JP2006129103A - Video apparatus and video system corresponding to network - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video apparatus corresponding to a network which can enlarge a function capable of controlling through the network and a video system corresponding to the network including this apparatus without adding an operation side apparatus for transmitting a control command through the network. <P>SOLUTION: The video apparatus 21 corresponding to the network includes an HDD 1 which stores moving image data, an HDD 2 which stores a GUI screen as a screen data file, an MPEG-2 encoder 5 which compresses and encodes screen data read from the HDD 2 to output it as a TS, an IEEE1394 interface 8 which sends the input TS as an isochronous stream on the network, switching means 6 for switching the TS input into the IEEE1394 interface 8 to either TS outputted from the MPEG-2 encoder 5 or the TS from the HDD 1, and system control means 7 for controlling the operation of the switching means 6. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a network-compatible video device that transmits a transport stream (TS) and receives a control command via a network, and a network-compatible video system including the device, and more particularly to a network compatible network from an operation-side device via a network. The present invention relates to generation and transmission of a graphical user interface (GUI) screen signal used when operating video equipment.

  Accompanying the digitization of audio visual (AV) devices such as televisions (TVs) and video tape recorders (VTRs), devices are connected via an IEEE 1394 network, and control target devices (for example, digital TVs) , A method for controlling a digital VTR) is widely used. For example, a digital TV and a digital VTR (for example, a D-VHS system VTR) are connected via an IEEE 1394 network, a digital VTR operation GUI screen is displayed on the digital TV, and an operation according to the GUI screen is performed using a remote control. Thus, functions such as playback and recording of the digital VTR are controlled. In general, data for generating a GUI for operating a digital VTR is incorporated in the digital TV in advance, and the digital VTR is converted from the digital TV according to the audio video / control (AV / C) command standard defined in the 1394 Trade Association (1394TA). A method of sending a control command via the IEEE 1394 network is adopted.

  However, in this method, it is not possible to operate a control target device other than a device in which GUI generation data is pre-installed in the digital TV, and a new function not supported by the digital TV is added to the control target device. In such a case, the new function cannot be operated from the digital TV. In addition, when a control target device other than a device in which data related to a control method or GUI generation data is previously incorporated is connected to the digital TV, the control target device cannot be operated from the digital TV at all.

  In order to solve such problems, each AV device holds the graphic display data in a distributed manner, transmits the graphic display data in response to a request from the digital TV as the operation side device, and the digital TV responds to the request. There has been proposed a graphic data distributed AV system in which only the graphic display is performed (see, for example, Patent Document 1).

  In addition, a DVD (digital versatile disc) player, which is a device to be controlled, is connected to a digital TV, which is an operation side device, via an IEEE 1394 network, and the DVD player performs video / audio through IEEE 1394 standard isochronous transmission (synchronous channel). Bitmap image information obtained by sending a signal and processing sub-picture pack information and sub-picture screen control information are transmitted through asynchronous transmission (asynchronous channel), and the digital TV responds to the sub-picture according to the screen control information. A method of synthesizing and outputting a video signal after synchronizing and positioning is proposed (for example, see Patent Document 2).

Japanese Patent Laid-Open No. 09-149325 (FIGS. 1 to 4) Japanese Unexamined Patent Publication No. 2003-116088 (FIG. 3)

  In the above-described conventional technology, the control target device is operated even if the GUI generation data for operating the control target device (for example, digital VTR) is not previously incorporated in the operation side device (for example, digital TV). Is possible. However, in order to realize such a function, the procedure and format for transmitting the GUI generation data between the operation side device and the control target device are determined, and the operation side device receives the GUI generation data. , It is necessary to incorporate a mechanism for synthesizing and generating GUI generation data with a video signal in advance, and the existing digital TV cannot be used as an operation side device unless the digital TV is changed. was there.

  In the above-described prior art, when it is necessary to frequently update bitmaps and still images for configuring the GUI screen, a large amount of GUI generation data is transmitted from the control target device to the operation side device through asynchronous transmission. There is also a problem that it is necessary to transmit, and the load of internal processing of both the control target device and the operation side device increases.

  Therefore, an object of the present invention is to transmit a graphical user interface screen data as a transport stream to the operation side device via a network, thereby enabling a function that can be operated by the operation side device without changing the operation side device. An object of the present invention is to provide a network compatible video device that can be expanded and a network compatible video system including the device.

  Another object of the present invention is to provide a network-compatible video device capable of transmitting a large amount of data for a graphical user interface screen while suppressing an increase in the internal processing load of the device, and a network-compatible video system including the device. Is to provide.

  A network-compatible video device according to the present invention receives a control command via a network, and stores screen data storage means for storing a graphical user interface screen generated in advance as a screen data file, and the screen data storage means. Screen data read control means for reading screen data, image compression encoding means for compressing and encoding the screen data read by the screen data read control means, and outputting it as a transport stream, and an input transport stream Interface means for transmitting the data as an isochronous stream on the network, and the transport stream input to the interface means as a transport stream output from the image compression encoding means or other Based on a switching means for switching to any one of the transport streams and a control command received via the network, operations of the screen data reading control means, the image compression encoding means, the interface means, and the switching means are controlled. System control means.

  The network compatible video system according to the present invention displays an image based on the network compatible video device and a transport stream transmitted from the network compatible video device via the network, and sends a control command to the network compatible video device. And an operating device that transmits via a network.

  According to the present invention, since the graphical user interface screen is isochronously transmitted as a transport stream via a network, any device that can receive and decode the transport stream without any change can be used without changing the operation side device. A new graphical user interface screen can be displayed on the operation side device, and the function that can be operated by the operation side device can be expanded.

  Also, according to the present invention, since the graphical user interface screen data is isochronously transmitted as a transport stream via a network, a large amount of graphical user interface screen data can be transmitted while suppressing an increase in the internal processing load of the device. The effect that it can transmit can be acquired.

