Patent Publication Number: US-2011064391-A1

Title: Video-audio playback apparatus

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2009-213990, filed on Sep. 16, 2009; the entire contents of which are incorporated herein by reference. 
     FIELD 
     Embodiments described herein relate generally to a video-audio playback apparatus. 
     BACKGROUND 
     When a conventional video-audio playback apparatus is used to reproduce videos, the display output of smooth motion video is achieved by decoding the entire compressed video stream inputted into the video-audio playback apparatus. 
     However, this method must keep the video-decoding processor always running even for those videos that the viewers pay no attention or that the viewers are less likely to consider important, such as videos with few changes in their contents and videos with little motion, so that the processor has to be used frequently. In addition, the backlight used for the displaying apparatus such as a liquid-crystal display has to be always engaged while the apparatus is being used by a viewer, which brings about a problem of large electric-power consumption. 
     Some existing displaying apparatuses cut the electric-power consumption by turning off, or reducing the light of, the backlights of their liquid-crystal displays while playback contents without videos. However, this method is adopted only when the contents that the apparatuses are playback are those without videos. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a diagram illustrating the system configuration of a video-audio playback apparatus according to an embodiment. 
         FIG. 2  is a configuration diagram illustrating in detail the flow of data according to the embodiment. 
         FIG. 3  is an operational flowchart according to the embodiment. 
         FIG. 4  is a conceptual diagram of audio data according to the embodiment. 
         FIG. 5  is an operational flowchart according to the embodiment. 
         FIG. 6  is a conceptual diagram illustrating the relationship between the profile and the flag value in operational flow of the embodiment 
         FIG. 7  is an operational flowchart according to the embodiment. 
         FIG. 8  is an operational flowchart according to the embodiment. 
         FIG. 9  is a conceptual diagram illustrating the relationship among the profile, the flag value, the waveform of the output audio data, the luminance with which a liquid-crystal-panel backlight is lighted, the compressed video data, and the state of compressed-video-data decoding procedure, according to the embodiment. 
     
    
    
     DETAILED DESCRIPTION 
     According to one embodiment, a video-audio playback apparatus including: a tuner configured to receive compressed video data and compressed audio data of a program; a compressed-audio-data decoding portion configured to decode the compressed audio data of the program sent from the tuner and thereby to generate audio data; an audio data processing portion configured to compare a sound volume of the audio data for an arbitrarily-determined period with a threshold; and a compressed-video-data decoding portion configured to perform first decoding processing on the compressed video data for the arbitrarily-determined period synchronized with the audio data for the arbitrarily-determined period when the sound volume of the audio data for the arbitrarily-determined period is equal to or lower than the threshold, the first decoding processing being according to the compressed video data. 
     An embodiment will be described below by referring to the drawings. Identical or equivalent portions that appear in various drawings are denoted by the same reference numerals and the description of those portions will not be repeated. 
     Embodiment 
     Firstly, the configuration of a video-audio playback apparatus  10  of an embodiment of the invention will be described by referring to  FIG. 1 . 
     The video-audio playback apparatus  10  of this embodiment includes: a tuner  11  configured to receive data of TV programs (streams of programs) via an antenna  1 ; an input-data processing processor  16  configured to receive, when necessary, inputs of compressed audio data and compressed video data from the tuner  11 , a video-input terminal  12 , and an audio-input terminal  13 , and then to decode these compressed audio data and compressed video data; a remote-control signal receiver  14  configured to receive signals produced when the viewer operates the remote control to perform such operations as making the video-audio playback apparatus  10  start or stop playback; an operation portion  15  through which the viewer directly performs such operations as making the video-audio playback apparatus  10  start or stop the playback; a memory portion  19  configured to store video data and audio data to be outputted to a video-displaying liquid-crystal panel  24 , a video-output terminal  25 , a speaker  26 , an audio-output terminal  27 , and the like; a video-data processing processor  17  and an audio-data processing processor  18  configured to perform various kinds of processing, which will be described later, on the video data and on the audio data stored in the memory portion  19 ; a DAC-and-amplifier portion  20  configured to perform D/A conversion of, or to amplify, the audio data from the processing processor  18 , and to output the resultant audio data to the speaker  26 ; a video-displaying-panel backlight controlling portion  21  configured to control the lighting state of a liquid-crystal-panel backlight  23 ; a video-displaying backend processing processor  22  configured to perform processing of filtering for image-quality improvement to enhance the image quality, or the like processing; and a controlling host processor  100  configured to control the above-mentioned processors, the video-displaying-panel backlight controlling portion  21 , and the like. 
