JP2004040580A - Video playback device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a video playback device capable of smooth fast-forward replay at controllable speed at fast-forward playback of high-efficiency-coded images recorded in a recording medium. <P>SOLUTION: The video playback device includes an N-fold-frequency vertical synchronizing signal generator 18 for outputting an image readout signal; synchronizing signal generators 20, 21 for generating synchronizing signals; an image data expander 12 for reading out a high-efficiency-coded image data from a recording medium 11 and outputting an expanded image data; an image skip section 13 for selecting the image data output from the image data expander 12 at intervals of (N - 1) frames and outputting the selected image data; a buffer 14 for storing the selected image data; a D/A converter 15 for analog-converting the image data; and an image display 16 for displaying the image data. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a video reproducing apparatus for reproducing encoded video data from a recording medium.
[0002]
[Prior art]
MPEG (Moving Picture Experts Group Phase), which is a high-efficiency coding method, is used in each field as an image compression method.
[0003]
FIG. 12 is a configuration diagram showing a conventional video reproducing apparatus described in, for example, Japanese Patent Application Laid-Open No. 2000-331421 (Japanese Patent Application No. 11-135815). 12, reference numeral 110 denotes MPEG data; 112, an MPEG frame structure identifier insertion device; 114, a recording medium; 116, MPEG data with an identifier inserted; 118, an MPEG frame structure identifier detection device; is there.
[0004]
Next, the operation will be described.
The MPEG frame structure identification insertion device 112 records the received MPEG data 110 on the recording medium 114. The MPEG frame structure identification detecting device 118 reproduces the MPEG data 116 recorded on the recording medium 114. Here, the MPEG frame structure identifier insertion device 112 determines each frame structure of the MPEG data 110, incorporates an identifier for identifying each frame structure into a transport packet, and records it on the recording medium 114 as MPEG data 116. When trick-playing the recorded MPEG data 116, the MPEG frame structure identifier detecting device 118 reads the incorporated identifier, and selects and decodes only a transport packet having a frame structure necessary for trick-play.
[0005]
Digital broadcast receivers, DVD hybrid decoders, hard disk recording / reproducing devices, and the like have a function of accumulating programs on a recording medium and performing time-shift viewing with the increase in the capacity of the hard disk device. In the time-shift viewing, a program can be reproduced from any recorded scene while recording a program using the high random accessibility of the disk medium. Digital broadcast receivers, DVD hybrid decoders, hard disk recording / reproducing devices, and the like have a function of accumulating programs on a recording medium and performing time-shift viewing with the increase in the capacity of the hard disk device. The time shift viewing / listening is to play back from an arbitrary recorded scene while recording a program by using a high random access property of a disk medium.
[0006]
In the conventional video reproducing apparatus described in Japanese Patent Laid-Open No. 2000-331421, fast-forward reproduction of video data recorded on a recording medium is realized by, for example, reproducing only an I picture. In many cases, the interval between I-pictures is from several frames to several tens of frames, and when only I-pictures are reproduced, they are displayed as considerably discontinuous images. Also, in BS digital broadcasting, the maximum interval is only defined as 0.5 seconds, so the interval is not constant depending on the stream. Therefore, the fast-forward speed differs depending on the stream.
[0007]
[Problems to be solved by the invention]
Since the conventional video reproducing apparatus is configured as described above, there is a problem that when only an I picture is reproduced, it is displayed as a considerably discontinuous video. There is also a problem that the fast-forward speed is different when the intervals between the streams are not constant.
[0008]
SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and in a fast-forward playback of a high-efficiency coded image recorded on a recording medium, a smooth fast-forward playback is possible, and the fast-forward playback speed is controllable. It is intended to obtain a playback device.
[0009]
[Means for Solving the Problems]
A video reproducing apparatus according to the present invention comprises: a synchronizing signal generating means for generating a predetermined times synchronizing signal having a frequency which is a predetermined times higher than a frequency of a reproduction synchronizing signal at the time of normal reproduction; An image data decompressor for outputting in synchronization with a synchronization signal, and image data output in synchronization with a predetermined multiplication signal are thinned out based on a reproduction synchronization signal during normal reproduction and output to a display for display. Image thinning means.
[0010]
The video reproducing apparatus according to the present invention further has a decoding clock generating means for generating a decoding clock having a frequency which is a predetermined multiple of the frequency at the time of normal reproduction, wherein the decoding clock is input to the image data expanding means, and the image data is expanded. In this means, the compressed image data of the video is expanded at a speed twice the speed of the normal reproduction.
[0011]
The video playback device according to the present invention includes a predetermined-speed playback instruction detection unit that receives a playback speed instruction from a user or the like and outputs an operation instruction for specifying which of a frequency during normal playback and a frequency of a predetermined multiple is to be used. It has more.
[0012]
A video reproducing apparatus according to the present invention comprises: a synchronizing signal generating means for generating a predetermined times synchronizing signal having a frequency which is a predetermined times higher than a frequency of a reproduction synchronizing signal at the time of normal reproduction; Image data expanding means for outputting in synchronization with a synchronization signal.
[0013]
The video playback device according to the present invention is a mode detection unit that determines whether or not the image display unit can display even when the frequency is set to a predetermined multiple of that of the normal playback, selects an operation mode, and outputs a mode notification, Image reading synchronization for selecting either a synchronization signal of a frequency at the time of normal reproduction from the synchronization signal generation means or a predetermined multiple synchronization signal of a predetermined multiple frequency in response to a mode notification from the mode detection means and outputting the selected signal as a read signal. Further comprising: a signal selection unit; and a data selection unit that selects one of the image data from the image data expansion unit and the image data from the image thinning unit in accordance with the mode notification from the mode detection unit. Means for expanding and outputting the compressed image data of the video in synchronization with the readout synchronization signal from the image readout synchronization signal selection unit; Depending on the mode notification from de detection means is usually one that generates a synchronizing signal of a predetermined multiple of the frequency of the synchronizing signals and the normal reproduction of the frequency at the time of reproduction.
[0014]
A video playback apparatus according to the present invention includes a predetermined-speed playback instruction detection unit that receives a playback speed instruction from a user or the like and outputs an operation instruction to specify which of a frequency during normal playback and a frequency of a predetermined multiple is used. A decoding clock generating means for generating a decoding clock having a frequency that is a predetermined multiple of the normal reproduction frequency, wherein the decoding clock is input to the image data decompression means, and the image data decompression means outputs the predetermined clock when the normal reproduction is performed. The compressed image data of the video is decompressed at the speed described above.
[0015]
In the video reproducing apparatus according to the present invention, the mode detection means can further determine whether or not the image data decompression means can perform decoding in synchronization with a readout signal of a predetermined multiple frequency from the image readout synchronization signal selection means and can perform decoding. If not, the image data decompression means thins out the image data and decodes only part of the image data.
[0016]
The video playback device according to the present invention includes a predetermined-speed playback instruction detection unit that receives a playback speed instruction from a user or the like and outputs an operation instruction for specifying which of a frequency during normal playback and a frequency of a predetermined multiple is to be used. Further, the mode detection means further determines whether or not the image data decompression means can decode in synchronization with a readout signal of a predetermined multiple frequency from the image readout synchronization signal selection means. The image data decompression means thins out the image data and decodes only a part of the image data.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described.