  Further, in the present invention, when a transport stream including data corresponding to a graphical user interface is generated by combining pre-created I-frame data and P-frame data, image compression encoding means operating in real time Therefore, the cost of the network compatible video equipment and the network compatible video system can be reduced.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a block configuration of a disc player 21 that is a network-compatible video device according to Embodiment 1 of the present invention, a digital TV 9 that is an operation side device, and a remote controller 10.

  As shown in FIG. 1, the disc player 21 is a control target device (for example, a video recording / reproducing device) that receives a control command from the digital TV 9 via a communication line 50 configuring an IEEE 1394 network. In addition, the disc player 21, the digital TV 9, and the remote controller 10 constitute a network-compatible video system according to the first embodiment. Note that the communication line 50 constituting the IEEE 1394 network may be either wired or wireless. Further, the disc player 21 and the digital TV 9 may be indirectly connected via other devices. Further, a network other than the IEEE 1394 network may be adopted as the network. Furthermore, the user may operate an operation unit (not shown) provided in the main body of the digital TV 9 instead of the remote controller 10.

  As shown in FIG. 1, the disc player 21 is a hard disk drive that is a stream storage means for storing a video signal displayed on the screen of a digital TV 9 connected to a network as an MPEG-2 transport stream (TS). (HDD) 1 and a hard disk drive (HDD) 2 which is a screen data storage means for storing data for generating a graphical user interface (GUI) (GUI generation data) as a GUI source. Further, the disc player 21 compresses and encodes the GUI generation data read by the read control means 3 for reading the transport stream from the HDD 1, the read control means 4 for reading data from the HDD 2, and the read control means 4, And an MPEG-2 encoder 5 which is an image compression encoding means for outputting as a transport stream. In the first embodiment, the GUI generation data stored in the HDD 2 is a graphics data file such as BMP (bitmap) or GIF (graphic interchange format).

  Furthermore, as shown in FIG. 1, the disc player 21 has an IEEE 1394 interface 8 which is an interface means for sending an input transport stream as an isochronous stream over a network, and a transport stream input to the IEEE 1394 interface 8. Is switched to either the transport stream read from the HDD 1 by the read control means 3 or the transport stream output from the MPEG-2 encoder 5. Further, the disc player 21 is generated based on the operation of the remote controller 10 and based on control commands received via the network, the read control means 3 and 4, the MPEG-2 encoder 5, the IEEE 1394 interface 8, and the switching means 6. System control means 7 for controlling the operation is provided. In the above description, the HDD 1 that stores the video / audio signal and the HDD 2 that stores the GUI generation data are described as separate HDDs, but the video / audio signal data and the GUI generation data are stored in the same HDD. Also good. In the above description, the case where the storage unit is an HDD has been described. However, other types of storage unit such as an optical disk or a semiconductor memory may be used as the storage unit.

  The IEEE 1394 interface 8 of the disc player 21 is connected to an IEEE 1394 interface (not shown) of the digital TV 9 via a communication line 50 constituting an IEEE 1394 network. The digital TV 9 receives a signal from the remote controller 10 operated by the user, and operates according to the operation of the remote controller 10. Further, the digital TV 9 receives a signal from the remote controller 10, generates a control command according to the operation of the remote controller 10, and sends it to the IEEE 1394 interface 8 of the disc player 21 by asynchronous transfer in the IEEE 1394 network. The control command received by the IEEE 1394 interface 8 is sent to the system control means 7 and used for controlling the read control means 3 and 4, the MPEG-2 encoder 5, and the switching means 6.

  When the MPEG-2 transport stream stored in the HDD 1 is displayed on the digital TV 9, the switching unit 6 selects the read control unit 3 based on the control signal from the system control unit 7, and the read control unit 3 selects the HDD 1. The MPEG-2 transport stream read from is sent to the IEEE 1394 interface 8. The IEEE 1394 interface 8 transmits the input MPEG-2 transport stream to the digital TV 9 by isochronous transfer via the network, and the digital TV 9 displays an image based on the received MPEG-2 transport stream.

  When displaying the GUI screen based on the GUI generation data stored in the HDD 2 on the digital TV 9, the switching unit 6 selects the MPEG-2 encoder 5 based on the control signal from the system control unit 7. The read control means 4 reads the GUI generation data from the HDD 2, and the MPEG-2 encoder 5 converts the GUI generation data into an MPEG-2 transport stream and sends it to the IEEE 1394 interface 8. The IEEE 1394 interface 8 transmits the input MPEG-2 transport stream to the digital TV 9 by isochronous transfer via the network, and the digital TV 9 displays a GUI screen based on the MPEG-2 transport stream.

  2 is a diagram showing an example of a GUI screen displayed on the digital TV 9 in the first embodiment, and FIG. 3 is a diagram showing another example of the GUI screen displayed on the digital TV 9 in the first embodiment. is there.

  A digital TV having an IEEE 1394 interface that is currently popular is generally designed assuming a D-VHS VTR as a video storage device. Therefore, a general video storage device that is currently commercialized has previously incorporated GUI screen data for D-VHS VTR operation on the digital TV side, and is an AV / C tape that is an AV / C command standard defined in 1394TA. In accordance with the recorder player subunit specification (AV / C Tape Recorder / Player Subunit Specification), a method of sending a control command from the digital TV to the D-VHS VTR via the IEEE 1394 network is adopted. At this time, for example, an operation screen as shown in FIG. 2 is displayed on the digital TV 9. One of the operations is selected by the button operation of the remote controller 10 to control the D-VHS system VTR. For example, the playback button 32 is selected using the remote controller 10 (at this time, the brightness or color of the playback button 32 is changed) and pressed (that is, the determination button or the like of the remote control 10 is pressed), so that the D-VHS system VTR is selected. In response to this, a playback control command is sent. The operation of the D-VHS VTR is limited to playback 32, stop 31, pause 33, fast forward 34, reverse fast forward 30 and the like based on the AV / C command standard.