     Subsequently, the configuration, the basic operations, and the flow of the data of this embodiment will be described by referring to  FIG. 2 . 
     The video-audio playback apparatus  10  is capable of receiving the input of compressed video data from either the antenna  1  or the video-input terminal  12 , and of receiving the input of compressed audio data from either the antenna  1  or the audio-input terminal  13 . The compressed video data and the compressed audio data thus inputted are then inputted into compressed-video decoding procedure  16   a  and compressed-audio decoding procedure  16   b , respectively, of the input-data processing processor  16 . 
     The compressed-video decoding procedure  16   a  generates video data through decoding processing, and then stores the video data in an output-video-data storing area  19   a  of the memory portion  19 . In addition, the compressed-audio decoding procedure  16   b  generates audio data through decoding processing, and then stores the audio data in an output-audio-data storing area  19   b  of the memory portion  19 . 
     The video data stored in the memory portion  19  are acquired by video-displaying backend processing procedure  22   a  of the video-displaying backend processing processor  22  so as to be subjected to various kinds of video processing which will be described later, and then are displayed on the video-displaying liquid-crystal panel  24 . 
     In addition, the audio data stored in the memory portion  19  are acquired by audio-data processing procedure  18   a  of the audio processing processor  18  so as to be subjected to various kinds of audio processing which will be described later, and then are outputted as sound from the speaker  26  after being passed through the DAC/amplifier portion  20 . 
     The compressed video data include I-Picture (Intra-Picture), P-Picture (Predictive-Picture), and B-Picture (Bi-directionally predictive-picture); and the data of any of the I-, P-, and B-Pictures are used for the video decoding. The I-Picture refers to the data which have no dependent relations with other frame images, and therefore complete frame images can be restored by decoding the data of I-Picture alone. The P-Picture refers to the data encoded with data-differential information predicted from foregoing frame-image data. The B-Picture refers to frame-image data coded with foregoing and succeeding references and data encoded with data-differential information predicted from both the frame received previously and the frame to be received. None of the P-Picture and the B-Picture can be decoded alone, so that no videos can be restored completely as expected from each of them only. To restore the video completely, it is necessary to start the decoding from the most immediate one of the foregoing I-Pictures. 
     Subsequently, detailed operational flow of the audio processing (i.e., decoding and profile generation) of this embodiment will be described by referring to the diagram of the detailed system configuration shown in  FIG. 2 , the flowchart shown in  FIG. 3 , and the conceptual diagram of the audio data shown in  FIG. 4 . 
     Firstly at step S 1 , the compressed-audio-data decoding procedure  16   b  of the input-data processing processor  16  acquires compressed audio data from the tuner  11 . The compressed audio data acquired here have a period of 21.3 ms, for example. Then at step S 2 , the compressed-audio-data decoding procedure  16   b  generates audio data by decoding the acquired compressed audio data, and stores the audio data in the output-audio-data storing area  19   b . Then at step S 3 , the audio-data processing procedure  18   a  acquires the audio data from the output-audio-data storing area  19   b , and calculates the average value of sound volume level thereof. Specifically, the audio-data processing procedure  18   a  calculates the average value of sound volume level for the audio data for a period of 21.3 ms, for example. 
     In this operational flow, by repeatedly calculating the average value of sound volume level for an arbitrarily-determined period of time (e.g., 5 seconds), a profile is generated for each of the arbitrarily-determined periods of time. Hereafter, the arbitrarily-determined period of time will be referred to as the profile generating period. In addition, in this embodiment, the compressed audio data are assumed to be received a profile generating period (e.g., 5 seconds) before the timing of outputting the sound and the video. Then, various kinds of processing, which will be described in detail below, are firstly performed on the compressed audio data, and then by taking the results into account, the controlling of the output of sounds and videos as well as the liquid-crystal-panel backlight  23  is performed. 
     Then at step S 4 , the audio-data processing procedure  18   a  determines whether the profile generating period has or has not elapsed. If a profile generating period has not elapsed yet, at step S 5 , the audio-data processing procedure  18   a  calculates an average value of the average value of the sound volume level for the audio data decoded this time and the average value for the audio data decoded before this time, and stores the average value thus calculated in a temporary-profile storing area  18   b  as a temporary profile. Here, if there are no audio data decoded previously, only the average value of the sound volume level for the audio data decoded this time is stored as a temporary profile in the temporary-profile storing area  18   b . Then again at step S 1 , the next compressed audio data are acquired, and the subsequent steps S 2  to S 5  are repeated until the profile generating period has elapsed. 
