NL8803100A - HDTV colour TV system - received film mode information signal indicating whether picture signal originates from film - Google Patents

Abstract

The encoding method comprises the steps by receiving the picture signal and determining motion vectors relating to a motion in a picture of the picture signal. A selection signal is obtd. to select one operation mode out of a number of possible operation modes on the picture signal depending on the selection signal to obtain a picture signal to be encoded. The selection signal and the motion vectors are digitally encoded to obtain an assisting signal to inform a decoder which one of the operation modes has been selected and about the motion vectors. The picture signal to be encoded and the assisting signal is encoded to obtain the encoded picture signal. A film mode information signal is received indicating whether the picture signal originates from film. The selecting step further depends on the film mode information signal. The film mode information signal is digitally encoded, the assisting signal also comprising the film mode information signal to inform the decoder whether the picture signal originates from film.

Description

N.V. Philips' Incandescent lamp factories in Eindhoven.

High definition television system comprising an image signal transmission path and storage device with a bandwidth which is too narrow for the high definition, and an image display device and image signal source suitable for such a system.

The invention relates to a high definition television system comprising an image signal transmission path and storage device with a bandwidth which is too narrow for the high definition, the system further comprising a high definition image signal source and at least one high definition image display device, which are coupled via the transmission path and the storage device, which image signal source is provided with an encoding circuit for encoding a high definition image signal into an image signal with the said limited bandwidth and which display device is designed with a supplementary decoding circuit for decoding the image signal with the limited bandwidth to display high definition image signal, which encoding circuit is implemented with at least three parallel image signal channels coupled by a time-division multiplex circuit, and with a motion estimator which, by supplying the image signal, movement of picture parts in the picture to be displayed estimates and, depending on the estimation result, the time-division multiplexing circuit causes one of the picture signal channels to supply the picture signal with the limited bandwidth for the transfer or storage, wherein, with a frame-wise encoding, each picture signal channel has a different picture signal refresh period, and which decoding circuit is outputted with at least three parallel image signal channels complementary to the encoding circuit coupled by a synchronized time-division multiplex circuit, the synchronization being effected by a transmitted or stored motion estimation result, respectively.

The invention also relates to an image display device and an image signal source suitable for such a system.

Such a high definition television system is known from a presentation at a conference and an associated article designated "TVDH'87, Ottawa (CA), October 4-8, 1987, vol. 1, P.

Bernard et al .: "Analysis of the structures de sous-échantillonnage spatio-temporel d'un signal TVHD and vue de sa transmission dans un canal MAC", pages 6.2.2-6.2.28 *. For color television, the introduction of high definition television (HDTV) for the home has been described. Based on the so-called MAC system (Multiplexed Analogue Component) with its limited bandwidth, a compatible high definition system (HD-MAC) has been described. It is stated here that there must be a balance between the best HD-MAC image available for specific receivers and the ability to maintain acceptable quality for existing MAC receivers. To this end, it has been proposed to use three picture signal channels with a shortest, middle and longest picture signal refresh period in the coding circuit and the complementary or inverse decoding circuit, the shortest being 20 ms. Depending on the motion estimation result, one of the three channels is used locally in the image. When moving over more than 2 picture elements per picture period (20 ms), the channel with the shortest period is used. When moving between 2 and 0.5 pixels per picture period, the channel becomes the middle period, and moving less than 0.5 pixels per picture period uses the channel with the longest period. In order to obtain the image signal bandwidth reduction, use is thus made of the splitting into sub-images which are stationary or which show some movement or much movement, respectively.

It has been found in practice that the high definition image often does not have optimal image quality. Differences in image resolution are noticeable.

The object of the invention is to realize a system in which the differences in image quality are less noticeable. A system according to the invention has, for this purpose, characterized in that the system operates in a film mode and a non-film mode, wherein during the film mode the image signal source outputs an image signal associated with a film with film images between which movement is present in the images, which movement occurs periodically with a film picture period, during which film mode a picture signal channel in the encoding and decoding circuit with the picture signal refresh period less than the film television picture period is inoperative.

The invention is based on the insight that an image quality improvement is obtained if a distinction is made according to whether the image signal originates from a film or not. In the image signal source, for example, a film-television conversion takes place with the aid of a telecine device. For example, 24 film images per second are converted into 25 television images per second. Optimal image quality is obtained by disabling the image signal channel that has an image signal refresh period less than the movie image period.