  However, video storage devices (for example, HDD recorders, DVD recorders, etc.) with different functions using different types of recording media such as disks (HDD, DVD, etc.) instead of magnetic tape have begun to spread in the market. Yes. A video storage device that uses a disk-shaped recording medium is defined by AV / C disk subunit general specification (AV / C Disc Subunit General Specification), which is an AV / C command standard. However, normally, GUI screen data mounted on a digital TV is for D-VHS VTR control.

  In the first embodiment, a control command based on a user's remote control operation is sent from the digital TV 9 to the IEEE 1394 interface 8 by asynchronous transfer via the IEEE 1394 network. The control command received by the IEEE 1394 interface 8 is sent to the system control unit 7, and the system control unit 7 generates an appropriate control signal according to the command and supplies the GUI or the stored video / audio stream to the IEEE 1394 interface 8. It is delivered from the IEEE1394 interface 8 to the digital TV 9 by isochronous transfer.

  For example, when the user presses the play button 32 using the remote controller 10 when the disc player 21 is in the stopped state, the content list stored in the HDD 1 is displayed on the screen of the digital TV 9 to display the content. Allows selection operation.

  That is, when the system control means 7 receives a playback command in the stopped state, a list of contents stored in the HDD 1 is found from the files stored in the HDD 2, and the list is converted into an MPEG-2 transport stream in advance. In this case, the file is sent directly to the switching means 6, and in the case of other files, it is converted into an MPEG-2 transport stream through the MPEG-2 encoder 5 and then input to the switching means 6. The switching means 6 selects an MPEG-2 transport stream corresponding to the content list screen and transmits it from the IEEE 1394 interface 8. At this time, the digital TV 9 receives the MPEG-2 transport stream that the disc player 21 sends out from the IEEE 1394 interface 8 by isochronous transfer, and displays it on the screen. In order to start reproduction in this way, a content list GUI is first displayed. Subsequently, for example, when the user presses the fast-forward button 34 using the remote controller 10, a fast-forward command is sent from the digital TV 9 to the disc player 21, but when a content list is displayed, the system control means 7 is regarded as a content selection operation and changes the GUI screen.

  For example, the content list shown in FIG. 3 indicates that the content “1. xxx news” is selected. In the first embodiment, each time a selection operation is performed with the remote controller 10 (for example, the fast-forward button on the remote controller 10 is pressed), the selected content is “2. Professional baseball broadcast OO vs. □□”, “3. The movement is performed in the order of “gymnastics”, and the selected content is selected (for example, a playback button on the remote controller 10 is pressed) in a state where the desired content is selected, thereby starting playback of the selected content. The GUI screen used here prepares as many content GUIs as the number of contents in advance, and whenever the selection command is received, the system control means 7 issues a command to the read control means 4 to update the file to be read. Alternatively, one content list screen is prepared, and the selected part (for example, “1. XXX News” or “2. Professional Baseball Relay XX vs. □”) where the content item is displayed. ) May be changed and created.

  In this way, the GUI screen is sent to the digital TV 9 as an MPEG-2 transport stream, and the control command from the digital TV 9 is limited to AV / C commands for operating the D-VHS system VTR, so that it has already spread to the market. A network-compatible video system that can easily operate the new functions of the video storage device connected to the network using the remote control 10 of the digital TV 9 can be constructed without modifying the digital TV.

  As described above, in the network compatible video device and the network compatible video system according to the first embodiment, the GUI screen is isochronously transmitted as a transport stream via the network, so that the operation side device receives the transport stream. If it is a device capable of decoding, it is possible to operate a network-compatible video device by displaying a new GUI screen on the operating device without changing the operating device.

  Further, in the network compatible video device and the network compatible video system according to the first embodiment, the GUI screen is isochronously transmitted as a transport stream via the network. GUI screen data can be transmitted.

Embodiment 2. FIG.
FIG. 4 is a diagram showing a block configuration of a disc player 22 that is a network-compatible video device according to Embodiment 2 of the present invention, a digital TV 9 that is an operation side device, and a remote controller 10. In FIG. 4, the same reference numerals are given to the same or corresponding components as those in FIG. The disc player 22 according to the second embodiment is characterized in that the HDD 2 stores GUI generation data as a transport stream and does not include an MPEG-2 encoder. 21.

  As shown in FIG. 4, the disc player 22 includes an HDD 1 that stores a video signal displayed on a screen of a digital TV 9 connected to a network as an MPEG-2 transport stream, and an MPEG data for generating a GUI. -2 It has HDD2 which accumulate | stores as a transport stream, the read control means 3 which reads a transport stream from HDD1, and the read control means 4 which reads a transport stream from HDD2.

  Further, as shown in FIG. 4, the disc player 22 receives the IEEE 1394 interface 8 which is an interface means for sending the input transport stream as an isochronous stream on the network, and the transport stream input to the IEEE 1394 interface 8. Switching means 6 for switching between the transport stream read from the HDD 1 by the read control means 3 and the transport stream read from the HDD 2 by the read control means 4. Further, the disc player 22 has system control means 7 for controlling operations of the read control means 3 and 4, the IEEE 1394 interface 8, and the switching means 6 based on a control command received via the network.

  Since the disc player 22 according to the second embodiment does not perform image compression encoding, there is an advantage that the hardware scale can be reduced. In the second embodiment, points other than those described above are the same as those in the first embodiment.

Embodiment 3 FIG.
FIG. 5 is a diagram showing a block configuration of a disc player 23 that is a network-compatible video device according to Embodiment 3 of the present invention, a digital TV 9 that is an operation side device, and a remote controller 10. In FIG. 5, the same or corresponding components as those in FIG. 1 or FIG. In the disc player 23 according to the third embodiment, the HDD 2 stores the GUI generation data as a graphics data file such as BMP or GIF and / or a data file converted into an MPEG-2 transport stream. This is different from the disc player 21 according to the first embodiment in that it does not include an MPEG-2 encoder.