Embodiment 1 FIG.
FIG. 1 is a block diagram of a video reproducing apparatus according to Embodiment 1 of the present invention. In FIG. 1, reference numeral 11 denotes a recording medium, 12 denotes an image data decompression unit, 13 denotes an image reading skipping unit, 14 denotes a buffer unit, 15 denotes a D / A conversion unit, and 16 denotes an image display. Reference numeral 17 denotes an N-times speed reproduction instruction detecting unit, 18 denotes an N-times frequency vertical synchronization signal generation unit, 19 denotes a system clock generation unit, 20 denotes a horizontal synchronization signal generation unit, and 21 denotes a vertical synchronization signal generation unit. It is a synchronization signal generation unit.
[0018]
In MPEG, an image is composed of three types of pictures, I, P, and B. Of these, only I pictures can be decoded without other pictures. Therefore, an operation that breaks the context, such as random access, is realized by accessing the I picture. Fast-forwarding is generally realized by intermittently accessing only the I picture among the I, P, and B pictures, but a smooth video cannot be obtained. Hereinafter, a description will be given of a video reproducing apparatus in which such high-efficiency coded data such as an MPEG video stream is recorded in a recording medium in advance and reproduced.
[0019]
Next, the operation will be described.
First, the normal operation will be described.
The high-efficiency encoded data read from the recording medium 11 is decoded by the image data decompression unit 12 using the system clock from the system clock generation unit 19 as a decoding clock. The N-times speed reproduction instruction detecting unit 17 notifies the N-times frequency vertical synchronization signal generating unit 18 and the image reading skipping unit 13 of a normal operation instruction. The N-times frequency vertical synchronizing signal generation unit 18 generates a normal frequency image readout signal in accordance with a normal operation instruction from the N-times speed reproduction instruction detection unit 17 and inputs the signal to the image data decompression unit 12 and the image reading skipping unit 13. I do. The image data decompression unit 12 outputs one decoded image data by using the image read signal as a trigger.
[0020]
Upon receiving the normal reproduction instruction from the N × speed reproduction instruction detecting unit 17, the image reading skipping unit 13 transfers the decoded image data input from the image data decompression unit 12 to the buffer unit 14 as it is. The system clock output from the system clock generator 19 is supplied to the vertical synchronizing signal generator 21 and the horizontal synchronizing signal generator 20 to generate a vertical synchronizing signal and a horizontal synchronizing signal having normal frequencies, respectively. The vertical synchronizing signal and the horizontal synchronizing signal of the normal frequency are supplied to the D / A conversion unit 15 and the image display unit 16.
[0021]
The buffer unit 14 outputs one piece of image data at a normal rate by using a vertical synchronization signal of a normal frequency from the vertical synchronization signal generation unit 21 as a trigger. The output image data is converted into an analog signal by the D / A converter 15 and an image is displayed on the image display 16 at a normal reproduction speed.
[0022]
Next, the operation at the time of N-times speed reproduction will be described.
Here, it is assumed that the image data decompression unit 12 has a capability of performing decoding processing without failure even when the bit rate of the input high-efficiency encoded data becomes N times the normal time. When the N-times speed reproduction instruction detecting unit 17 detects an N-times speed reproduction instruction or the like from the user, the N-times speed vertical synchronization signal generating unit 18 and the image skipping unit 13 are notified of an N-times speed reproduction operation instruction. The N-times frequency vertical synchronizing signal generation unit 18 generates an image read signal having a frequency N times the normal frequency in response to an operation instruction for N-times speed reproduction, and inputs the signal to the image data decompression unit 12 and the image reading skip unit 13. The high-efficiency encoded data is input from the recording medium 11 to the image data decompression unit 12 at a rate N times the normal rate. The image data decompression unit 12 outputs one decoded image data, triggered by the image readout signal of N times frequency from the N times frequency vertical synchronization signal generation unit 18 as a trigger. As a result, the output image data is transferred to the image skipping unit 13 at a bit rate that is N times the normal bit rate.
[0023]
When the image skipping unit 13 receives the operation instruction of N-times speed reproduction from the N-times speed reproduction instruction detection unit 17, the image reading skip unit 13 synchronizes the input image data with every N-1 sheets in synchronization with the image reading signal of N times frequency. The selected image data is transferred to the buffer unit 14 at the subsequent stage, and other image data is deleted. As a result, the output rate of the image data from the image skipping unit 13 becomes the normal bit rate.
[0024]
On the other hand, the horizontal synchronizing signal generator 20 and the vertical synchronizing signal generator 21 generate a vertical synchronizing signal and a horizontal synchronizing signal having normal frequencies, respectively, according to the system clock from the system clock generating unit 19, as in the normal reproduction operation. I do. The buffer unit 14 outputs one piece of image data using the vertical synchronization signal of the normal frequency generated by the vertical synchronization signal generation unit 21 as a trigger. The output image data is converted into an analog signal by the D / A converter 15, and an image is displayed on the image display 16.
[0025]
As described above, up to the input stage of the image skipping unit 13, the data bit rate is N times the normal, and after the output stage of the image skipping unit 13, the image data rate becomes the normal bit rate. It can be displayed on the display device. The image displayed on the image display unit 16 is an N-1 skipped image (an image at a ratio of N images in a normal operation, one image) at each period of the vertical synchronization signal. , N times speed reproduction is realized.
[0026]
FIG. 3 is a schematic diagram showing the operation of the video playback device according to Embodiment 1 during 2 × speed playback. In FIG. 3, reference numeral 31 denotes an image readout signal output by the N-fold frequency vertical synchronization signal generation unit 18, reference numeral 32 denotes image skipping unit input data, reference numeral 33 denotes image reading skipping unit output data, and reference numeral 34 denotes buffer readout. And 35 is buffer read data (display image).
[0027]
When the N × speed reproduction instruction detecting unit 17 detects a 2 × speed reproduction instruction from the user, the N × frequency vertical synchronizing signal generation unit 18 and the image reading skip unit 13 send an operation instruction of the reproduction speed 2 to the N × speed reproduction instruction detecting unit 17. Will be notified from The N-fold frequency vertical synchronizing signal generator 18 outputs an image read signal 31 shown in FIG. On the other hand, the vertical synchronization signal generated by the vertical synchronization signal generation unit 21 is input to the buffer unit 14 as a buffer read signal 34. The vertical synchronizing signal has a normal frequency, and the image reading signal 31 has a frequency twice as high as the normal frequency. The image data decompression unit 12 outputs the image skipping unit input data 32 in synchronization with the image read signal 31. The image skipping section input data 32 is transferred to the image skipping section 13. The image skipping unit 13 operates to output one out of two input images of the image skipping unit input data 32, and the transfer rate is different from the input rate as in the image skipping unit output data 33 in FIG. Is output as 1/2. The image skipping unit output data 33 is input to the buffer unit 14. The image skipping section output data 33 input to the buffer section 14 is read out by a normal vertical synchronizing signal, is converted into an analog signal by the D / A conversion section 15, and a display image 35 is obtained by the image display section 16. As a result, the display image 35 is displayed at twice the normal playback speed.