     If the profile generating period has elapsed, the audio-data processing procedure  18   a  stores the temporary profiles accumulated until this time in the temporary-profile storing area  18   b , that is, the temporary profiles for the profile generating period, in a profile storing area  18   c  as a collective profile at step S 6 . Then, the average value of sound volume level for the audio data acquired this time is stored as a new temporary profile in the temporary-profile storing area  18   b.    
     Then at step S 7 , if there are any profiles accumulated until the previous time, the audio-data processing procedure  18   a  calculates the average value of sound volume level for the program by obtaining the average value of the profile stored this time and the profiles accumulated until the previous time. Then at step S 8 , the audio-data processing procedure  18   a  stores the average value of sound volume level for the program, the audio data, and the profile stored in the profile storing area  18   c  in an output-audio-data storing area  19   c . These three kinds of information are updated incessantly while the program is being viewed. 
     If, for example, the profile generating period is five seconds, the profile and the average value of sound volume level for the program can be defined by the following Formulas 1 and 2.  FIG. 4  shows a diagram of these concepts. 
       Profile=Average value of sound volume level for a period of 5 seconds=Σ{Average values of sound volume level for temporary profiles (e.g., for every 21.3 ms)}/Number of compressed audio frames contained in a period of 5 seconds  (Formula 1)
 
       Average value of sound volume level for the program=Average value of profiles accumulated since the start of receiving the program=Σ{Profiles accumulated since the start of receiving the program}/Number of profiles accumulated since the start of receiving the program  (Formula 2)
 
     Then at step S 9 , the controlling host processor  100  determines whether the program has or has not ended. If the program has already ended, the controlling host processor  100  makes the audio-data processing procedure  18   a  finish the audio processing (decoding and profile generation). If the program has not ended yet, the steps from step S 1  are repeated until the program ends. 
     Note that the end of a program is recognized by, for example, making the controlling host processor  100  determine whether there is or is not a signal representing the end of the program, which is attached to the data of the program, such as the compressed video data or the compressed audio data. 
     Alternatively, the determination at step S 9  may be done not only by recognizing the end of the program but also by the viewer&#39;s operation to stop the playback of the program by the video-audio playback apparatus  10 . In this case, the signal of the viewer&#39;s operation to stop playback is inputted by either the remote-control signal receiver  14  or the operation portion  15  to notify the controlling host processor  100 . 
     Subsequently, detailed operational flow of the processing to determine the attention level of the viewer will be described by referring to  FIG. 5 . The attention level is determined by checking the three kinds of information stored in the output-audio-data storing area  19   c.    
     Firstly at step S 20 , the profile stored recently and the average value of sound volume level for the profiles accumulated since the start of receiving the program are acquired from the output-audio-data storing area  19   c . The average value of sound volume level for the profiles accumulated since the start of receiving the program is used as a threshold. 
     Then at step S 21 , the threshold and the profile are compared with each other. If the profile is higher than the threshold, the flag value to determine the attention level (hereafter, simply referred to as the flag value) in a flag storing area  18   d  is set, for example, at  2  at step S 22 , and then at step S 25 , whether the program has or has not ended is determined. If the program has already ended, the audio processing (determination of attention level) is finished. If the program has not ended yet, the process at step S 20  is performed again. Note that at the shipment of the video-audio playback apparatus from the factory, the recording flag and the playback flag do not have to be set. 
     If, on the other hand, the determination at step S 21  concludes that the profile is equal to or lower than the threshold, it is determined at step S 23  whether each of the consecutive multiple profiles (e.g., two; hereafter referred to as the consecutive number) including the profile immediately before this one is or is equal to or lower than the threshold. If each of these profiles is equal to or lower than the threshold, −1 is added to the flag value at step S 24 , and whether the program has or has not ended is determined at step S 25 . If the program has already ended, this audio processing (attention-level determination) is finished. If the program has not ended yet, the process at step S 20  is performed again. 
     On the other hand, if each of the above-mentioned consecutive profiles is neither equal to nor lower than the threshold, no further arithmetic operation is performed on the flag value, and whether the program has or has not ended is determined at step S 25 . If the program has already ended, this audio processing (attention-level determination) is finished. If, on the other hand, the program has not ended yet, the process at step S 20  is performed again. 