  As shown in FIG. 5, the disc player 23 generates a GUI and a HDD 1 that is a stream storage unit that stores a video signal displayed on a screen of a digital TV 9 connected to a network as an MPEG-2 transport stream. As a graphics data file such as a bitmap or GIF and / or a data file that has been previously encoded and compressed according to the MPEG-2 video standard and converted into an MPEG-2 transport stream It has an HDD 2 as screen data storage means for storing, a read control means 3 for reading a transport stream from the HDD 1, and a read control means 4 for reading a transport stream from the HDD 2.

  Further, as shown in FIG. 1, the disc player 23 has an IEEE 1394 interface 8 which is an interface means for sending the input transport stream as an isochronous stream on the network. Further, the disc player 23 can transport a transport stream input to the IEEE 1394 interface 8 from the HDD 1 by the read control unit 3, a transport stream read from the HDD 2 by the read control unit 4, or And a switching means 6 for switching to one of the transport streams read from the HDD 2 by the read control means 4 and converted by the MPEG-2 encoder 5. Furthermore, the disc player 23 performs operations of the read control means 3 and 4, the MPEG-2 encoder 5, the IEEE 1394 interface 8, and the switching means 6 based on a control command received via the network in accordance with the operation of the remote controller 10. It has system control means 7 for controlling.

  According to the disc player 23 according to the third embodiment, the load on the MPEG-2 encoder 5 can be reduced by previously compressing and encoding the GUI screen that is frequently used, so that the hardware of the MPEG-2 encoder 5 can be reduced. The wear scale can be reduced. In the third embodiment, points other than the above are the same as in the first or second embodiment.

Embodiment 4 FIG.
FIG. 6 is a diagram showing a block configuration of a disc player 24 that is a network-compatible video device according to Embodiment 4 of the present invention, a block configuration of a digital TV 9 that is an operation side device, a remote control unit 14, and a remote controller 10. . In FIG. 6, the same or corresponding components as those in FIGS. 1 to 3 are denoted by the same reference numerals.

  As shown in FIG. 6, the disc player 24 according to the fourth embodiment has the same configuration as the disc player 23 according to the third embodiment. Further, the network compatible video system according to the fourth embodiment is obtained by adding a remote control unit 14, a digital television 9, and a remote controller 10A to the disc player 24. However, the disc player 24 according to the fourth embodiment may have the same configuration as the disc players described in the first and second embodiments and in the fifth to seventh embodiments described later.

  As shown in FIG. 6, the remote control unit 14 includes a remote control light receiving unit 13 that receives an infrared pulse from the remote control 10, a control signal generation unit 12 that generates a control command, and an IEEE 1394 interface 11. The remote control light receiving unit 13 receives a signal transmitted from the remote control 10 when the user performs a remote control operation, converts the signal to the control signal generation unit 12 and sends the electric signal. The control signal generation means 12 converts it into a control command corresponding to the received remote control signal, outputs it to the IEEE 1394 interface 11, and transmits the command to the disc player by IEEE 1394 asynchronous transfer. The command sent here may be based on the above-mentioned AV / C command standard or may be newly defined uniquely.

  The introduction of the remote control unit 14 not only controls the disc player through limited commands such as playback, stop, fast forward, etc. sent from the digital TV 9 to the disc player 24 by remote control operation, but also supports buttons mounted on the remote control 10A. Thus, it is possible to freely define the correspondence between the command and the operation of the disc player. For example, in the first embodiment, content selection is performed in a control user interface unique to a digital TV by using a playback or fast-forward command that is a user interface used when controlling a D-VHS VTR. With the addition of the remote control unit 14, a selection button (up arrow button, down arrow button, left arrow button, right arrow as shown in the remote control 10A in FIG. Button and a decision button arranged in the middle of the arrow button) can be transmitted to the disc player, so that the options displayed on the GUI can be easily moved and selected, making it easier to understand and easier to use. A good user interface can be provided. Therefore, it is possible to perform control corresponding to various new functions using the TV remote controller without modifying the digital TV 9. The fourth embodiment is the same as the first to third embodiments except for the points described above.

Embodiment 5. FIG.
FIG. 7 is a block diagram showing a configuration of a disc player 25 that is a network-compatible video device according to Embodiment 5 of the present invention. FIG. 8 is an explanatory diagram showing a frame configuration used in the network compatible video equipment according to the fifth embodiment. In FIG. 7, the same or corresponding components as those in FIG. 1 are denoted by the same reference numerals.

  As shown in FIG. 7, the disc player 25 stores the HDD 1 that stores the video signal displayed on the screen of the digital TV 9 connected to the network as an MPEG-2 transport stream, and the data of the GUI screen generated in advance. The HDD 2 stores the compressed and encoded data as an I (intra) frame data file in the MPEG standard, and stores a P frame (predictive) data file generated under a preset condition. The disc player 25 is read by the I frame read control means 32 for reading I frame data from the HDD 2, the P frame read control means 31 for reading P frame data from the HDD 2, and the I frame read control means 32. Frame synthesizing means 30 for synthesizing I frame data and P frame data read by the P frame reading control means 31, and transport stream forming means 33 for converting the output of the frame synthesizing means 30 into a transport stream. Have.

  Further, the disc player 25 transmits the input transport stream as an isochronous stream on the network and the transport stream input to the IEEE 1394 interface 8 as a transport stream or a transport read from the HDD 1. Switching means 6 for switching to one of the transport streams output from the port stream forming means 33, and a read control means 3, an I frame read control means 32, and a P frame read control means based on a control command received via the network 31, frame synthesizing means 30, interface means 8, and system control means 7 for controlling the operation of switching means 6.

  In the first to fourth embodiments, the GUI generation data is stored as an image file in the HDD 2 and converted into an MPEG-2 transport stream by the MPEG-2 encoder 5 or sent out to the HDD 2 in advance. It is assumed that two transport streams are accumulated. In the fifth embodiment, instead of the MPEG-2 encoder 5, a frame synthesizing unit 30 that is an MPEG-2 stream synthesizing unit is used, and the HDD 2 stores each screen constituting the GUI as an I frame in MPEG-2 video. In addition, the portion corresponding to the P frame following the I frame is stored separately.