[0028]
As described above, the video reproducing apparatus according to the first embodiment generates the synchronizing signal generating means (18, 20, 21) for generating the predetermined times synchronizing signal having the frequency which is a predetermined times higher than the frequency of the reproduction synchronizing signal at the time of the normal reproduction. ), Image data expansion means (12) for expanding compressed image data of a video and outputting the image data in synchronization with a predetermined multiplication signal, and image data output in synchronization with the predetermined multiplication signal during normal reproduction. Image thinning means (13) for thinning out an image based on a reproduction synchronization signal, outputting the thinned image to a display means, and displaying the thinned image.
[0029]
The video reproducing apparatus according to the first embodiment receives a reproduction speed instruction from a user or the like and outputs an operation instruction for designating which of a frequency during normal reproduction and a frequency which is a predetermined multiple is used. Means (17).
[0030]
As described above, according to the first embodiment, the image data decompression unit performs the decoding operation of all image data at N times the normal speed, and the image skipping unit outputs the decoded image data every N-1 frames. In this case, reproduction at N times speed can be performed, and by setting the value of N to a relatively small integer value, an effect of performing smooth N times speed reproduction can be obtained.
[0031]
According to the first embodiment, the image data decompression unit decodes all the image data, and the image skipping unit skips and displays all the decoded image data by N-1 frames. Regardless of the data structure of the compressed image data stream, the effect that the displayed image data is accurately N times faster can be obtained.
[0032]
According to the first embodiment, the N-times speed reproduction instruction detecting unit receives the reproduction speed instruction from the user or the like and outputs an operation instruction to specify which of the normal frequency and the N times frequency is used. Therefore, an effect is obtained that N-times speed reproduction can be performed at a reproduction speed according to a reproduction speed instruction from a user or the like.
[0033]
Embodiment 2 FIG.
FIG. 2 is a block diagram of a video playback device according to Embodiment 2 of the present invention. In FIG. 2, reference numeral 23 denotes a decoding clock generator. Other components are the same as those shown in FIG. In the first embodiment, it is assumed that the image data decompression unit 12 has a sufficiently high processing capability even in a normal operation. However, the image data decompression unit 12 in the second embodiment uses a frequency of a decoding clock for performing a decoding process. To increase the processing capacity.
[0034]
Next, the operation will be described.
The system clock from the system clock generator 19 and the operation instruction from the N-times speed reproduction instruction detector 17 are input to the decoded clock generator 23. The decoding clock from the decoding clock generating unit 23 is input to the image data expanding unit 12 in place of the system clock from the system clock generating unit 19 input to the image data expanding unit 12 of the first embodiment.
[0035]
The decoding clock generation unit 23 changes its operation in response to an operation instruction from the N-times speed reproduction instruction detection unit 17 and generates a normal frequency decoding clock when receiving an operation instruction for normal reproduction with N = 1. . When an operation instruction for N-times speed reproduction in which the value of N is an integer equal to or greater than 2 is received, a decoding clock having a frequency N times the normal time is generated.
[0036]
By changing the decoding clock frequency in accordance with the N-times speed reproduction operation instruction, the decoding processing speed of the image data decompression unit 12 follows the reproduction speed specified by the user input to the N-times speed reproduction instruction detection unit 17. Can be done. The operation of other parts is the same as in the first embodiment.
[0037]
Since the video reproducing apparatus according to the second embodiment is configured and operates as described above, it is possible to reproduce at N times speed.
[0038]
Further, since the display image is selected and displayed by skipping N-1 images among all the decoded images, the displayed image is accurately N times speed regardless of the data configuration of the highly efficient encoded stream.
[0039]
Also, by setting the value of N to a relatively small integer value, smooth N-times speed reproduction can be performed.
[0040]
As described above, the video reproducing apparatus according to the second embodiment generates the synchronous signal generating means (18, 20, 21) for generating the predetermined times synchronizing signal having the frequency times the frequency of the reproducing synchronizing signal at the time of the normal reproduction. ), Image data expansion means (12) for expanding compressed image data of a video and outputting the image data in synchronization with a predetermined multiplication signal, and image data output in synchronization with the predetermined multiplication signal during normal reproduction. An image thinning means (13) for thinning out an image based on the reproduction synchronization signal, outputting the image to the display means and displaying the image, and a decoding clock generating means (23) for generating a decoding clock having a frequency that is a predetermined multiple of the frequency during normal reproduction The decoding clock is input to the image data decompression means (12), and the image data decompression means decompresses the compressed image data of the video at a speed twice as fast as that of the normal reproduction.
[0041]
The video reproducing apparatus according to the second embodiment receives a reproduction speed instruction from a user or the like and outputs an operation instruction for specifying which of a frequency during normal reproduction and a predetermined multiple frequency is to be used. Means (17).
[0042]
As described above, according to the second embodiment, the image data decompression unit performs the decoding operation of all the image data at N times the normal speed, and the image skipping unit outputs the decoded image data every N-1 frames. In this case, reproduction at N times speed can be performed, and by setting the value of N to a relatively small integer value, an effect of performing smooth N times speed reproduction can be obtained.
[0043]
According to the second embodiment, the image data decompression unit decodes all image data, and the image skipping unit skips and displays all decoded image data by N-1 frames. Regardless of the data structure of the compressed image data stream, the effect that the displayed image data is accurately N times faster can be obtained.
[0044]
According to the second embodiment, the decoding clock supplied to the image data expansion unit is generated by the decoding clock generation unit, and the frequency of the decoding clock is increased by N times. Since the decoding operation of all image data is performed at N times speed, the effect of increasing the operation speed of the image data decompression unit can be obtained.
[0045]
According to the second embodiment, the N-times speed reproduction instruction detecting unit receives the reproduction speed instruction from the user or the like and outputs an operation instruction to specify which of the normal frequency and the N times frequency is used. Therefore, an effect is obtained that N-times speed reproduction can be performed at a reproduction speed according to a reproduction speed instruction from a user or the like.
[0046]
Embodiment 3 FIG.
FIG. 4 is a block diagram of a video reproducing apparatus according to Embodiment 3 of the present invention. In FIG. 4, reference numeral 11 denotes a recording medium on which high-efficiency encoded data is recorded, 12 denotes an image data decompression unit, 15 denotes a D / A conversion unit, 16 denotes an image display unit, and 17 denotes an N-speed. A reproduction instruction detecting unit 19 is a system clock generating unit, 20 is a horizontal synchronizing signal generating unit, and 21 is a vertical synchronizing signal generating unit.
[0047]
Next, the operation will be described.
First, the normal operation of the video reproducing apparatus according to the third embodiment will be described.