     The steps described above are repeated until the program ends. 
     Note that the value at which the flag value is set when the attention level is determined as being high is not necessarily 2. In addition, the value used in the arithmetic operation to be performed when the attention level is determined as being low is not necessarily −1. These values may be set appropriately. In addition, any value can be set as the initial value of the flag value. 
     Subsequently, a conceptual diagram illustrating the relationship between the profiles of the above-described operational flow and the flag values is shown in  FIG. 6 . Note that, in  FIG. 6 , the consecutive number at step S 23  is assumed to be two. 
     Firstly, since the target profile for the attention-level determination at a time T 1  is a profile P 1  that is higher than the threshold, the flag value is set at 2. Then, the target profile for the attention-level determination at a time T 2  is a profile P 2  that is lower than the threshold, but the profile immediately before the profile P 2  is the profile P 1 , so that the flag value is kept at 2. In addition, the target profile for the attention-level determination at a time T 3  is also a profile P 2 , but the profile preceding the one that is immediately before the profile P 2  at the time T 3  is the profile P 1 , so that the flag value is kept at 2. 
     Then, since the target profile for the attention-level determination at a time T 4  is a profile P 2 , and both of the two consecutive profiles including the profile immediately before the one at the time T 4  are profiles P 2 , −1 is added to the flag value. As a result, the flag value becomes 1. In addition, since the target profile for the attention-level determination at a time T 5  is also a profile P 2 , −1 is again added to the flag value, so that the flag value becomes 0. The same applies to the case of a time T 6 , and therefore the flag value becomes −1. 
     Then, since the target profile for the attention-level determination at a time T 7  is a profile P 1 , the flag value is set at 2. In addition, since the target profile for the attention-level determination at a time T 8  is also a profile P 1 , the flag value is kept at 2. 
     Suppose, for example, that a time period with a flag value of 1 or larger is a time period with a high attention level. Having a flag value of 1 or larger, a time period from T 1  to T 4  and a time period from T 7  to T 8  have a high attention level. In contrast, having a flag value smaller than 1, a time period from T 5  to T 6  have a low attention level. Note that the flag value with which a time period is determined as having a high attention level is not necessarily 1 or higher. Rather, the flag value may be set appropriately. 
     Subsequently, a detailed operational flow of video processing performed after a flag value is set in the above-described operation will be described by referring to  FIGS. 7 and 8 . 
     Firstly at step S 30 , the input-data processing processor  16  acquires compressed video data from the tuner  11  and passes the acquired compressed video data to the compressed-video-data decoding procedure  16   a . Then at step S 31 , the controlling host processor  100  checks the flag value in the flag storing area  18   d . If the flag value is one or larger, then at step S 32 , the controlling host processor  100  makes the compressed-video-data decoding procedure  16   a  decode all of the I/P/B-Pictures of the compressed video data acquired at step S 30 . Then at step S 33 , the controlling host processor  100  makes the video-displaying-panel backlight controlling portion  21  perform control so that the liquid-crystal-panel backlight  23  may be lighted with an ordinary luminance. The ordinary luminance mentioned above is from 450 to 550 cd/m 2  (candela per square meter). 
     Then at step S 34 , the compressed-video decoding procedure  16   a  stores the video data decoded at step S 32  in the output-video-data storing area  19   a . Then at step S 35 , the controlling host processor  100  determines whether the program has or has not ended. If the program has already ended, this video processing is finished. If the program has not ended yet, the process at step S 30  is performed again where the input-data processing processor  16  acquires the next compressed video data. 
     On the other hand, if the flag value is neither equal to 1 nor larger than 1 at step S 31 , then at step S 36 , the controlling host processor  100  makes the compressed-video-data decoding procedure  16   a  decode the compressed video data acquired at step S 30  in accordance with the decoding method based on the compressed video data. Details of the procedure for checking the decoding method based on the compressed video data will be described later by referring to  FIG. 8 . Then at step S 37 , the controlling host processor  100  makes video-displaying-panel backlight controlling portion  21  control the liquid-crystal-panel backlight  23  so that the liquid-crystal-panel backlight  23  can be lighted with a luminance that is lower than the ordinary one. Then, like the case described above, the decoded video data are stored at step S 34 , and then at step S 35 , whether the program has or has not ended is determined. 
     Subsequently, details of the procedure for checking the decoding method at step S 36  mentioned above will be described by referring to  FIG. 8 . 
