WO2011077058A1 - Method and device for producing transition effects between two tv channels - Google Patents

Abstract

The invention relates to a method for producing transition effects in real time between a first and a second TV transmission video channel on a display screen, in which method: a first and a second TV transmission video source are processed and decoded simultaneously in a first and a second processing pathway respectively so as to generate said first and second TV transmission video channels; in response to a directive to switch from the current display of the first TV transmission video channel to the display of the second TV transmission video channel, the first and second TV transmission video channels thus decoded are digitally combined in a combiner for a predetermined duration. Said combination involves generating a transition video signal displaying a progressive disappearance of the first TV transmission video channel and a progressive appearance of the second TV transmission video channel.

Description

 "Method and apparatus for effecting transition effects between two TV channels."

The present invention relates to a method and a device for performing transition effects between two TV channels. It applies especially when a user uses his remote control to change channels.

 With the introduction of digital terrestrial television, we realize that the fact of zapping from one television channel to another causes a disconnection of the current channel (with a black screen or video freeze, image to stop) and then a few moments later, the connection to the next channel. The transition between two channels is thus slow and boring for the user. Current decoders or Set Top Box generally use components designed around a moderately powerful processor (usually a MIPS processor or ARM clocked at 500MHz), this partly explains the offset found during a change of channels. Such a processor is not able to realize an instantaneous transition. The present invention aims to make the transition attractive during a chain change by eliminating the effects of a black screen or a frozen image. Another object of the invention is to allow a high definition quality transition. At least one of the above objects is achieved with a method for real-time transition effects between a first and a second TV transmission video channel on a display screen, wherein the method comprises:

 simultaneously processing and decoding first and second TV transmission video sources in a first and a second processing channel respectively so as to generate said first and second TV transmission video channels,

in response to a command to switch from the current display of the first TV transmission video channel to the display of the second TV transmission video channel, it is digitally combined for a period of time. predetermined the first and second TV transmission video channels thus decoded in a combiner; this combination of generating a transition video signal displaying a gradual disappearance of the first TV transmission video channel and a progressive appearance of the second TV transmission video channel.

 The predetermined duration is related to two phenomena. It must be long enough to mask the connection time to the second channel and long enough for the transition effect to be perceptible to the user. The minimum duration of zapping on digital channels is of the order of 2 to 3 seconds. To be perceptible the effect must last at least 2 to 3 seconds. The predetermined duration is considered to be the longest duration between the perception of the effect and the duration of zapping on the equipment in the considered network.

 The term "TV transmission video channel" refers to a real-time video signal representing a television channel or a mosaic of television channels, this video signal possibly coming from a reception by radio relay or by a network such as an ADSL signal or the like.

 With the method according to the invention, two separate processes are carried out in parallel making it possible to obtain television channel signals which are suitable for display on a television set. In particular, video signals are manipulated and not still images. These video signals correspond to quality television channels, notably high definition television, which are broadcast in normal times (excluding the transition period). That is, the present invention can realize the transition effect on video signals of the same quality as the video signals viewed in normal time.

 With the invention, we take advantage of transition times that are generally heavy between two television channels. The viewer no longer has the impression of a blockage during a change of channels, this change is now done smoothly.

According to a characteristic of the invention, the two-part display screen is split respectively displaying the first and second TV transmission video channels, then the size of the second TV transmission video channel is progressively enlarged while proportionally reducing the size. of the first TV transmission video channel until the second channel TV transmission video occupies the entire display screen. Such a transition can give the impression of scrolling a page in a "book" mode, in which the screen is split vertically, or in a "notepad" mode in which the screen is split according to the horizontal.

 It is also possible to envisage other transition modes, such as, for example, a zoom mode: during the predetermined duration, the second TV transmission video channel appears on a corner of the display screen and then gradually and completely replaces the first TV transmission video channel by a progression along the vertical and horizontal axes.

 Another zoom mode can start from a small window displaying the second video channel. In this case, during the predetermined duration, the second TV transmission video channel appears on this window of predetermined size on the display screen and then gradually and completely replace the first TV transmission video channel by a progression along the vertical axes. and horizontal.

 This second zoom mode can advantageously be applied when it is desired to select a string from a mosaic. A mosaic is a video channel that displays a matrix of video channels in small windows. In a mosaic, the user uses a remote control to move the cursor from one small window to another. To select a channel, the user must place the cursor on the small window displaying the desired video channel, then select by pressing for example an "OK" button on the remote control. According to the invention, the small window expands to occupy the entire screen.