The highly efficient encoded video data read from the recording medium 11 is decoded by the image data decompression unit 12. The N-times speed reproduction instruction detection unit 17 notifies the horizontal synchronization signal generation unit 20 and the vertical synchronization signal generation unit 21 of a normal operation instruction. The horizontal synchronizing signal generator 20 and the vertical synchronizing signal generator 21 generate a horizontal synchronizing signal and a vertical synchronizing signal of a normal frequency according to a normal operation instruction, respectively, and the horizontal synchronizing signal is a D / A converter 15 and an image display unit. The vertical synchronizing signal is input to the image data decompression unit 12, the D / A conversion unit 15, and the image display unit 16. The image data decompression unit 12 outputs one decoded image data using the vertical synchronization signal as a trigger. The output image data is converted into an analog signal by the D / A converter 15 and an image is displayed on the image display 16 at a normal reproduction speed.
[0048]
Next, the operation of N-speed playback will be described.
Here, it is assumed that the image data decompression unit 12 has a capability of performing decoding processing without failure even when the bit rate of the input high-efficiency encoded data becomes N times the normal time. Further, it is assumed that the image display unit 16 can display an image even with a horizontal synchronization signal and a vertical synchronization signal having a frequency N times higher than the frequency during normal operation.
[0049]
When the N-times speed reproduction instruction detecting unit 17 detects an N-times speed reproduction instruction or the like from the user, it notifies the horizontal synchronization signal generation unit 20 and the vertical synchronization signal generation unit 21 of the operation instruction of the reproduction speed N. The horizontal synchronizing signal generator 20 and the vertical synchronizing signal generator 21 respectively generate a horizontal synchronizing signal and a vertical synchronizing signal having a frequency N times the normal frequency in accordance with the operation instruction of the reproducing speed N, and the horizontal synchronizing signal is subjected to D / A conversion. The vertical synchronizing signal is input to the image data expansion unit 12, the D / A conversion unit 15, and the image display unit 16. In the image data decompression unit 12, the highly efficient encoded data is transferred from the recording medium 11 at a rate of N times the normal time, and one vertical decoded signal is triggered by a vertical synchronization signal having a frequency of N times the normal frequency as a trigger. Data is output. As a result, the output image data is transferred to the D / A converter 15 at a bit rate that is N times the normal bit rate. The output image data is converted into an analog signal by the D / A converter 15, and an image is displayed on the image display 16.
[0050]
FIG. 5 is a schematic diagram showing an operation of the video playback device according to the third embodiment during double-speed playback. In FIG. 5, reference numeral 51 denotes a vertical synchronization signal output by the vertical synchronization signal generator 21 during normal reproduction (normal frequency), 52 denotes a display image during normal reproduction, and 53 denotes an output from the vertical synchronization signal generator 21. Is a vertical synchronization signal at the time of double speed reproduction, and 54 is a display image at the time of double speed reproduction.
[0051]
When the N × speed reproduction instruction detecting unit 17 detects the 2 × speed reproduction instruction, it notifies the horizontal synchronization signal generation unit 20 and the vertical synchronization signal generation unit 21 of the operation instruction of the reproduction speed 2. The vertical synchronizing signal generation section 21 outputs a vertical synchronizing signal 53 at the time of double speed reproduction shown in FIG. This is twice the frequency of the vertical synchronizing signal 51 during normal reproduction. The image data expansion unit 12 outputs image data in synchronization with the vertical synchronization signal 51, converts the image data into an analog signal by the D / A conversion unit 15, and displays the analog signal on the image display unit 16. The displayed image looks like the display image 54 at the time of double speed reproduction shown in FIG. 5, and all the images decoded by the image data decompression unit 12 are displayed at twice the speed of the display image 52 at the time of normal reproduction. Will go.
[0052]
Since the video reproducing apparatus according to the third embodiment is configured and operates as described above, it can reproduce at N times speed.
[0053]
Further, since the display image is obtained by decoding all the images of the high-efficiency coded stream and is displayed in synchronization with the vertical synchronization signal of N times frequency, the displayed image is independent of the data configuration of the high-efficiency coded stream. Exactly N times speed.
[0054]
Further, in the first and second embodiments, only the image selected from all the decoded data according to the reproduction speed is displayed, so that the reproduction speed can be obtained only by an integral multiple. In the third embodiment, all the decoded images are displayed in synchronization with the vertical synchronizing signal of N times frequency, so that the display can be realized at an arbitrary reproduction speed.
[0055]
Further, since all the decoded images are displayed at the N-times speed on the image display unit 16, it is possible to realize a very smooth N-times speed reproduction as compared with fast-forward reproduction by dropping frames.
[0056]
As described above, the video reproducing apparatus according to the third embodiment includes the synchronizing signal generating means (20, 21) for generating the predetermined times synchronizing signal having the frequency times the frequency of the reproducing synchronizing signal at the time of normal reproduction. Image data expansion means (12) for expanding compressed image data of video and outputting the image data in synchronization with a predetermined multiple synchronization signal.
[0057]
The video playback device according to the third embodiment receives a playback speed instruction from a user or the like and outputs an operation instruction to specify which of a frequency during normal playback and a predetermined multiple frequency is to be used. Means (17).
[0058]
As described above, according to the third embodiment, the image data decompression unit performs the decoding operation of all image data at N times the normal speed and displays all the decoded image data. Double-speed reproduction can be performed, and by setting the value of N to a relatively small integer value, an effect of performing smooth N-speed reproduction can be obtained.
[0059]
According to the third embodiment, since the image data decompression unit decodes all the image data and displays all the decoded image data, the display is performed regardless of the data configuration of the compressed image data stream. The image data to be obtained has an effect of being accurately N times faster.
[0060]
According to the third embodiment, the vertical synchronization signal supplied to the image data decompression unit is generated by the synchronization signal generation unit, and the decoded image data is displayed in synchronization with the vertical synchronization signal. The effect that N-times speed reproduction can be performed for N other than an integer is obtained.
[0061]
According to the third embodiment, the N-times speed reproduction instruction detecting unit receives a reproduction speed instruction from a user or the like and outputs an operation instruction to specify which of the normal frequency and the N times frequency is used. Therefore, an effect is obtained that N-times speed reproduction can be performed at a reproduction speed according to a reproduction speed instruction from a user or the like.
[0062]
Embodiment 4 FIG.
FIG. 6 is a block diagram of a video reproducing apparatus according to Embodiment 4 of the present invention. In FIG. 6, reference numeral 61 denotes an image reading synchronization signal selection unit, 63 denotes a mode detection unit, and 62 denotes a data selection unit. Other components are the same as those shown in FIG.
[0063]
In the fourth embodiment, the configuration of the first embodiment is combined with the configuration of the third embodiment. The configuration of the first embodiment includes a mode detection unit 63, an image reading synchronization signal selection unit 61, and a data selection unit. A part 62 is added.
[0064]
Next, the operation will be described.
The operation of the fourth embodiment selects one of the N-times speed reproduction according to the configuration of the first embodiment and the N-times speed reproduction according to the configuration of the third embodiment according to the value of N in the operation instruction of the N-times speed reproduction. It is.