A high definition color television system according to the invention, which operates with a luminance signal and with chrominance signals which obtain, via a luminance encoding circuit and chrominance encoding circuits, respectively, the bandwidth reduction which is eliminated by means of at least three picture channels, at least three picture signals, by means of at least three picture signals, using at least three picture decoding circuits, respectively. middle and longest picture signal refresh period, characterized in that during the non-film mode, the luminance encoding and luminance decoding circuit operates with at least all three picture signal channels, and the chrominance encoding and chrominance decoding circuits operate with the shortest and the longest picture signal refresh period, and during and chrominance encoding and decoding circuits operating the image signal channels having the middle and the longest image signals post refresh period, which middle period is equal to the movie television picture period.

A high definition image display device according to the invention suitable for use in the high definition television system equipped with the decoding circuit for decoding the image signal with the limited bandwidth into a high definition image signal to be displayed, which decoding circuit is provided with at least three parallel image signal channels which are coupled are by a synchronized time-division multiplex circuit, the synchronization being effected by a transmitted or estimated motion estimation result, respectively, characterized in that during the film mode and the non-film mode, respectively, an image signal channel having the image signal refresh period less than the movie television image period is out of action, respectively.

An embodiment of the color television display device equipped with a luminance decoding circuit and chrominance decoding circuits, at least three picture signal channels per decoding circuit having at least one short, middle and longest picture signal refresh period, is characterized in that the luminance decoding circuit operates during the non-film mode at least all three image signal channels and the chrominance decoding circuits operate with the shortest and the longest image signal refresh period, and during the film mode the lumminance and chrominance decoding circuits operate with the image signal channels having the middle and the longest image signal refresh period, which middle period is equal to the film television image .

A high definition image signal source according to the invention, implemented with an encoding circuit for encoding a high definition image signal into an image signal with the said limited bandwidth, which encoding circuit is implemented with at least three parallel image signal channels coupled by a time-division multiplex circuit, and with a motion estimator which, while supplying the image signal, estimates the degree of movement of image parts in the image to be displayed and, depending on the estimation result, the time-division circuitry causes one of the image signal channels to supply the image signal with the limited bandwidth for the transfer and storage, each image signal channel being provided with a frame-coding. has a different picture signal refresh period, characterized in that the picture signal source is provided with a selector switch for selecting the film mode, whereby the motion estimator is adjusted.

The invention will be explained in more detail with reference to the accompanying drawing, in which figure 1 shows a block diagram of an image signal source suitable for use in a high definition television system according to the invention for color television and figure 2 shows a block diagram of a suitable high definition image display device.

In the block diagram of a high definition image signal source according to the invention given in Figure 1, DSS designates an, for example, digital signal source. The image signal source of Figure 1 is said to be suitable for use in an HD-MAC color television system, which is illustrated with a MAC encoding circuit MAC ENC and with the designation 1250/50/2: 1 at the signal source DSS. The number 1250 represents the number of television lines per image period, with 50 single interlaced (2: 1) frames forming 25 images. Here there is an unspecified television line period equal to 32 ps. The signal source DSS could further supply an uninterlaced image signal to which the designation 1250/50/1 belongs. The image signal source DSS supplies, for example, image signals from a television camera or a telecine device with which original 24 Hz film images are converted into 25 Hz television images. The original 41.66 ms film frame period is substantially equal to the 40 ms television frame period and is converted herein, which is referred to as a film television frame period. 0T shows an output of the image signal source according to Figure 1, which is coupled via an image signal transmission path (not shown) to an input IT shown in Figure 2 of a high-definition image display device according to the invention. The connection 0Τ-ΙΤ may include an image signal storage device instead of a transmission path. Regardless of the implementation of the connection OT-IT, it is stated that it has a more limited bandwidth than the image signal bandwidth. As an example, a transmission or storage bandwidth of 6.75 MHz is mentioned with a television system 625/50/2: 1, while an original image signal bandwidth of 54 MHz is present. In the schematic of Figure 1, Y0 (54 MHz) denotes a luminance signal and 0 and V0 (27 MHZ) denote chrominance signals supplied by the signal source DSS. An encoding circuit according to the invention follows in the source DSS, in which an encoded luminance signal Y1 (13.5 MHz) and processed chrominance signals U1 and V1 (6.75 MHz) are applied to the encoding circuit MAC ENC. Data circuitry is further supplied to the circuit MAC ENC from an encoding circuit DATV ENC, where DATV stands for "Digitally Assisted TV", and an input data signal and audio signal are designated DS, SS. The circuit MAC ENC provides in a known manner for a bandwidth halving and a simultaneous sequential conversion of the supplied image signals.