     Firstly, the compressed-video-data decoding procedure  16   a  counts, at step S 40 , how many I/P/B-Pictures of compressed video data have arrived, and then determines, at step S 41 , whether a video-picture checking period (e.g., 5 seconds) has or has not elapsed. The video-picture checking period mentioned here has the same length as the above-described profile generating period (e.g., 5 seconds), and the compressed video data of the video-picture checking period are data synchronized with the compressed audio data of the corresponding profile generating period. 
     If the determination at step S 41  concludes that a video-picture checking period has elapsed, then at step S 42 , the compressed-video-data decoding procedure  16   a  determines whether I-Picture is or is not included in the compressed video data. If I-Picture is included, then at step S 43 , the compressed-video-data decoding procedure  16   a  determines whether I-Picture is or is not included in the compressed video data of a video-picture checking period that is immediately before the above-mentioned video-picture checking period (hereafter, referred to as the previous video-picture checking period). If I-Picture is included also in the compressed video data of the previous video-picture checking period, that is, I-Picture is included in the compressed video data of the two consecutive video-picture checking periods, then at step S 44 , the compressed-video-data decoding procedure  16   a  decodes only the I-Picture. This method will be referred to as the decoding method  1 . Then at step S 45 , the compressed-video-data decoding procedure  16   a  stores, in a counting-result storing area  16   c , the results of counting the I/P/B-Pictures in the video-picture checking period, and then the decoding based on the compressed video data is finished. Note that the counting-result storing area may be provided in the memory portion  19  instead. 
     If, on the other hand, the determination at step S 42  concludes that no I-Picture is included, then at step S 46 , whether I-Picture is or is not included in the compressed video data of the previous video-picture checking period. If the determination at step  46  concludes that I-Picture is included, or if the determination at step S 42  concludes that I-Picture is included but the determination at step S 43  concludes that no I-Picture is included in the compressed video data of the previous video-picture checking period, that is, if I-Picture is not included in the compressed video data of both of the two consecutive video-picture checking periods, then at step S 47 , either I-Picture or the P-Picture is decoded. To put it differently, if I-Picture is included, the I-Picture is decoded, but if no I-Picture is included, P-Picture is decoded instead. This will be referred to as the decoding method  2 . Then at step S 45 , as in the above-described case, the results of counting the I/P/B-Pictures in the video-picture checking period is stored in the counting-result storing area  16   c , and then the decoding based on the compressed video data is finished. 
     If the determination at step S 46  concludes that no I-Picture is included in the compressed video data of the previous video-picture checking period, only the P-Picture is decoded at step S 47 . This will be referred to as the decoding method  3 . Then at step S 45 , as in the above-described case, the results of counting the I/P/B-Pictures in the video-picture checking period is stored in the counting-result storing area  16   c , and then the decoding based on the compressed video data is finished. 
     Subsequently,  FIG. 9  shows the relationship among the profile, the flag value, the waveform of outputted audio data, the luminance of lighting liquid-crystal-panel backlight  23 , the compressed video data, and the state of the compressed-video-data decoding procedure  16   a . In  FIG. 9 , the initial value of the flag value is assumed to be zero. 
     Since, as has been described earlier, the compressed audio data are received a profile generating period (e.g., 5 seconds) before the timing at which the sound and the video are outputted, the receiving of the compressed audio data starts at a time t 1  and the generation of a profile also starts at the time t 1 . 
     Since the profiles for a period from the time t 1  to a time t 2 , a period from the time t 2  to a time t 3 , and a period from the time t 3  to a time t 4  are profiles P 2 , their corresponding flag values, whose initial value is zero, are 0, −1, and −2, respectively. Note that the consecutive number at step S 23  of  FIG. 5  is assumed to be one. 
     Then, on the basis of these flag values, the luminance of the liquid-crystal-panel backlight  23  is lowered in the periods from the time t 2  to the time t 3 , from the time t 3  to the time t 4 , and from the time t 4  to the time t 5 . 
     Of all these periods, I-Picture is included in the compressed video data of the period from the time t 2  to the time t 3  and the period from the time t 3  to the time t 4 . The compressed video data of the period from the time t 2  to the time t 4  are decoded by the decoding method  1 . Specifically, since the compressed video data of the period from the time t 2  to the time t 3  includes a single I-Picture, the single I-Picture is decoded. In addition, since the compressed video data of the period from the time t 3  to the time t 4  includes two I-Pictures, the two I-Pictures are decoded. Since the compressed video data of the period from the time t 4  to the time t 5  includes no I-Picture, and the compressed video data of the period from the time t 3  to the time t 4  includes I-Pictures, the compressed video data of the period from the time t 4  to the time t 5  are decoded by the decoding method  2 . Specifically, since the compressed video data of the period from the time t 4  to the time t 5  includes a single P-Picture, the single P-Picture is decoded. 