[0065]
The mode detecting unit 63 specifies the N-times speed reproduction mode as follows. That is, when an operation instruction for N-times speed reproduction is issued, the frequency of the vertical synchronization signal (N times the frequency of the system clock) generated by the vertical synchronization signal generation unit 21 is set to the vertical synchronization signal that the image display unit 16 can pull in. If the frequency is equal to or lower than the upper limit frequency, the N-times speed reproduction mode according to the configuration of the third embodiment is selected. Otherwise, the N times speed reproduction mode according to the configuration of the first embodiment is selected.
[0066]
The mode detecting unit 63 notifies the horizontal synchronizing signal generating unit 20, the vertical synchronizing signal generating unit 21, the image reading synchronizing signal selecting unit 61 and the data selecting unit 62 of the selected N × speed reproduction mode instruction.
[0067]
FIG. 7 is a diagram illustrating a portion that performs an effective operation when the N-times speed reproduction mode according to the configuration of the third embodiment is selected. FIG. 8 is a diagram illustrating a portion that performs an effective operation when the N-times speed reproduction mode according to the configuration of the first embodiment is selected. In FIG. 7 and FIG. 8, the part that is performing an effective operation is indicated by a thick line.
[0068]
FIG. 7 shows a case where the frequency (N times the frequency of the system clock) of the vertical synchronization signal output from the vertical synchronization signal generation unit 21 is equal to or lower than the upper limit frequency of the vertical synchronization signal frequency that the image display unit 16 can pull in. The operation part is shown. The horizontal synchronization signal generation unit 20 and the vertical synchronization signal generation unit 21 receive the mode instruction from the mode detection unit 63, respectively, and operate so as to perform the reproduction according to the configuration of the third embodiment. That is, a horizontal synchronizing signal and a vertical synchronizing signal having N times the frequency of the normal operation are generated.
[0069]
When receiving the reproduction mode instruction according to the configuration of the third embodiment, the image reading synchronization signal selection unit 61 expands the vertical synchronization signal generated by the vertical synchronization signal generation unit 21 which is N times the normal frequency and expands the image data. It is selected as a trigger for reading data from the unit 12. When receiving the reproduction mode instruction according to the configuration of the third embodiment, the data selection unit 62 selects the data from the image data decompression unit 12. As a result, all the image data decoded at the normal bit rate N times is transferred from the image data decompression unit 12 to the data selection unit 62. Output data from the image data decompression unit 12 is transferred from the data selection unit 62 to the D / A conversion unit 15. The analog output from the D / A conversion unit 15 is transferred to the image display unit 16, and is synchronized with the horizontal synchronization signal and the vertical synchronization signal of N times the frequency from the horizontal synchronization signal generation unit 20 and the vertical synchronization signal generation unit 21. An image at N times speed is displayed.
[0070]
By adopting the same operation as that of the third embodiment, all the decoded image data is displayed at N times normal reproduction speed, and a very smooth N times speed display is obtained.
[0071]
FIG. 8 shows an effective operation when the frequency of the vertical synchronization signal (N times the frequency of the system clock) output from the vertical synchronization signal generation unit 21 is higher than the upper limit frequency of the vertical synchronization signal frequency that the image display unit 16 can pull in. The part is shown. In this case, the mode detection unit 63 notifies the horizontal synchronization signal generation unit 20, the vertical synchronization signal generation unit 21, the image reading synchronization signal selection unit 61, and the data selection unit 62 of the reproduction mode instruction according to the configuration of the first embodiment. I do. The horizontal synchronizing signal generator 20 and the vertical synchronizing signal generator 21 each receive a mode instruction, generate a horizontal synchronizing signal and a vertical synchronizing signal having the same frequency as in the normal operation, and perform the same operation as in the first embodiment.
[0072]
The N-times frequency vertical synchronizing signal generating unit 18 generates an image reading signal of N times frequency, and the image reading signal of N times frequency is read by the image reading synchronizing signal selecting unit 61 and the image data of the image data expanding unit 12 is read. The signal is selected and input to the image data decompression unit 12 and the image reading skipping unit 13, respectively. The image data decompression unit 12 outputs one piece of decoded image data, triggered by an image read signal of N times frequency. As a result, the output image data is transferred to the image skipping unit 13 at a bit rate that is N times the normal bit rate. The image reading skipping unit 13 selects the input image data every N-1 sheets in synchronization with the image reading signal of N times frequency, transfers the image data to the buffer unit 14 at the subsequent stage, and transfers the other image data. Is deleted. As a result, the image data output rate from the image skipping unit 13 becomes the normal bit rate.
[0073]
On the other hand, the vertical synchronizing signal generation section 21 generates a normal frequency vertical synchronizing signal, and the buffer section 14 uses the normal frequency vertical synchronizing signal generated by the vertical synchronizing signal generating section 21 as a trigger. Is output. The data selection unit 62 that has received the mode designation selects the image data from the buffer unit 14, transfers it to the D / A conversion unit 15, and the image is displayed on the image display unit 16.
[0074]
As a result, even at a reproduction speed at which the image display unit 16 cannot be pulled in, by adopting the configuration of the first embodiment, it is possible to reproduce at N times speed.
[0075]
Since the video reproducing apparatus according to the fourth embodiment is configured and operates as described above, it is possible to perform N-times speed reproduction in which the range of the value of N is larger.
[0076]
As described above, the video playback apparatus according to the fourth embodiment generates synchronization signal generation means (18, 20, 21) for generating a predetermined multiple synchronization signal having a frequency that is a predetermined multiple of the frequency of the reproduction synchronization signal during normal reproduction. ), Image data expansion means (12) for expanding compressed image data of a video and outputting the image data in synchronization with a predetermined multiplication signal, and image data output in synchronization with the predetermined multiplication signal during normal reproduction. An image thinning means (13) for thinning out an image based on a reproduction synchronizing signal and outputting it to a display means for display, and judging whether or not an image display section can display even at a frequency which is a predetermined multiple of that in normal reproduction. A mode detection means (63) for selecting an operation mode and outputting a mode notification; and a normal playback from the synchronization signal generation means (18, 20, 21) in response to the mode notification from the mode detection means (63). Of frequency An image reading synchronization signal selecting means (61) for selecting any one of a synchronization signal and a predetermined multiplication signal having a predetermined frequency and outputting the selected signal as a reading signal; A data selecting unit (62) for selecting one of the image data from the data decompressing unit (12) and the image data from the image thinning unit (13), wherein the image data decompressing unit (12) outputs an image reading synchronization signal. In synchronization with the read synchronization signal from the selection unit, the compressed image data of the video is expanded and output, and the synchronization signal generation means (18, 20, 21) responds to the mode notification from the mode detection means (63). And a synchronizing signal having a frequency that is a predetermined multiple of that of the normal reproduction.
[0077]
As described above, according to the fourth embodiment, decoding is performed by the image data decompression unit in accordance with whether or not the reproduction speed specified by the value of N for N-times speed reproduction is a reproduction speed at which the image display unit can pull in. To display all the decoded image data or to display the image data decoded by the image data decompressor by skipping N-1 frames, so that the value range of N is larger at N times speed. The effect that the reproduction can be performed is obtained.