In Fig. 1, the luminance signal YO is applied to a Y signal processing circuit PCY, while the chrominance signal Ü0 and VO, respectively, is supplied to a similarly executed (10 and VO signal processing circuit PCü and PCV, respectively. Circuit PCY is further shown in detail with three parallel image signal channels. PC1, PC2 and PC3 which are coupled by a time division multiplex circuit MOX1 and via these are connected to the MAC ENC circuit.

The picture signal channel PC1 is shown with a series connection of a low-pass filter LPF1, a sample circuit SC1, drawn as a switching circuit, to which a sample clock pulse signal CS is applied and a line shifting circuit LS1. The known line shift is illustrated with a dashed and dotted line and an arrow. Likewise, the channel PC2 is equipped with a low-pass filter LPF2, a sampling circuit SC2 and a line shifting circuit LS2. The image signal channel PC3 is provided with a switching circuit SC4 to which a switching signal VS occurring with an image period is applied, a low-pass filter LPF3 and a sample circuit SC3 with the supply of the sample clock pulse signal CS. The switching signal VS ensures that the YO signal is processed for one frame period during each image period.

The output of the low-pass filter LPF3 is coupled to an input of a motion estimator Mot Est. The motion estimator Mot Est is drawn in three parts, where it is illustrated with 0-> 0.5, 0.5-> 12 and 12-> that motion signals S80, S40 and S20 are output as motion estimation results if a motion is detected that is smaller or larger. is then a threshold value of 0.5 or 12 picture elements per picture period of 40 ms. A dashed-dotted line indicates that under certain circumstances, in a film mode, the motion estimator Mot Est only works with a threshold of 0.5 pixels per image period, so that even with motion greater than 12 pixels per image period, the motion signal S40 information "movement". Furthermore, the motion estimator Mot Est is provided with an output which is coupled to the encoding circuit DATV ENC for supplying motion vectors VR associated with the detection of an exceeding of the threshold values 0.5 and 12 picture elements per picture period.

The motion signals S80 and S40 become direct and the motion signal S20 is applied via a switching circuit SC5 to the encoding circuit DATV ENC, the time division multiplex circuit MUX1 and two time division multiplex circuits MUX2 and MUX3. The circuits MUX2 and MUX3 are coupled to outputs of the circuits PCU and PCV. The circuits MUX are drawn as mechanical switches for simplicity, each with three input terminals T20, T40 and T80 and an output terminal T0, but in practice they function as electronic switches. When the motion signal S20, S40 or S80 is supplied, the terminal T20, T40 or T80 is connected to the terminal T0 and signals Y20, U20, V20; Y40, U40, V40 and Y80, U80, V80 respectively. At 20, 40 and 80, image signal refresh periods equal to 20, 40 and 80 ms respectively are indicated. The values for the shortest, middle and longest image signal refresh periods have been mentioned as an example. More periods and other durations are possible. The terminals T0 are coupled to inputs of the coding circuit MAC ENC. In the described known manner, the signals Y1, U1 and V1 are obtained and applied to the encoding circuit MAC ENC.

According to an aspect of the invention, the switching circuit SC5 is provided, which is controlled from a manual and automatic film mode switching Film Mod Man and Aut, respectively, via a selector switch SW1. The Film Mod Aut circuit is supplied with the luminance signal YO, in which it is detected that movement is only present per image period. Instead of this detection resulting from the use of a telecine signal source, the Film Mod Man circuit may operate when the film use is known in advance. Instead of a separate circuit Film Mod Man, such a circuit could be present in the signal source DSS. In all three cases there is a film information FM at the circuit output which arrives at an output terminal TO of the selector switch SW1 via an input terminal TA or TM. An exposed terminal TT is shown at selector switch SW1 and is connected to terminal TO in the non-film mode. The terminal T0 of the selector switch SW1 is coupled, in addition to the switching circuit SC5, to the coding circuit DATV ENC, the motion estimator Mot Est and the time-division multiplex circuits MUX2 and MUX3. The film information FM is encoded in the circuit DATV ENC into, for example, one film mode information bit which occurs in the signal at the output OT. Furthermore, the film information FM shifts the threshold value of 12 picture elements per picture period in the motion estimator Mot Est so that the information "motion" also occurs at larger values in the motion signal S40. In the switching circuit SC5, a free-standing terminal TAM is connected to an output terminal T0 thereof, instead of an input terminal TT to which the motion signal S20 is applied. It has been found that in the film mode the motion signal S20 is suppressed in the control of the circuits MüX and the encoding in the circuit DATV ENC. For an implementation of the motion estimator Mot Est, reference is made to the non-prepublished Dutch Patent Application 8800452 (PHN 12.453). For obtaining an optimal estimation result in the film mode, reference is made to the non-prepublished Dutch Patent Application 8801347 (PHN 12.576). The film information hereby not only shifts the threshold value of 12 picture elements per picture period, but also adjusts the motion estimate by selecting certain frames.