 Another transition mode is such that for the predetermined duration, the second TV transmission video channel has a size identical to that of the first TV transmission video channel and a total transparency so that this second TV transmission video channel is first invisible; then the transparency of the two TV transmission video channels is inversely varied so that the second TV transmission video channel completely replaces the first TV transmission video channel on the display screen.

According to an advantageous characteristic of the invention, the video transmission channels TV, after decoding and before combination, undergo a 3D projection by means of a graphics processing unit arranged in each treatment route. In this case, the two television channels between which a transition must be made are three-dimensional video. To do this, it is possible to insert into the processing channel a graphic processing unit or graphics processor unit (GPU) specially dedicated to producing, for example, transitions using 3D projections.

 Preferably, the step of simultaneous processing and decoding of a first and a second TV transmission video sources also generates at least a first audio signal and a second audio signal respectively, and in response to a setpoint to move from displaying the first TV transmission video channel on the display of the second TV transmission video channel, mixing the first and second audio signals for a predetermined time in a mixer; this mixture for generating at least one audio transition signal between the first audio signal and the second audio signal.

 It is also possible to provide sound transitions such that during the predetermined duration, the mixer can gradually reduce the first audio signal while gradually increasing the second audio signal. These transitions can be accompanied by a stereo mix such that during the predetermined duration, the first audio signal is sent to a first audio output (the right channel for example), and the second audio signal is sent to a second audio output ( the left channel for example), and the first audio signal is progressively disappearing while gradually increasing the second audio signal

 Advantageously, to modify the level of the first and second audio signals, an automatic gain control is performed after decoding and before mixing.

 Furthermore, a digital-to-analog conversion of the transition video signal can be performed before sending to an analog display screen. In the same manner, a digital-to-analog conversion of the first audio signal and the second audio signal is carried out when the sound diffusion means are able to receive analog audio signals.

According to an advantageous embodiment of the invention, in the absence of instructions, the first video transmission channel TV is processed by the first processing channel then displayed on the display screen without transition effect; the second TV transmission video channel is a TV transmission video channel preceding or following said first TV transmission video channel, and this second TV transmission video channel is processed simultaneously by the second processing channel but not by the combiner.

 This embodiment is particularly applicable during incremental navigation or by successive channels by means of a remote control. This is for example the case when a user scans the channels one after the other by stopping a little moment on each channel to see if the current program is interested or not. Indeed, this mode according to the invention makes it possible to prepare the processing and the decoding of the following chain even before the user has selected it. Thus, as soon as the next channel is selected, the combination of the video channels is activated, which enables the transition to be made instantaneously.

 According to another aspect of the invention, there is provided a TV receiving device or "Set Top Box" for performing real-time transition effects between a first and a second TV transmission video channel on a display screen; this device comprising:

 first and second processing channels for simultaneously processing and decoding said first and second TV transmission video channels respectively,

 a combiner for digitally combining for a predetermined duration the first and second TV transmission video channels, in response to a set point to switch from the display of the first TV transmission video channel to the display of the second transmission video channel. TV; this combination of generating a transition video signal displaying a gradual disappearance of the first TV transmission video channel and a progressive appearance of the second TV transmission video channel.

Each processing channel may include a tuner, a demodulator, a demultiplexer, a video decoder and an audio decoder. The graphics processing unit is preferably arranged between the video decoder and the combiner. The automatic gain control is arranged between the audio decoder and the mixer. Other advantages and characteristics of the invention will appear on examining the detailed description of a non-limiting embodiment, and the appended drawings, in which:

 Figure 1 is a general view of a Set Top Box connected to a television;

 FIG. 2 is a general view of two video channel processing channels according to the invention;

 Figure 3 comprises three views of a television screen illustrating a "book" zapping effect;

 Figure 4 comprises three views of a television screen illustrating a zapping effect of type "notepad";

 Figure 5 comprises four views of a television screen illustrating a zapping effect of "zoom" type;

 Figure 6 shows four views of a television screen illustrating a "mosaic" type zapping effect;

 Figure 7 shows three views of a television screen illustrating a "transparent" zapping effect;

 FIG. 8 comprises three views of a television screen illustrating a "3D" type zapping effect;

 Fig. 9 is a view illustrating a linear audio transition; and

Fig. 10 is a view illustrating a non-linear audio transition.