[0078]
According to the fourth embodiment, the N-times speed reproduction instruction detecting unit receives the reproduction speed instruction from the user or the like and outputs an operation instruction to specify which of the normal frequency and the N times frequency is used. Therefore, an effect is obtained that N-times speed reproduction can be performed at a reproduction speed according to a reproduction speed instruction from a user or the like.
[0079]
Embodiment 5 FIG.
FIG. 9 is a block diagram of a video device according to Embodiment 5 of the present invention. In FIG. 9, reference numeral 61 denotes an image reading synchronization signal selection unit, 63 denotes a mode detection unit, and 62 denotes a data selection unit. Other components are the same as those shown in FIG.
[0080]
In the fifth embodiment, the configuration of the second embodiment is combined with the configuration of the third embodiment. The configuration of the second embodiment includes a mode detection unit 63, an image reading synchronization signal selection unit 61, and a data selection unit. A part 62 is added.
[0081]
Next, the operation will be described.
The operation of the fifth embodiment selects either the N-times speed reproduction according to the configuration of the second embodiment or the N times speed reproduction according to the configuration of the third embodiment according to the value of N in the operation instruction of the N-times speed reproduction. It is.
[0082]
The mode detecting unit 63 specifies the N-times speed reproduction mode as follows. That is, when an operation instruction for N-times speed reproduction is issued, the frequency of the vertical synchronization signal (N times the frequency of the system clock) generated by the vertical synchronization signal generation unit 21 is set to the vertical synchronization signal that the image display unit 16 can pull in. If the frequency is equal to or lower than the upper limit frequency, the N-times speed reproduction mode according to the configuration of the third embodiment is selected. Otherwise, the N times speed reproduction mode according to the configuration of the second embodiment is selected.
[0083]
As in the second embodiment, the processing speed of the image data decompression unit 12 during N-times speed reproduction depends on the frequency of the decoding clock generated from the decoding clock generating unit 23. That is, at the time of the N-times speed reproduction, the decoding clock generated from the decoding clock generation unit 23 has a frequency N times that of the normal reproduction, whereby the decoding rate in the image data decompression unit 12 becomes N times the normal time. . Except for the above operation of the image data decompression unit 12, the operation and effect are the same as those of the video reproducing apparatus in the fourth embodiment.
[0084]
As described above, the video reproducing apparatus according to the fifth embodiment has the synchronizing signal generating means (18, 20, 21) for generating the predetermined times synchronizing signal having the frequency times the frequency of the reproducing synchronizing signal at the time of the normal reproduction. ), Image data expansion means (12) for expanding compressed image data of a video and outputting the image data in synchronization with a predetermined multiplication signal, and image data output in synchronization with the predetermined multiplication signal during normal reproduction. An image thinning means (13) for thinning out an image based on a reproduction synchronizing signal and outputting it to a display means for display, and judging whether or not an image display section can display even at a frequency which is a predetermined multiple of that in normal reproduction. A mode detection means (63) for selecting an operation mode and outputting a mode notification; and a normal playback from the synchronization signal generation means (18, 20, 21) in response to the mode notification from the mode detection means (63). Of frequency An image reading synchronization signal selecting means (61) for selecting any one of a synchronization signal and a predetermined multiplication signal having a predetermined frequency and outputting the selected signal as a reading signal; A data selection unit (62) for selecting either image data from the data decompression unit (12) or image data from the image thinning unit (13), and a frequency for normal reproduction in response to a reproduction speed instruction from a user or the like A predetermined speed reproduction instruction detecting means (17) for outputting an operation instruction designating which of the above and a predetermined frequency is to be used, and a decoding clock generation for generating a decoding clock having a frequency twice as high as the frequency during normal reproduction Means (23), wherein the image data decompression means (12) compresses the video in synchronism with the read synchronization signal from the image read synchronization signal selection section. The image data is expanded and output, and the synchronizing signal generating means (18, 20, 21) responds to the mode notification from the mode detecting means (63) to output the synchronizing signal of the frequency during normal reproduction and the predetermined signal during normal reproduction. A synchronizing signal having a double frequency is generated, a decoding clock is input to the image data decompression means (12), and the image data decompression means decompresses the compressed image data of the video at a predetermined speed of normal reproduction. is there.
[0085]
As described above, according to the fifth embodiment, decoding is performed by the image data decompression unit depending on whether or not the reproduction speed specified by the value of N for N-times speed reproduction is a reproduction speed at which the image display unit can pull in. To display all the decoded image data or to display the image data decoded by the image data decompressor by skipping N-1 frames, so that the value range of N is larger at N times speed. The effect that the reproduction can be performed is obtained.
[0086]
According to the fifth embodiment, the decoding clock supplied to the image data decompression unit is generated by the decoding clock generation unit, and the frequency of the decoding clock is increased by N times. Since the decoding operation of all image data is performed at N times speed, the effect of increasing the operation speed of the image data decompression unit can be obtained.
[0087]
According to the fifth embodiment, the N-times speed reproduction instruction detection unit receives a reproduction speed instruction from a user or the like and outputs an operation instruction to specify which of the normal frequency and the N-times frequency to use. Therefore, an effect is obtained that N-times speed reproduction can be performed at a reproduction speed according to a reproduction speed instruction from a user or the like.
[0088]
Embodiment 6 FIG.
FIG. 10 is a block diagram of an image reproducing apparatus according to Embodiment 6 of the present invention. In FIG. 10, each component is the same as in FIG. In the sixth embodiment, the output (mode instruction) of the mode detection unit 63 is also input to the image data decompression unit 12 as compared with the fourth embodiment shown in FIG.
[0089]
Next, the operation will be described.
The mode detection unit 63 determines whether the image data decompression unit 12 can decode at a speed N times the normal decoding speed, and determines whether the image data decompression unit 12, the image reading synchronization signal selection unit 61, the horizontal synchronization signal generation unit 20, A mode designation is notified to the synchronization signal generator 21 and the data selector 62. If decoding can be performed at a speed N times the normal decoding speed, the processing in Embodiment 4 is performed. If decoding cannot be performed at a speed N times the normal decoding speed, the image data decompression unit 12 outputs an I picture or Only the I picture and the P picture are decoded, and the decoded image data is displayed by the same method as the normal reproduction method.
[0090]
Since the video reproducing apparatus according to the sixth embodiment is configured and operates as described above, it is possible to perform N-times speed reproduction in which the range of the value of N is larger than in the case of the fourth embodiment.