  In MPEG-2 video encoding, generally, motion prediction is performed between data of an I frame that is encoded using only data in a certain frame and data of a preceding frame, and a prediction error is encoded together with a motion vector. An encoded video bitstream composed of a frame and a B (bi-directionally predictive) frame that encodes a prediction error and a motion vector obtained by performing bidirectional motion prediction using the preceding and succeeding frames is formed. At this time, dozens of P frames or B frames are inserted between the I frame and the next I frame, and one or two B frames are inserted between the I frame and the following P frame or consecutive P frames. It is common. A set of frames inserted from an I frame to the next I frame is called a 1 GOP (Group of Pictures). An MPEG-2 video stream is configured in such a form that GOPs are continuously connected. In the encoding of moving images, since images differ from frame to frame, it is necessary to continuously encode all frames. However, in the case of a GUI screen, the image of each frame does not necessarily change. In the case of the GUI screen, the still image is continuously displayed until an input from the user is received, and the next GUI screen may be determined based on the user's operation. Therefore, a GUI screen stream can be generated by encoding each GUI screen to be displayed as an I frame, reading I frame data corresponding to a necessary GUI screen, and sending it out. In this case, since the frame rate of the video signal decoded and displayed by the digital TV is generally set to 29.97 Hz or the like, it is necessary to send only 29.97 frames per second. In MPEG-2 video encoding, the code amount of each frame generally increases in the order of B frame, P frame, and I frame. For this reason, the amount of code required to maintain a constant image quality is greatly increased when a stream is composed of only I frames, compared to the case where there are B frames and P frames using motion compensation prediction. In constructing a network-compatible user interface, as the code amount increases, the network bandwidth required for GUI screen data transmission becomes wider, and higher-speed processing is required for sending GUI screen data. become. Therefore, in the fifth embodiment, a GOP including a plurality of P frames followed by an I frame is configured by the following method, and an MPEG-2 video stream for a GUI screen is continuously sent out while suppressing the code amount.

  In P frame encoding, motion detection is performed between the immediately preceding I frame or P frame, and compensation is performed according to the motion vector for each macroblock which is one of the encoding units. Are subjected to DCT (discrete cosine transform) as a prediction error, and are encoded into a video stream together with a motion vector. Here, when a still image is encoded as in the case of the GUI screen, the same image continues, so the motion vectors are all 0 and the prediction error is almost 0. In actual MPEG-2 video coding, since the preceding frame which is a reference for obtaining the prediction error is not an original image but an image decoded after the coding is used, even if a still image is coded by MPEG-2 video, the prediction is performed. Although the error is not 0, the P frame is encoded with the motion vector and the prediction error set to 0 here. When MPEG-2 video encoding is performed with one I frame followed by a plurality of P frames as 1 GOP by this method, the code of the P frame becomes irrelevant to the I frame, and all the same data if the image size is the same. It becomes a column.

  For example, as shown in FIG. 8, when a GOP is formed by connecting five P frames 200 to I frames 100, 101, 102, 103, 104,..., All GOPs depend on the I frame. However, the same P frame data is inserted. At this time, since the P frame 200 is encoded with both the prediction error and the motion vector being 0, the data amount is significantly smaller than that of the I frame. Therefore, a portion corresponding to a P frame of a video stream that is encoded with 0 as both a prediction error and a motion vector is extracted in advance, and the extracted P frame data is connected to GUI data encoded as an I frame to form a GOP. By doing so, an MPEG-2 video stream with a frame rate of 29.97 Hz can be generated while suppressing the amount of generated codes. The video stream obtained in this way is inserted into the MPEG-2 transport stream by an MPEG-2 system multiplexer or the like and then sent to the digital TV through the IEEE 1394 interface.

  In the fifth embodiment, based on the control from the system control means 7, the I frame stored in the HDD 2 is read from the I frame read control means 32, and the P frame is read out from the P frame read control means 31. This is supplied to the frame synthesizing means 30. The I / P frame synthesizing unit 30 composes a GOP by synthesizing the I frame and the P frame, and outputs the GOP to the transport stream forming unit 33. The transport stream forming unit 33 converts the video stream into a transport stream and supplies it to the IEEE 1394 interface 8 via the switching unit 6. It should be noted that the I frame and the P frame need not be created in real time, and can be performed by software processing using a general-purpose processor without a dedicated hardware MPEG-2 encoder.

  In this way, necessary GUI screens are encoded and stored in advance as I frames, and P frames are prepared with both prediction errors and motion vectors encoded as 0, and an appropriate GUI screen is set as an I frame according to the control target device. By selecting and combining with the prepared P frame data, an MPEG-2 video stream that can be decoded and displayed on a digital TV simply by reading and combining stored data without using an MPEG-2 video encoder. The cost required for hardware construction can be reduced. The fifth embodiment is the same as the first to fourth embodiments except for the points described above.

Embodiment 6 FIG.
FIG. 9 is a block diagram showing a configuration of a disc player 26 that is a network-compatible video apparatus according to Embodiment 6 of the present invention. 9, the same reference numerals are given to the same or corresponding components as those in FIG.

  As shown in FIG. 9, the disc player 26 stores the HDD 1 that stores the video signal displayed on the screen of the digital TV 9 connected to the network as an MPEG-2 transport stream, and the GUI screen data generated in advance. An HDD 2 that stores the compressed and encoded data as an I-frame data file in the MPEG standard, and stores it as a transport stream file in which the P-frame data generated under a preset condition is inserted into the payload of the transport stream. Have. Further, the disc player 26 includes an I frame read control unit 32 that reads I frame data from the HDD 2 and a P frame read control unit 31 that reads a transport stream including P frame data from the HDD 2. Further, the disc player 26 includes an I frame insertion unit 36 that generates a transport stream in which the I frame data output from the I frame read control unit 32 is inserted into the payload, and an I frame output from the I frame insertion unit 36. A transport stream including frame data and a transport stream including P frame data output from the P frame reading control unit 31 and a transport stream connecting unit 37 for inserting system information; Time information updating means 38 for updating time information included in the transport stream output from the means 37.