In Figure 1 we see a Set Top Box 1 equipped with hardware and software to implement the method according to the invention. It is connected to a television 2 which is able to render audio / video signals of TV transmission in the form of television channels. The user controls the Set Top Box 1 by means of a remote control 3 with infrared. The channels displayed on the TV 2 are transited via the Set Top Box and can come from any type of transmission media such as IPTV (ADSL for "Asymmetric Digital Subscriber Line" via the telephone line or fiber optic), the Satellite by means of a dish, Cable or digital terrestrial television by wireless communication.

It is also possible to envisage the method according to the invention implemented not in a Set Top Box but in an integrated manner within a television set or a player such as a DVD recorder connected to a television set. . The method according to the invention involves two digital processing channels as illustrated in FIG. 2. Each processing channel makes it possible to process and decode a TV transmission video source SRC1 or SRC2 so as to obtain two TV transmission channels which can be respectively displayed on a TV. The two sources SRC1 and SRC2 are preferably the same source coming for example from the same radio antenna in the case of reception of digital terrestrial television channels. Each treatment channel includes a tuner:

 - TUN1 to select a first TV channel that is being displayed on the TV and,

 TUN2 for selecting a second television channel to be combined with the first television channel to effect a transition or zapping effect according to the invention; the roles are reversed with each change of channel.

 The second television channel is selected by the tuner TUN2 as soon as the user actuates his remote control 3 so as to generate a setpoint to the Set Top Box 1. This setpoint is received via an infrared receiver and then interpreted by a microprocessor CPU which has for function to manage the different electronic components and software of the Set Top Box. In this case, it can be said that the second processing channel of the source SRC2 is activated only from a setpoint of the user.

But one can also provide a specific preprocessing mode where the second channel is active and continuously processes a string following or preceding the current string, but without activating the combination operation. This specific pretreatment mode can be implemented when the user scrolls the channels by means of his remote control. It allows to quickly activate the operation of transition between two consecutive chains. For example, if the user is looking at the channel named "C", the second processing channel can already process the chain "D" chronologically following the chain "C" without however activate the transition. Only when the user has actually selected the channel "D" by means of his remote control will the transition be activated, that is to say the combination of the two channels so as to achieve a zapping effect according to the invention. Of course, preprocessing can be done with the "B" chain that precedes chronologically the chain "C" being broadcast. After transition, the channel "D" of the second channel is broadcast live on the television, and the pretreatment is then performed on the first processing channel. On the other hand, if the user selects a different channel from "D", the second processing channel switches to this new selected channel. The transition will be less instantaneous than in the case where the preprocessing channel is then the channel actually selected by the user.

 Each processing channel comprises a demodulator DMD1 and DMD2 receiving a modulated carrier frequency from TUN1 and TUN2 respectively, and restoring a demodulated signal representative of the TV transmission channel selected in TUN 1 and TUN2 respectively. A DMX1 demultiplexer DMX2 is then distinguished to reproduce on the one hand a video signal and on the other hand an audio signal. A video decoder DEC VI, DEC V2 performs a decoding for example from an MPEG2 or MPEG4 coding to a basic video signal which is the TV transmission channel readable by the television. As far as the audio signal is concerned, a decoder DEC A1, DEC A2 is used to restore the acceptable audio signal for the television.

 The two processing channels can be implemented by a chipset or "chipset" capable of performing a double video and audio decoding. This "chipset" has two video decoders and two audio decoders operating simultaneously. A video / audio decoder assembly is used to decode the first TV transmission channel, and at the same time a second video / audio decoder set is used to decode the second TV transmission channel. The "chipset" may include many DSP ("Digital Signal Processor") processors specializing in signal processing, for example four DSPs (developing for example 500MFLOPS each) for video and two for audio.

 The CPU microprocessor used is adapted to support very high processing rates. It is a powerful microprocessor (developing eg 2GFLOPS if it was to handle all the digital processing alone) able to perform all or part of video and audio decoding.

According to one embodiment, the two decoders DEC VI and DEC V2 feed a combiner 4 which integrates several algorithms; each algorithm being associated with a transition. Transitions can be preprogrammed so that they are used one after the other. The user may also be able to select the desired type of transition. The combiner generates an accessible digital television signal, in particular via an HDMI connector or the like. The combiner can also power a digital video encoder (DENC) 5 which converts the received digital video signal into a high quality analog signal compatible with TV standards. It is thus possible to have video signals in the following formats: Y / C, RGB, YUV or other.