[0091]
As described above, the video reproducing apparatus according to the sixth embodiment generates the synchronizing signal generating means (18, 20, 21) for generating the predetermined times synchronizing signal having the frequency times the frequency of the reproducing synchronizing signal at the time of the normal reproduction. ), Image data expansion means (12) for expanding compressed image data of a video and outputting the image data in synchronization with a predetermined multiplication signal, and image data output in synchronization with the predetermined multiplication signal during normal reproduction. An image thinning means (13) for thinning out an image based on a reproduction synchronizing signal and outputting it to a display means for display, and judging whether or not an image display section can display even at a frequency which is a predetermined multiple of that in normal reproduction. A mode detection means (63) for selecting an operation mode and outputting a mode notification; and a normal playback from the synchronization signal generation means (18, 20, 21) in response to the mode notification from the mode detection means (63). Of frequency An image reading synchronization signal selecting means (61) for selecting any one of a synchronization signal and a predetermined multiplication signal having a predetermined frequency and outputting the selected signal as a reading signal; A data selecting unit (62) for selecting one of the image data from the data decompressing unit (12) and the image data from the image thinning unit (13), wherein the image data decompressing unit (12) outputs an image reading synchronization signal. In synchronization with the read synchronization signal from the selection unit, the compressed image data of the video is expanded and output, and the synchronization signal generation means (18, 20, 21) responds to the mode notification from the mode detection means (63). A mode synchronizing signal having a frequency at the time of normal reproduction and a synchronizing signal having a frequency which is a predetermined multiple of the frequency at the time of normal reproduction are generated. It is further determined whether or not decoding is possible in synchronization with a readout signal of a predetermined multiple frequency from the output synchronization signal selecting means (61). If decoding is not possible, the image data decompression means (12) converts the image data to image data. Only some of the image data is decoded by thinning.
[0092]
As described above, according to the sixth embodiment, all of the I, P, and B pictures are decoded according to whether or not the image data decompression unit can decode at N times the normal decoding speed. Or the decoding of only an I picture or an I picture and a P picture, it is possible to obtain the effect of enabling N-times speed reproduction in which the range of N values is larger.
[0093]
Embodiment 7 FIG.
FIG. 11 is a block diagram of a video playback device according to Embodiment 7 of the present invention. In FIG. 11, each component is the same as in FIG. In the seventh embodiment, as compared with the fifth embodiment shown in FIG. 9, the output (mode designation) of the mode detection unit 63 is also input to the decoded clock generation unit 23.
[0094]
Next, the operation will be described.
The mode detection unit 63 determines whether or not the image data decompression unit 12 can perform decoding even if the decoding clock frequency becomes N times the decoding clock frequency during normal decoding, and the decoding clock generation unit 23 and the image reading synchronization signal selection unit. 61, the horizontal synchronizing signal generator 20, the vertical synchronizing signal generator 21 and the data selector 62 are notified of the mode designation. If decoding is possible even if the frequency of the decoding clock becomes N times that of normal decoding, the processing in Embodiment 5 is performed. If decoding cannot be performed at N times the normal decoding speed, the image data decompression unit 12 Decodes only an I-picture or only an I-picture and a P-picture, and the decoded image data is displayed in the same manner as the normal playback.
[0095]
Since the video reproducing apparatus according to the seventh embodiment is configured and operates as described above, it is possible to perform N-times speed reproduction in which the value range of N is larger than in the fifth embodiment.
[0096]
As described above, the video reproducing apparatus according to the seventh embodiment generates the synchronizing signal generating means (18, 20, 21) for generating the predetermined times synchronizing signal having the frequency times the frequency of the reproducing synchronizing signal at the time of normal reproduction. ), Image data expansion means (12) for expanding compressed image data of a video and outputting the image data in synchronization with a predetermined multiplication signal, and image data output in synchronization with the predetermined multiplication signal during normal reproduction. An image thinning means (13) for thinning out an image based on a reproduction synchronizing signal and outputting it to a display means for display, and judging whether or not an image display section can display even at a frequency which is a predetermined multiple of that in normal reproduction. A mode detection means (63) for selecting an operation mode and outputting a mode notification; and a normal playback from the synchronization signal generation means (18, 20, 21) in response to the mode notification from the mode detection means (63). Of frequency An image reading synchronization signal selecting means (61) for selecting any one of a synchronization signal and a predetermined multiplication signal having a predetermined frequency and outputting the selected signal as a reading signal; A data selection unit (62) for selecting either image data from the data decompression unit (12) or image data from the image thinning unit (13), and a frequency for normal reproduction in response to a reproduction speed instruction from a user or the like And a predetermined speed reproduction instruction detecting means (17) for outputting an operation instruction for designating which of the frequency and the predetermined frequency is to be used, wherein the image data decompression means (12) reads out from the image reading synchronization signal selecting section. In synchronization with the synchronizing signal, the compressed image data of the video is decompressed and output, and the synchronizing signal generating means (18, 20, 21) outputs the mode from the mode detecting means (63). In response to the notification, a mode synchronization means generates a synchronization signal having a frequency at the time of normal reproduction and a synchronization signal having a frequency which is a predetermined multiple of the frequency at the time of normal reproduction. It is further determined whether or not decoding is possible in synchronization with a readout signal of a predetermined frequency from the selection means (61). If decoding is not possible, the image data decompression means (12) thins out the image data and partially Only the image data is decoded.
[0097]
As described above, according to the seventh embodiment, depending on whether or not the image data decompression unit can decode with a decoding clock having a frequency N times the frequency of normal decoding, the I picture, P picture, and B picture can be decoded. Since the selection is made to decode all or only the I picture or the I picture and the P picture, it is possible to obtain the effect that it is possible to perform N-times speed reproduction in which the range of the value of N is larger.
[0098]
【The invention's effect】
As described above, according to the present invention, the image data decompression means performs the decoding operation of all the image data at the constant double speed during normal reproduction, and the image thinning means thins out the decoded image data. Can be reproduced, and by setting the value of the constant to a relatively small integer value, there is an effect that smooth constant-speed reproduction can be performed.
[0099]
According to the present invention, since the image data decompression means decodes all the image data and the image thinning means thins out all the decoded image data, the image data can be displayed regardless of the data configuration of the compressed image data stream. The image data to be obtained has an effect of accurately becoming a constant double speed.
[0100]
According to this invention, the N-times speed reproduction instruction detecting unit receives the reproduction speed instruction from the user or the like and outputs an operation instruction for specifying which of the frequency at the time of normal reproduction and the frequency of the constant times is to be used. Therefore, there is an effect that constant speed reproduction can be performed at a reproduction speed according to a reproduction speed instruction from a user or the like.
[0101]
According to this invention, the decoding clock supplied to the image data decompression means is generated by the decoding clock generation means, and the frequency of the decoding clock is multiplied by a constant. Thus, since the decoding operation of all image data is performed, the operation speed of the image data decompression means can be increased.
[0102]
According to the present invention, since the image data decompression means performs the decoding operation of all the image data at the constant speed of the normal reproduction and displays all the decoded image data, the reproduction at the constant speed can be performed. By setting the value of the constant to a relatively small integer value, there is an effect that smooth constant-speed reproduction can be performed.
[0103]
According to the present invention, since the image data decompression means decodes all the image data and displays all the decoded image data, the displayed image is independent of the data configuration of the compressed image data stream. The data has the effect of being exactly a constant double speed.
[0104]
According to the present invention, the vertical synchronization signal supplied to the image data decompression unit is generated by the synchronization signal generation unit, and the decoded image data is displayed in synchronization with the vertical synchronization signal. There is an effect that constant-speed reproduction can be performed for the constant of.
[0105]
According to the present invention, all of the image data decoded by the image data decompression means is displayed according to whether or not the reproduction speed specified by the constant value of the constant speed reproduction is a reproduction speed at which the image display unit can pull in. Alternatively, it is possible to select whether the image data decoded by the image data decompression means is to be thinned out and displayed, so that there is an effect that it is possible to perform constant-speed reproduction in which the range of the value of the constant is larger.