  Further, the disc player 26 transmits the input transport stream as an isochronous stream on the network, and the transport stream input to the IEEE 1394 interface 8 as a transport stream read from the HDD 1 or Based on the switching means 6 for switching to any one of the transport streams output from the transport stream connecting means 37, and the control command received via the network, the read control means 3, the I frame read control means 32, the P frame read control The system 31 controls the operation of the means 31, the I frame inserting means 36, the transport stream connecting means 37, the time information updating means 38, the interface means 8, and the switching means 6. And a beam control means 7.

  When a GUI screen encoded in an MPEG-2 video stream is transmitted to a digital TV via the IEEE1394 interface, it is converted into an MPEG-2 transport stream. At this time, a so-called MPEG-2 transport stream multiplexer is used to transmit the video stream to a table for transmitting system information such as PAT (Program Association Table), PMT (Program Map Table), and the clock timing on the transmission side. Time axis multiplexing with PCR (program clock reference) and so on. In the MPEG-2 transport stream, data is divided into 188-byte packets and transmitted. Each packet is given an ID number (PID: packet identifier) for each data to be transmitted. By designating a specific PID, one signal multiplexed in the transport stream can be extracted. The PMT describes the relationship between each component such as video of a program multiplexed in the transport stream and the PID. In addition, since a plurality of programs can be multiplexed in the transport stream, a PAT indicating the PID of the PMT corresponding to each program is inserted into the transport stream. The PAT PID is specified as 0 in the standard. When the transport stream is separated into each component on the decoding side, the PAT is first extracted, and the PMT PID of the desired program is found from the extracted PAT. Thereafter, the PMT is read to specify a PID such as a video. For this reason, the PAT and PMT must be inserted at the beginning of the transport stream.

  In addition, for video streams (referred to here as video elementary streams), PTS (packetized) is added with headers such as DTS (decoding time stamp) indicating the start timing of video decoding and PTS indicating the display timing of decoded frames. Elementary stream) and then inserted into the payload of the transport stream packet.

  As shown in the third embodiment, when a video stream is separated and stored in P frames encoded with both I frame, prediction error, and motion vector set to 0, the P frame portion is fixed and transported in advance. Prepare it by inserting it into the stream packet. For the I frame, every time it is read, a PES header is added and inserted into the transport stream packet. In forming the transport stream of the I frame portion, PCR is inserted at an appropriate interval. In addition, in order to make the bit rate of the transport stream to be transmitted constant, the number of transport stream packets in the I frame portion is fixed so as to have a larger payload capacity than all the accumulated I frames, and the I frame data portion After ending, the stuffing packet (PID: 1 fffh) is assumed. Here, by placing the PAT and PMT packets at the head and connecting the transport stream of the P frame portion to the transport stream of the I frame portion including the stuffing packet, a transport stream for 1 GOP can be easily generated. it can.

However, at this time, time information such as PCR, PTS, and DTS needs to be set to an appropriate value at the time of transport stream generation / transmission, but it is generated so that the bit rate of the transport stream is constant. If an appropriate PCR is set first, the next value can be easily obtained from the number of packets between two consecutive PCR insertion packets. Since the PCR is a value obtained by counting the clock of 27 MHz, for example, if the initial value PCR ₀ is inserted into the N _0th packet, the PCR ₁ that is the PCR value inserted into the N _1st packet is When the bit rate is BR, it can be calculated by the following equation.
PCR ₁ = PCR ₀ + (N ₁ −N ₀ ) × 188 × 8 × 27000000 / BR

PTS (presentation time stamp) and DTS can also be automatically determined from the initial value and the frame rate. PCR is divided into a base partial PCR _b and a lower partial PCR _e in units of 90 kHz (= 27000000/300) (ie, PCR = PCR _b × 90000 + PCR _e )
And inserted into the stream. The DTS and PTS are set with reference to the clock of the base portion 90 kHz. If the DTS value is DTS ₀ in a certain frame F ₀ , the following frame has the frame rate FR,
DTS ₁ = DTS ₀ + 900000 / FR
It becomes. As described above, when the GOP is composed of only the I frame and the P frame, the PTS may use a value obtained by adding a certain offset to the DTS. In setting the DTS, the PCR base value at the corresponding frame position is added with an offset.

  In the MPEG-2 transport stream, in addition to the time information described above, numbers are assigned in order of packets for each PID, and inserted into each packet with the continuity counter value. The value of the order number is also updated sequentially at the time of transmission.

  FIG. 10 is an explanatory diagram illustrating a configuration of a transport stream corresponding to 1 GOP generated in the network-compatible video equipment according to the sixth embodiment. A PAT packet 301 and a PMT packet 302 are inserted at the head of this stream. Subsequently, packets (TS1 to TSn) 303 to 305 having I frame data as a payload are created. Here, as described above, the number of packets 303 to 305 is fixed, and the packet after the insertion of the I frame data is a stuffing packet.

  In the sixth embodiment, the GUI generation data is stored in the HDD 2, and I frame data and P frame data are read using the read control means 31 and 32, respectively. Since the I frame data is stored as a video elementary stream (ES), the PES header is added using the I frame insertion means 36 and then inserted into the payload of the transport stream. Since the P frame data is stored in the HDD 2 in the form of a transport stream in advance, the data read through the P frame reading control means 32 is sent directly to the transport stream connecting means 37 and sent from the I frame inserting means 36. It is connected to a transport stream corresponding to the output I frame, and system information such as PAT and PMT is added. The GUI stream generated by the transport stream connecting unit 37 is input to the time information updating unit 38, and after the PCR, DTS, PTS, and continuity counter values are updated by the above method, the isochronous is transmitted from the IEEE1394 interface 8. Sent as a stream.