When the film information FM is supplied or not to the time-division multiplex circuits MUX2 and MÜX3, these operate in different ways. When the film information FM and the simultaneous suppression of the motion signal S20 are supplied, the circuits MUX2 and MUX3 (and MUX1) operate with the image signal refresh periods equal to 80 and 40 ms. With no supply of the film information FM, supply of all three motion signals S80, S40 and S20 to the circuits MUX2 and MUX3, they operate only with the picture signal refresh periods equal to 80 and 20 ms. Thus, in a non-film mode (SW1, TT), a luminance encoding circuit (PCY, MUX1) operates with all three picture signal channels PC1, PC2 and PC3, while chrominance encoding circuits (PCU, MUX2) and (PCV, MUX3) operate with the shortest, respectively. longest image signal refresh period of 20 ms and 80 ms, respectively. During a movie mode (SW1, TA, TM), the luminance encoding circuit (PCY, MUX1) and the chrominance encoding circuit (PCD, MUX2) and (PCV, MUX3) all operate with the longest and the middle picture signal refresh periods of 80 and 40 ms, respectively.

In the block diagram of the high definition image display device of Fig. 2, the input IT is coupled to an input of a decoding circuit MAC DEC which, in addition, operates in reverse to the coding circuit MAC ENC of Fig. 1. References used in Fig. 1 are similar or the same accentuated manner in Figure 2. The MAC DEC circuit outputs data signals and audio signals DS ', SS', a luminance signal Y1 'and chrominance signals U1' and V1 '. An output of the MAC DEC circuit is coupled to an input of a decoding circuit DATV DEC which, in addition, operates in reverse to the encoding circuit DATV ENC. The circuit DATV DEC outputs data signals DS ', motion vectors VR', a film information FM 'and signals S80, S40 and S20 in the non-film mode (SW1, TT). In the film mode (SW1, TA, TM) described in Figure 1, the signals S20 do not occur, which is illustrated with a cross-out in Figure 2. A time division multiplex circuit MUX11, complementary, operating in reverse on the circuit MUX1 of Figure 1, signals S80 and S40 are applied.

Time-division multiplex circuits MUX12 and MÜX13, complementary, operating in reverse to the circuits MDX2 and MUX3 of Figure 1, are fed the signal S80, the absence of which implies an information (S40). The information (S40) is shown for clarification in the film information FM '.

Figure 2 shows a Y-signal processing circuit PCY 'with three signal channels PC 11, PC 12 and PC13. Channels PC11 and PC12 are complementary, inverted to channels PC1 and PC2 of Figure 1. Channel PC1 includes a series arrangement of a line shifting circuit LS11, a sample insertion circuit SC11 and a low-pass filter LPF11. In the circuit SC11, the insertion of the samples is indicated with "0" and a changeover switch. Channel PC12 is similarly configured with circuits LS12 and SC12 and a filter LPF12. During the film mode (SW1, TA, TM), only the output signal of the signal channel PC11 is used, which is indicated by Y80 '.

The signal channel PC13 includes a sample insertion circuit SC 13 and a subsequent low-pass filter LPF13. An output of the filter LPF13 is coupled to inputs of a switching circuit SC14, an interpolation circuit Int and a memory circuit MEM40. An output of the circuit MEM40 with a memory period equal to an image period of 40 axis is coupled to a further input of the interpolation circuit Int, to a control input of which the motion vectors VR 'are supplied. An output of the interpolation circuit Int is coupled to a further input of the switching circuit SC14, to a switching input from which a signal VS 'is applied. The switching circuit SC14 and the circuits Int and MEM40 are complementary, acting in reverse to the switching circuit SC4 of Figure 1. The result is the output of a signal Y40 'through the signal channel PC13. Via the time-division multiplex circuit MUX11, an processed luminance signal Y0 '(54 MHz) is obtained for supply to a high definition image display HDTV suitable for a (1250/50/2: 1) display. In the presence of an unsigned low-definition image display, the signals output from the MAC DEC decoding circuit can be used directly for display. Compatibility is present between the high and the low definition display. The circuit components between the MAC DEC circuit and the HDTV image displayer realize the bandwidth recovery to the high definition.