[0106]
According to the present invention, depending on whether or not the image data decompression means can decode at a constant multiple of the normal decoding speed, all of the I picture, P picture, and B picture can be decoded, Since it is selected whether to decode the picture and the P picture, there is an effect that it is possible to perform constant-speed reproduction in which the range of the value of the constant is larger.
[0107]
According to the present invention, depending on whether or not the image data decompression unit can decode with a decoding clock having a frequency that is a constant multiple of the normal decoding, all of the I picture, P picture, and B picture are decoded, Since the selection is made to decode only the I picture or the I picture and the P picture, there is an effect that it is possible to perform constant-speed reproduction in which the range of the value of the constant is larger.
[Brief description of the drawings]
FIG. 1 is a block diagram of a video playback device according to Embodiment 1 of the present invention.
FIG. 2 is a block diagram of a video playback device according to Embodiment 2 of the present invention.
FIG. 3 is a schematic diagram showing an operation of the video playback device according to the first embodiment during double-speed playback.
FIG. 4 is a block diagram of a video playback device according to Embodiment 3 of the present invention.
FIG. 5 is a schematic diagram showing the operation of the video playback device according to Embodiment 3 during double-speed playback.
FIG. 6 is a block diagram of a video playback device according to Embodiment 4 of the present invention.
FIG. 7 is a diagram illustrating a portion that performs an effective operation when an N × speed reproduction mode according to the configuration of the third embodiment is selected.
FIG. 8 is a diagram illustrating a portion that performs an effective operation when an N × speed reproduction mode according to the configuration of the first embodiment is selected.
FIG. 9 is a block diagram of a video device according to Embodiment 5 of the present invention.
FIG. 10 is a block diagram of an image reproducing apparatus according to Embodiment 6 of the present invention.
FIG. 11 is a block diagram of a video playback device according to Embodiment 7 of the present invention.
FIG. 12 is a configuration diagram showing a conventional video playback device.
[Explanation of symbols]
Reference Signs List 11 recording medium, 12 image data decompression unit, 13 image reading skipping unit, 14 buffer unit, 15 D / A conversion unit, 16 image display unit, 17 N-times speed reproduction instruction detection unit, 18 N-times frequency vertical synchronization signal generation unit, Reference Signs List 19 system clock generation unit, 20 horizontal synchronization signal generation unit, 21 vertical synchronization signal generation unit, 23 decoding clock generation unit, 31 image readout signal, 32 image skipping unit input data, 33 image skipping unit output data, 34 buffer reading Signal, 35 buffer read data, 51 vertical sync signal for normal playback, 52 display image for normal playback, 53 vertical sync signal for 2x speed playback, 54 display image for 2x speed playback, 61 image read sync signal selector , 62 data selector, 63 mode detector, 110 MPEG data, 112 MPEG frame structure identifier insertion Apparatus, 114 recording medium, 116 MPEG data with identifier inserted, 118 MPEG frame structure identifier detector.

Claims (9)

Synchronization signal generation means for generating a predetermined multiple synchronization signal having a frequency that is a predetermined multiple of the frequency of the reproduction synchronization signal during normal reproduction,
Image data decompression means for decompressing the compressed image data of the video and outputting in synchronization with the predetermined multiple synchronization signal;
Image thinning means for thinning out the image data output in synchronization with the predetermined times synchronization signal based on the playback synchronization signal at the time of the normal playback and outputting the thinned image to display means for display. Playback device. Further comprising a decoding clock generating means for generating a decoding clock having a frequency that is a predetermined multiple of the frequency during normal reproduction,
2. The video reproducing apparatus according to claim 1, wherein the decoding clock is input to the image data expanding means, and the image data expanding means expands the compressed image data of the video at a speed twice as fast as that of the normal reproduction. . The apparatus according to claim 11, further comprising: a predetermined-speed reproduction instruction detecting means for receiving a reproduction speed instruction from a user or the like and outputting an operation instruction for designating which of a frequency during normal reproduction and a predetermined multiple frequency is to be used. The video playback device according to claim 1. Synchronization signal generation means for generating a predetermined multiple synchronization signal having a frequency that is a predetermined multiple of the frequency of the reproduction synchronization signal during normal reproduction,
An image reproducing apparatus, comprising: image data expanding means for expanding compressed image data of an image and outputting the image data in synchronization with the predetermined times synchronization signal. The apparatus according to claim 11, further comprising a predetermined-speed reproduction instruction detecting means for receiving an instruction from a user or the like to output an operation instruction for designating which of a frequency at the time of normal reproduction and a predetermined multiple frequency is to be used. 3. The video reproducing apparatus according to 3. Mode detection means for determining whether or not the image display unit can be displayed even when the frequency is set to a predetermined multiple of that of the normal reproduction, selecting an operation mode and outputting a mode notification,
In response to the mode notification from the mode detecting means, an image to be output as a read signal by selecting one of a synchronizing signal having a frequency at the time of normal reproduction from the synchronizing signal generating means and a predetermined times synchronizing signal having a predetermined frequency Read synchronization signal selection means,
In accordance with the mode notification from the mode detection means, further comprising a data selection means for selecting any of the image data from the image data expansion means and the image data from the image thinning means,
The image data decompression means synchronizes with the read synchronization signal from the image read synchronization signal selection unit, decompresses and outputs compressed image data of the video,
The synchronizing signal generating means generates a synchronizing signal having a frequency at the time of normal reproduction and a synchronizing signal having a frequency which is a predetermined multiple of the frequency at the time of normal reproduction in response to the mode notification from the mode detecting means. 2. The video reproduction device according to 1. A predetermined speed reproduction instruction detecting means for receiving a reproduction speed instruction from a user or the like and outputting an operation instruction for specifying which of the frequency at the time of normal reproduction and the frequency of the predetermined times is used;
Further comprising a decoding clock generating means for generating a decoding clock having a frequency that is a predetermined multiple of the frequency during normal reproduction,
7. The video reproducing apparatus according to claim 6, wherein the decoding clock is input to the image data expanding unit, and the image data expanding unit expands the compressed image data of the video at a speed twice as fast as that of the normal reproduction. . The mode detection means further determines whether or not the image data decompression means can decode in synchronization with a readout signal of a predetermined frequency from the image readout synchronization signal selection means,
7. The video reproducing apparatus according to claim 6, wherein when decoding is not possible, the image data decompression means thins out the image data and decodes only a part of the image data. A predetermined-speed reproduction instruction detecting means for receiving a reproduction speed instruction from a user or the like and outputting an operation instruction for designating which of a frequency at the time of normal reproduction and a frequency of a predetermined multiple is to be used,
The mode detection means further determines whether or not the image data decompression means can decode in synchronization with a readout signal of a predetermined frequency from the image readout synchronization signal selection means,
7. The video reproducing apparatus according to claim 6, wherein when decoding is not possible, the image data decompression means thins out the image data and decodes only a part of the image data.

Images