  As described above, in the sixth embodiment, I frame data prepared in advance is inserted into a payload of a preset transport stream, and P frame data, PAT, and PMT that have been converted into a transport stream form are connected. In addition, since the transport stream is obtained by sequentially updating the PCR, DTS, PTS, and continuity counter value, the MPEG-2 transport stream can be obtained without using dedicated hardware such as an MPEG-2 encoder / multiplexer. Can be generated, and the hardware cost of the system can be reduced. In the sixth embodiment, points other than the above are the same as those in the first to fifth embodiments.

Embodiment 7 FIG.
FIG. 11 is a block diagram showing a configuration of a disc player 27 that is a network-compatible video device according to Embodiment 7 of the present invention. 10, the same reference numerals are given to the same or corresponding components as those in FIG.

  As shown in FIG. 11, the disc player 27 stores the HDD 1 that stores the video signal displayed on the screen of the digital TV connected to the network as an MPEG-2 transport stream, and the data of the GUI screen generated in advance. The data is compressed and encoded as I frame data in the MPEG standard, stored as individual files for each slice in the I frame, and P frame data generated under preset conditions is used as the payload of the transport stream. And an HDD 2 which is a screen data storage means for storing as an inserted transport stream file. The disc player 27 connects the I frame slice reading means 39 for reading data of each slice of the I frame and the slice data read by the I frame slice reading means 39 to form an I frame slice. Update means 40, I frame insertion means 36 for generating a transport stream in which the data of the I frame generated by the I frame slice update means 40 is inserted in the payload, and P frame reading for reading out the transport stream including the P frame The control unit 31 connects the transport stream including the I frame data output from the I frame insertion unit 36 and the transport stream including the P frame data output from the P frame reading control unit 31, and system information The A transport stream coupling means 37 to enter, and a time information updating means 38 for updating the time information contained in the transport stream output from the transport stream coupling means 37.

  Further, the disc player 27 transmits the input transport stream as an isochronous stream on the network, and the transport stream input to the IEEE 1394 interface 8 as a transport stream or time read from the HDD 1. Based on the switching means 6 for switching to one of the transport streams output from the information update means 38 and the control command received via the network, the I frame slice reading means 39, the P frame reading control means 31, the I frame inserting means 36, a system for controlling operations of the I frame slice updating means 40, the transport stream connecting means 37, the time information updating means 38, the interface 8, and the switching means 6. And a control means 7.

  In MPEG-2 video encoding, each frame is generally divided into slices that are formed by arranging one row of macroblocks in the horizontal direction. FIGS. 12A and 12B are explanatory diagrams showing the configuration of slices in the fifth embodiment.

  In FIG. 11, the I frame data of the GUI screen is divided into slices and stored in the HDD 2. In outputting the GUI screen data as an MPEG-2 transport stream, first, all slices of the initial screen are read from the HDD 2 using the I frame slice reading means 39 and supplied to the I frame slice updating means 40. The I frame slice update unit 40 connects the slices of the received I frame to form an I frame and outputs it to the I frame insertion unit 36. The I frame insertion means 36 obtains the output converted into the transport stream, and the transport stream connection means 37 joins it with the P frame portion. The output of the transport stream connecting means 37 is delivered to the IEEE 1394 interface 8 via the time information updating means 38.

  When the user performs an operation, for example, when the selection position of the operation button display needs to be changed from FIG. 12A to FIG. 12B, the slice to be changed based on the control from the system control means 7 Data is read by the I frame slice reading means 39 and sent to the I frame slice updating means 40. The I frame slice update means 40 creates I frame data in which only the corresponding slice portion is changed, and outputs it to the I frame insertion means 36. FIGS. 12A and 12B show an example in which one screen is divided into seven slices 351 to 357. In GUI display, for example, only a part of the screen is often changed, such as when only the operation button display is changed according to the user's operation. In the example of FIGS. 12A and 12B, only the slice 356 is changed, and the other slices may be fixed. Therefore, by dividing the I frame into slices and accumulating them, and combining the accumulated data of each slice to form the I frame, I frame data in which a part of the GUI screen is changed can be generated.

  As described above, in the seventh embodiment, the I frame is divided into slices and stored. Therefore, when a large number of GUI screens that change a part of the screen are required, only the changed part of the slice data is displayed. As a result, it is possible to reduce the volume of data on the GUI screen. In the seventh embodiment, points other than the above are the same as those in the first to sixth embodiments.

It is a figure which shows the block structure of the disc player which is a network corresponding | compatible video equipment concerning Embodiment 1 of this invention, digital TV which is an operation side apparatus, and a remote control. 6 is a diagram illustrating an example of a GUI displayed on the digital TV in Embodiment 1. FIG. FIG. 10 is a diagram showing another example of a GUI displayed on the digital TV in the first embodiment. It is a figure which shows the block structure of the disc player which is a network corresponding | compatible video equipment concerning Embodiment 2 of this invention, digital TV which is an operation side apparatus, and a remote control. It is a figure which shows the block configuration of the disc player which is a network corresponding | compatible video equipment concerning Embodiment 3 of this invention, digital TV which is an operation side apparatus, and a remote control. It is a figure which shows the block configuration of the disc player which is a network corresponding | compatible video equipment concerning Embodiment 4 of this invention, the digital TV which is an operation side apparatus, the block configuration of a remote control unit, and a remote control. It is a block diagram which shows the structure of the disc player which is a network corresponding | compatible video equipment concerning Embodiment 5 of this invention. FIG. 10 is an explanatory diagram showing a frame configuration used in a network compatible video device according to a fifth embodiment. It is a block diagram which shows the structure of the disc player which is a network corresponding | compatible video equipment concerning Embodiment 6 of this invention. FIG. 20 is an explanatory diagram illustrating a configuration of a stream generated in a network compatible video device according to a sixth embodiment. It is a block diagram which shows the structure of the disc player which is a network corresponding | compatible video equipment concerning Embodiment 7 of this invention. (A) And (b) is explanatory drawing which shows the structure of the slice in the network corresponding | compatible video equipment concerning Embodiment 7. FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1, 2 Hard disk drive (HDD), 3, 4 Reading control means, 5 MPEG-2 encoder, 6 Switching means, 7 System control means, 8 IEEE1394 interface, 9 Digital TV (operation side apparatus), 10 Remote control, 11 IEEE1394 interface , 12 control signal generating means, 13 remote control light receiving section, 14 remote control control unit, 21 to 23, 25 to 27 disk player (network compatible video equipment, control target equipment), 31 I frame read control means, 32 P frame read control means 36 I-frame inserting means, 37 Transport stream connecting means, 38 Time information updating means, 39 I-frame slice reading means, 40 I-frame slice updating means, 50 Communication line.