In Figure 2, a U1 'signal processing circuit PCD' is shown in detail, a V1 'signal processing circuit PCV' being considered to be designed in the same manner. A signal channel PC21 is similar to the signal channel PC11 equipped with a line shifting circuit LS21, a sample insertion circuit SC21 and a low-pass filter LPF21 and it outputs a signal U8Ö '. A signal channel PC22 contains circuits LS22 and SC22 and a low-pass filter LPF22, of which, however, an output is coupled to an input of a switching circuit SW11 which further forms part of a signal channel PC23. In the signal channel PC23, the signal U1 'is supplied to a further input of the switching circuit SW11 via a sample insertion circuit SC23 and a low-pass filter LPF23. T20 and T40 denote input terminals of the circuit SW11 which are connectable to an output terminal T0 under the control of the movie information FM '(S40). Here, the switching circuit SW11 has a film mode mode (SW11, T40) and a non-film mode mode (SW11, T20). Figure 2 illustrates that during the film mode (SW1, TA, TM) of Figure 1 and (SW11, T40) of Figure 2, the signal channels PC21 (80 ms) and PC23 (40 ms) operate in a chrominance decoding circuit (PCU ', MUX12) , during the non-film mode (SW1, TT) of Figure 1 and (SW11, T20) of Figure 2, the signal channels PC21 (80 ms) and PC22 (20 ms) are operating. For circuits MUX12 and MUX13, this is further indicated by terminals T80 and T20.40. Just as the circuit PCü 'supplies the signals U80' and U40 'during the film mode (SW1, TA, TM) and (SW11, T40), the circuit PCV' supplies signals V80 'and V40'. As signals Ü0 'and V0' (27 MHz), these signals are applied to the high definition image display HDTV. Thus, the signals YO ', UO' and VO 'are supplied to the image display HDTV via a synchronized time division multiplex circuit (MUX11, 12, 13), under the control of the signals S80, S40 and possibly S20, which are the result of the estimation results. The system of Figures 1 and 2 has been achieved to operate with a film mode (SW1, TA, TM) and (SW11, T40) and a non-film mode (SW1, TT) and (SW11, T20). During the film mode, the image signal source of Figure 1 in particular therein supplies the source DSS, an image signal associated with a film having film images between which there is movement in the images, periodically with a film image period of about 40 ms. During the movie mode, the image signal channel (e.g. PC2) in the encoding circuit (e.g. PCY, MUX1) and that (e.g. PC12) in the decoding circuit (e.g. PCY ', MUX11) is turned off with the image signal refresh period of 40 ms.

The embodiment of the circuits PCÜ 'and MÜX12, which is shown in detail in figure 2, may be present in reverse, in addition to the embodiment with the circuit PCÜ and MUX2, in the reverse manner.

Numerous aspects have been described in detail above, which aspects are based on the following:

When applying the image signal refresh periods equal to 80, 40 and 20 ms, the algorithm also maintains in a 25 Hz film mode where the 20 m signal channel is eliminated, thereby significantly increasing the image resolution across the board.

In the chrominance encoding, no motion compensation is applied and a maximum of two image signal processing channels is active at any time. During a 50 Hz mode, the 80 ms and 20 ms channel are used, and during the 25 Hz movie mode, the 80 ms and 40 ms channel are used. The chrominance channels are fundamentally similar to the luninance channels, containing filters, sample circuits and line shift circuits, operating at 27 MHz en and V input signals, producing a multiplex ÜV output signal. The film mode is determined by one information bit.

In the motion estimate with the two threshold values of 0.5 and 12 pixels per 40 ms, only the threshold value crossing at 0.5 pixels per 40 ms is taken into account during the 25 Hz film mode.