     Then, since the profile for the period from the time t 4  to a time t 5  is a profile P 1 , the corresponding flag value is 2. Then, although the profile for the period from the time t 5  to a time t 6  is a profile P 2 , the flag value for the period from the time t 5  to the time t 6  is kept at 2 since the profile for the period from the time t 4  to the time t 5  is a profile P 1 . Then, since the profile for the subsequent period from the time t 6  to a time t 7  is a profile P 2 , and the consecutive number at step S 23  of  FIG. 5  is one, the flag value for the period from the time t 6  to the time t 7  is 1. 
     Then, on the basis of these flag values, the luminance of the liquid-crystal-panel backlight  23  is set at the ordinary luminance both in the period from the time t 5  to the time t 6  and in the period from the time t 6  to the time t 7 , and is lowered in the period from the time t 7  to a time t 8 . 
     Since the flag value is 1 for the period from the time t 5  to the time t 6  and for the period from the time t 6  to the time t 7 , all the I/P/B-Pictures of the compressed video data of these periods are decoded. Since the flag value for the period from the time t 7  to the time t 8  is smaller than 1, and neither the compressed video data of the period from the time t 7  to the time t 8  nor the compressed video data of the previous period from the time t 6  to the time t 7  include any I-Picture, the compressed video data of the period from the time t 7  to the time t 8  are decoded by the decoding method  3 . Specifically, the compressed video data of the period from the time t 7  to the time t 8  include two P-Pictures, the two P-Pictures are decoded. From then on, similar processing is successively performed until a time t 15 . 
     According to this embodiment, it is possible to provide a video-audio playback apparatus capable of reducing the electric-power consumption by controlling the video decoding and the liquid-crystal-panel backlight if the viewer&#39;s attention level, which is determined on the basis of the sound volume level, is determined as being low, that is, if the sound volume level is low. In contrast, if the viewer&#39;s attention level is determined as being high, the video and the sound are outputted completely as expected and, simultaneously, the liquid-crystal-panel backlight is controlled so as to restore the ordinary luminance. In addition, since the flag value is calculated by considering the states of the multiple profiles including the profile immediately before the target profile for the sound volume-level determination, the state of the period when the viewer&#39;s attention level is determined as being high can be kept for a while even after the profile drops down below the average sound volume level of the program. Accordingly, the viewer is less likely to miss the scene which comes immediately after the scene with a high attention level and which might still be important to the viewer. 
     Note that the embodiment described above is not the only form of carrying out the invention. 
     For example, to enhance the image quality, the video-displaying backend processing procedure  22   a  of the video-displaying backend processing processor  22  may stop the image-quality improving filtering processing or the like if the flag value is, for example, smaller than 1, and may perform the image-quality improving filtering processing only when the flag value is, for example, equal to or larger than 1. Thereby, the processing to enhance the image quality does not have to be performed all the time, allowing the electric-power consumption to be cut furthermore. 
     In addition, instead of making the compressed-video-data decoding procedure  16   a  change the target picture for the decoding as in the case of the above-described embodiment, the electric-power consumption of the video-data processing processor can be cut by slowing down the system clock speed of the video-data processing processor and/or by thinning out the compressed video data if the flag value is, for example, smaller than 1. 
     In addition, the video-displaying liquid-crystal panel  24  is not the only possible kind of displaying device. A plasma display apparatus or other kinds of displaying device may be used instead. If the displaying device needs no backlight, neither the video-displaying-panel backlight controlling portion  21  nor the liquid-crystal-panel backlight  23  are necessary. 
     In addition, the video-audio playback apparatus  10  shown in  FIG. 1  includes none of the antenna  1 , the audio-input terminal  13 , the video-input terminal  12 , the operation portion  15 , the liquid-crystal-panel backlight  23 , the video-displaying liquid-crystal panel  24 , the video-output terminal  25 , the speaker  26 , and the audio-output terminal  27 , but such a configuration is not the only possible example. Some, or all, of these may be included in the configuration of the video-audio playback apparatus  10 , if necessary. 
     While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel devices and methods described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modification as would fall within the scope and spirit of the inventions.