 As will be seen below, when a transition between two TV channels involves 3D projections, the direct link between each decoder DEC VI, DEC V2 and the combiner 4 is replaced by a graphics processor GPU1, GPU2 which has the function to model in three dimensions each TV transmission video channel coming from decoder DEC VI and DEC V2. The transition within the combiner 4 is then made from the 3D video signals rather than 2D video signals.

 Moreover, the two audio decoders DEC A1 and DEC A2 feed an audio mixer 6 via an automatic gain control AGC1 and AGC2, respectively. These automatic gain controls allow the amplitude of the audio signal to be modulated according to the desired transition. Preferably, the video transition is correlated to the audio transition. We can consider the same audio transition for different video transitions. The mixer 6 generates a digital audio signal of the S / PDIF type, for example, which can be converted into a stereo type analog audio signal by means of a digital-to-analog audio converter 7.

 In Figures 3 to 8 there are several transition examples to go from a first channel being viewed to a second channel.

Figure 3 illustrates a "book" transition. When the user zaps, the video image of the second channel is first processed by one of the two processing channels, then displayed on a window of a few pixels according to the horizontal, and all available pixels according to the vertical. This window displays the video of the second channel in a format compressed according to the horizontal. This window is placed on the right (or left) of the TV screen then grows to gradually replace the video image of the first channel (which is compressed according to the horizontal). The transition is done even while the video images are of high quality and animated. It's not about frozen images. The development of the transition within the combiner 4 and the display of moving video images are done in real time.

 Assuming that the size of the TV screen is L * H pixels, the video image of the first channel being broadcast will initially use (Ln) * H part of the screen while the window displaying the video image of the second string will use n * H pixels, n is a variable that starts with a few units to finally reach the value of L. In order to keep a smooth effect, n can be increased by one step each frame of displayed image. For example, a transition between two 1280x720 HD video images using a 32-pixel pitch will result in 40 frames, less than 2 seconds (at 25 frames / sec) for a transition.

 This embodiment can also be implemented with a window occupying the full width (horizontal) of the television screen, its height (vertical) progressing from a few pixels to the maximum height. An example is shown in Figure 4. In Figure 5, the embedded window is finite size in height and vertical. The transition is to stretch the image vertically and horizontally until it reaches the maximum size. This window can be embedded anywhere on the screen. In the examples just described, the video image is embedded whole but "flattened" way: the transition of stretching or lengthening to its standard high definition display size. A variant may be the scrolling of the video image of the second channel gradually "above" the video image of the first channel. In this case one discovers little by little the video image of the second channel which is of high quality without compression. There is no zoom effect. The scrolling can be done according to different trajectories: from left to right, from right to left, from top to bottom, from bottom to top, from one corner to another, or any random trajectory resulting in a complete recovery of the 'screen.

A particular case of the transition as shown in Figure 5 is illustrated in Figure 6 where the user zaps from a mosaic of strings. In this case, the window is embedded in place of the video image (thumbnail) representing the channel selected by the user. The location of the thumbnail is known by the application that manages the video mosaic and which knows where the focus is on the video thumbnail On the request for connection to the selected channel, one connects to said selected channel, decodes it and displays the decoded video, resized to the size of a thumbnail instead of the corresponding video thumbnail. Then the magnification effect of the video can take place.

 This image is then stretched to the size of the screen.

FIG. 7 shows an embodiment where the video image of the second channel gradually appears on the screen, replacing the image of the first channel: the transparency effect is used by displaying the two video images of same size across the screen with full transparency for the second video frame and zero transparency for the first video frame, and then gradually reversing the transparency level of the first video frame.

 In Figure 8 is shown a transition from 3D video images. We go from one channel to another as if we were turning a page of a book.

 In addition to the above, the audio signal is also transitioned. During the transition, for example, the audio signal of the first channel can be attenuated at the same time as that of the second channel is increased. The audio transition lasts the same time as the video transition. AGC1 and AGC2 are used to vary the amplitude of the sound signals of the two chains in transition. We can consider a linear transition as in Figure 9 or nonlinear in Figure 10; the solid line representing the audio signal of the first string, the dotted line representing the audio signal of the second string.

 Another interesting effect is to make a stereo transition where the audio signal of the first channel is for example broadcast on a left speaker while the audio signal of the second channel is broadcast on a right speaker, or vice versa. Such an effect reinforces the impression of movement of the video transition.

