagram shown in FIG. 3, the data shown in FIG. 4. Because of this fact, on the output port B of frame memory FM1, we obtain the luminance components Yl, Ym, Yn, Yo, Yp, Ya in a continuous stream which are output at the instantaneous frequency of 27 Mhz, which corresponds well to a compression ratio of 4/3. In fact, 27=(10.125×2)×(4/3). In this case, the incrementation of the horizontal counter of frame memory FM1 is performed as shown in FIG. 4. Every three pulses, we send two simultaneous control pulses since a chrominance component is interlaced with three luminance components. Simultaneously, we output chrominance components Cα and Cβ on output port B of frame memory FM2. In this case, a block of valid data is output every three blocks at the moment when the horizontal counter incrementation is composed of two pulses. A buffer register is of course necessary to obtain a continuous flow of input at the chrominance data sampling frequency, i.e. 9 Mhz from this 27 Mhz flow. 
     According to another characteristic of the present invention, the output port A of two frame memories is used to obtain the data which make it possible to perform noise reduction processing. Because of the writing mode used to write in frame memories FM1 and FM2, the luminance component is obtained from a frame memory, while the chrominance component is obtained from the other frame memory, the functions of each memory being inverted at each frame i.e. memory FM1 stores a first luminance data in one frame but when a chrominance data is to be read it is stored in frame memory 2, frame memory 1 being disabled from reading during presentation of chrominance data. The control signals demonstrating the operation of counter incrementations are shown in FIG. 5. The output port A operates at the same frequency as input port A, we respectively obtain on the output port A of each frame memory FM1 and FM2, a chrominance component Cα or Cβ followed by three insignificant blocks and three luminance components Yl, Ym, Yn, Yon Yp, . . . followed by an insignificant block. In this case, the counter is incremented to point to the next blocks, but the data is insignificant. In output from ports A of frame memories FM1 and FM2, we thus obtain the data delayed by one image which can be used for noise reduction or for any other processing by being sent to a preprocessing circuit, as shown hereunder in FIG. 6. 
     We will now describe with reference to FIG. 6, a device that allows implementation of the processing method in compliance with the present invention. In the circuits shown in FIG. 6, the luminance and chrominance components of a video signal have first been separated before being processed and stored in video memories FM1 and FM2. As shown in FIG. 6, the circuit that complies with the present invention includes two video memories 100, 101 with three ports, i.e. an input port A operating at a 13.5 Mhz frequency, a low speed output port A operating at a 13.5 Mhz frequency and a high speed output port B operating at a 27 Mhz frequency. The input ports A of video memories 100 and 101 receive digitized signals issued from a signal processing circuit 111. This processing circuit 111 receives as input the luminance Y and chrominance C signals multiplexed in circuit 105 to form a signal at 13.5 mega-samples per second. Before entering into circuit 105, the luminance signal Y is sent to a low pass filter 102 then an analog digital convertor 103 transforms the aforesaid luminance signal into digitized data sampled at a 10.125 Mhz frequency and a FIFO (first in, first out) type buffer circuit 104 entering the data at a 10.125 Mhz frequency and outputting them at a processing frequency of 13.5 Mhz; likewise, before entering into circuit 105 the luminance signals are sent to a low pass filter 106 receiving the chrominance signal U and to a low pass filter 107 receiving chrominance signal V, then to a multiplexer 108 multiplexing signals U and V issued from low pass filters 106 and 107, the multiplexer operating at a frequency FH/2, an analog digital convertor 109 transforming the analog chrominance signals into digital chrominance data sampled at a frequency of 3.375 Mhz, and to a FIFO type buffer circuit 110 whose input operates at 3.375 Mhz frequency and the output at 13.5 Mhz frequency. As shown in FIG. 6, output ports A of memories 100 and 101 are each connected to the input of two multiplexer 112, operating at the frame frequency. The outputs of multiplexer 112 is respectively sent to the signal processing circuit 111 processing circuit, to perform noise reduction by adding the weighted signal of the previous image to the luminance signal or chrominance signal. Moreover, outputs B of video memories 100 and 101 are respectively connected to the inputs of the two multiplexers 114, 115 operating at image frequency T/2. As an output from multiplexer 114, we obtain chrominance data at an instantaneous sampling frequency of 27 Mhz. These chrominance data are input into a FIFO type buffer register 116 which outputs them at the 9 Mhz sampling frequency. The data output from the buffer register are either sent directly, or after passage in a vertical filter 117, to a demultiplexing circuit 118 to separate the chrominance data into chrominance datum U and chrominance datum V. They are each sent to an digital analog convertor 119, 120 operating at 9 Mhz frequency and in a known manner the signals issued from the digital analog convertors 119, 120 are sent to low pass filters 121, 122 to obtain output chrominance signals U and V which can be displayed without distortion on a 16/9 screen. Likewise, as an output from multiplexer 115, we obtain a luminance signal at the sampling frequency of 27 Mhz. This signal is sent to a digital-analog convertor 123 operating at 27 Mhz, then to a low pass filter 124 to obtain a luminance signal that can be directly displayed on a 16/9 screen. 
     The above described circuit thus makes it possible, by using two frame memories, to perform video signal processing which complies with the present invention. This processing permits display of the video signal on a 16/9 screen without distortion.