Claims (9)

High definition television system comprising an image signal transmission path and storage device with a bandwidth which is too narrow for the high definition, the system further comprising a high definition image signal source and at least one high definition image display device, which are coupled via the transmission path and the storage device, respectively image signal source is provided with an encoding circuit for encoding a high definition image signal into an image signal with the said limited bandwidth and which display device is provided with a complementary decoding circuit for decoding the image signal with the limited bandwidth into a high definition image signal to be reproduced, which encoding circuit is provided with at least three parallel image signal channels which are coupled by a time-division multiplex circuit, and with a motion estimator which, while supplying the image signal, determines the degree of movement of image parts in the Image to be displayed estimates and, depending on the estimation result, the time-division multiplexing circuit causes one of the image signal channels to supply the image signal with the limited bandwidth for the transfer and storage, respectively, in the case of a frame-wise encoding, each image signal channel has a different image signal refresh period, and which decoding circuit is performed with at least three parallel image signal channels complementary to the encoding circuit coupled by a synchronized time-division multiplex circuit, the synchronization being effected by a transferred or stored motion estimation result, respectively, characterized in that the system operates with a film mode and a non-film mode, the image signal source during the film mode outputting an image signal associated with a film having movie images between which there is motion in the images, which motion occurs periodically with a movie image period, during which mode of motion an image signal channel in the encoding and decoding circuit with the picture signal refresh period less than the movie television picture period is inoperative. 2. High definition television system as claimed in claim 1, which system is a color television system operating with a luminance signal and with chrominance signals which, via a luminance encoding circuit and chrominance encoding circuits, respectively, obtain the bandwidth reduction which is present via a complementary luminance decoding circuit and at least three-phase decoding signals, at least having three-phase decoding signals, respectively. having at least a shortest, middle and longest picture signal refresh period, characterized in that during the non-film mode, the luminance encoding and luminance decoding circuit is operative with at least all three picture signal channels and the chrominance coding and chrominance decoding circuits are operative with the shortest and longest picture signal signal during the film mode, the luminance and chrominance encoding and decoding circuits are operative with the image signal channels by the medium th and the longest picture signal refresh period, which middle period is equal to the film television picture period. High-definition television system according to Claim 1 or 2, characterized in that the operating mode is determined in the film mode or the non-film mode by transmitting an information bit stored in the image signal transmission path or in the image signal storage device, respectively. . High definition image display device suitable for use in a system according to claim 1, 2 or 3, equipped with the decoding circuit for decoding the image signal with the limited bandwidth to a high definition image signal to be displayed, which decoding circuit is provided with at least three parallel image signal channels coupled by a synchronized time-division multiplex circuit, the synchronization being effected by a transmitted or estimated motion estimation result, respectively, characterized in that during the film mode and the non-film mode, respectively, an image signal channel having the image signal refresh period less than the movie television image period is out of action, respectively . High definition image display device according to Claim 4, provided with a luminance decoding circuit and chrominance decoding circuits, wherein at least three image signal channels per decoding circuit are present, with at least a shortest, middle and longest image signal refresh period, characterized in that the luminance decoding circuit is active during the non-film mode all three image signal channels and the chrominance decoding circuits operate with the shortest and the longest image signal refresh period, and during the film mode, the lumminance and chroma decoding circuits operate with the image signal channels having the middle and the longest image signal refresh period, which middle period is equal to the movie television image period. High definition image display device according to Claim 5, characterized in that in the chrominance decoding circuits a switching circuit is present at the picture signal channels having the shortest and the middle picture signal refresh period, which switching circuit gives a non-film mode and a film mode mode. High definition image signal source suitable for use in a system according to claim 1, 2 or 3, provided with an encoding circuit for encoding a high definition image signal into an image signal with the said limited bandwidth, which encoding circuit is provided with at least three parallel image signal channels coupled by a time-division multiplexing circuit, and with a motion estimator which, while supplying the image signal, estimates the degree of movement of image parts in the image to be displayed and, depending on the estimation result, the time-division division one of the image signal channels, respectively, the image signal with the limited bandwidth for transmission with a frame-coding, each picture signal channel has a different picture signal refresh period, characterized in that the picture signal source is provided with a selector switch for selecting the film mode, whereby the motion estimator is adjusted. High definition image signal source according to Claim 7, characterized in that the selector switch operates a switching circuit through which the motion estimation result associated with the image signal channel having an image signal refresh period smaller than the film-television image period is suppressed. High definition image signal source according to Claim 7 or 8, characterized in that the film mode selector switch is associated with the transfer and storage of a film mode information bit, respectively.