 Of course, the invention is not limited to the examples that have just been described and many adjustments can be made to these examples without departing from the scope of the invention.

Claims

A method for realizing transition effects in real time between a first and a second TV transmission video channel on a display screen, wherein:

 simultaneously processing and decoding first and second TV transmission video sources in a first and a second processing channel respectively so as to generate said first and second TV transmission video channels,

 in response to a command to switch from the current display of the first TV transmission video channel to the display of the second TV transmission video channel, the first and second TV transmission video channels are digitally combined for a predetermined duration; thus decoded in a combiner; this combination of generating a transition video signal displaying a gradual disappearance of the first TV transmission video channel and a progressive appearance of the second TV transmission video channel.

2. Method according to claim 1, characterized in that for the predetermined duration, the display screen is divided into two parts respectively displaying the first and second TV transmission video channels, then the size of the second video channel is progressively enlarged. while proportionally reducing the size of the first TV transmission video channel until the second TV transmission video channel occupies the entire display screen.

3. Method according to claim 2, characterized in that splits the display screen in the vertical or horizontal.

4. Method according to claim 1, characterized in that for the predetermined duration, the second TV transmission video channel appears on a corner of the display screen and then gradually and completely replace the first TV transmission video channel by a progression along the vertical and horizontal axes.

5. Method according to claim 1, characterized in that for the predetermined duration, the second TV transmission video channel appears on a window of predetermined size on the display screen and then gradually and completely replace the first transmission video channel. TV by a progression along the vertical and horizontal axes.

6. Method according to claim 1, characterized in that for the predetermined duration, the second TV transmission video channel has a size identical to that of the first TV transmission video channel and a total transparency so that this second transmission video channel. TV is first invisible, then inversely varies the transparency of the two TV transmission video channels so that the second TV transmission video channel completely replaces on the display screen the first TV transmission video channel.

7. Method according to any one of the preceding claims, characterized in that the video transmission channels TV, after decoding and before combination, undergo a 3D projection by means of a graphics processing unit arranged in each processing channel.

8. Method according to any one of the preceding claims, characterized in that performs a digital-to-analog conversion of the transition video signal before sending to an analog display screen.

A method as claimed in any one of the preceding claims, characterized in that the simultaneous processing and decoding step of a first and second TV transmission video source also generates at least a first audio signal and a second signal. audio respectively, and

in response to a command to change from the display of the first TV transmission video channel to the display of the second TV transmission video channel, the first and second audio signals are mixed for a predetermined duration in a mixer; this mixture to generate at least a transition audio signal between the first audio signal and the second audio signal.

10. The method of claim 9, characterized in that for the predetermined duration, the mixer allows to gradually reduce the first audio signal while gradually increasing the second audio signal.

11. Method according to claim 9, characterized in that during the predetermined duration, the first audio signal is sent to a first audio output, and the second audio signal is sent to a second audio output, and the first signal is progressively disappeared. audio while gradually increasing the second audio signal

12. Method according to any one of claims 9 to 11, characterized in that for modifying the level of the first and second audio signals, an automatic gain control is performed after decoding and before mixing.

13. Method according to any one of claims 9 to 12, characterized in that performs a digital-to-analog conversion of the first audio signal and the second audio signal.

14. Method according to any one of the preceding claims, characterized in that in the absence of setpoint, the first TV transmission video channel is processed by the first processing channel and then displayed on the display screen without transition effect. ; the second TV transmission video channel is a TV transmission video channel preceding or following said first TV transmission video channel, and this second TV transmission video channel is processed simultaneously by the second processing channel but not by the combiner.

15. TV receiving device for realizing transition effects in real time between a first and a second TV transmission video channel on a display screen; this device comprising: first and second processing channels for simultaneously processing and decoding said first and second TV transmission video channels respectively,

 a combiner for digitally combining for a predetermined duration the first and second TV transmission video channels, in response to a set point to switch from the display of the first TV transmission video channel to the display of the second transmission video channel. TV; this combination of generating a transition video signal displaying a gradual disappearance of the first TV transmission video channel and a progressive appearance of the second TV transmission video channel.

16. Device according to claim 15, characterized in that each processing channel comprises a tuner, a demodulator, a demultiplexer, a video decoder and an audio decoder.

17. Device according to claim 15 or 16, characterized in that a graphics processing unit is arranged between the video decoder and the combiner.

18. Device according to any one of claims 15-17, characterized in that an automatic gain control is disposed between the audio decoder and the mixer.