Claims (12)

A network compatible video device that receives control commands via a network,
Screen data storage means for storing a graphical user interface screen generated in advance as a screen data file;
Screen data read control means for reading screen data from the screen data storage means;
Image compression encoding means for compressing and encoding the screen data read by the screen data reading control means, and outputting the compressed data as a transport stream;
Interface means for sending the input transport stream as an isochronous stream on the network;
Switching means for switching the transport stream input to the interface means to either the transport stream output from the image compression encoding means or another transport stream;
System control means for controlling operations of the screen data reading control means, the image compression encoding means, the interface means, and the switching means based on a control command received via the network. Network compatible video equipment. A network compatible video device that receives control commands via a network,
Screen data storage means for storing data obtained by compressing and encoding data of a graphical user interface screen generated in advance as a transport stream file;
Screen data read control means for reading a transport stream from the screen data storage means;
Interface means for sending the input transport stream as an isochronous stream on the network;
Switching means for switching the transport stream input to the interface means to either the transport stream read by the screen data read control means or another transport stream;
A network-compatible video apparatus comprising: system control means for controlling operations of the screen data reading control means, the interface means, and the switching means based on a control command received via the network. A network compatible video device that receives control commands via a network,
Pre-generated graphical user interface screen is stored as a screen data file and / or data obtained by compressing and encoding pre-generated graphical user interface screen data is stored as a transport stream file Screen data storage means to
Screen data read control means for reading screen data or a transport stream from the screen data storage means;
Image compression encoding means for compressing and encoding the screen data read by the screen data reading control means, and outputting the compressed data as a transport stream;
Interface means for sending the input transport stream as an isochronous stream on the network;
The transport stream input to the interface means is either a transport stream output from the image compression encoding means, a transport stream read by the screen data read control means, or another transport stream. Switching means for switching to
System control means for controlling operations of the screen data reading control means, the image compression encoding means, the interface means, and the switching means based on a control command received via the network. Network compatible video equipment. A network compatible video device that receives control commands via a network,
Screen data storage means for compressing and encoding pre-generated graphical user interface screen data and storing it as an I-frame data file in the MPEG standard, and storing a P-frame data file generated under preset conditions When,
I frame read control means for reading I frame data from the screen data storage means;
P frame read control means for reading P frame data from the screen data storage means;
Frame combining means for combining the data of the I frame read by the I frame read control means and the data of the P frame read by the P frame read control means;
Transport stream forming means for converting the output of the frame synthesizing means into a transport stream;
Interface means for sending the input transport stream as an isochronous stream on the network;
Switching means for switching the transport stream input to the interface means to either the transport stream output from the transport stream forming means or another transport stream;
System control means for controlling operations of the I frame read control means, the P frame read control means, the frame synthesis means, the interface means, and the switching means based on a control command received via the network. A network-compatible video device. A network compatible video device that receives control commands via a network,
Pre-generated graphical user interface screen data is compressed and encoded and stored as an I-frame data file in the MPEG standard, and P-frame data generated under preset conditions is inserted into the payload of the transport stream Screen data storage means for storing as a transport stream file,
I frame read control means for reading I frame data from the screen data storage means;
P frame read control means for reading a transport stream including P frame data from the screen data storage means;
I frame insertion means for generating a transport stream in which I frame data output from the I frame read control means is inserted into a payload;
A transport for connecting a transport stream including I frame data output from the I frame insertion means and a transport stream including P frame data output from the P frame reading control means and inserting system information Stream connection means;
Time information updating means for updating time information included in the transport stream output from the transport stream connecting means;
Interface means for sending the input transport stream as an isochronous stream on the network;
Switching means for switching the transport stream input to the interface means to either the transport stream output from the time information update means or another transport stream;
Based on a control command received via the network, the operations of the I frame read control means, the P frame read control means, the I frame insertion means, the transport stream connecting means, the interface means, and the switching means are performed. Network-compatible video equipment, comprising: system control means for controlling. A network compatible video device that receives control commands via a network,
Pre-generated graphical user interface screen data is compressed and encoded into I-frame data according to the MPEG standard, stored as individual files for each slice in the I-frame, and generated under preset conditions Screen data storage means for storing P frame data as a transport stream file inserted in the payload of the transport stream;
I frame slice reading means for reading data of each slice of the I frame;
I frame slice update means for joining the slice data read by the I frame slice read means to form an I frame;
I frame insertion means for generating a transport stream in which I frame data generated by the I frame slice update means is inserted into a payload;
P frame read control means for reading a transport stream including the P frame;
A transport for connecting a transport stream including I frame data output from the I frame insertion means and a transport stream including P frame data output from the P frame reading control means and inserting system information Stream connection means;
Time information updating means for updating time information included in the transport stream output from the transport stream connecting means;
Interface means for sending the input transport stream as an isochronous stream on the network;
Switching means for switching the transport stream input to the interface means to either the transport stream output from the time information update means or another transport stream;
Based on a control command received via the network, the I frame slice reading means, the P frame reading control means, the I frame inserting means, the I frame slice updating means, the transport stream connecting means, the time information updating Network-compatible video equipment, characterized by comprising: means, interface means, and system control means for controlling the operation of the switching means. Stream storage means for storing a transport stream;
Stream read control means for reading a transport stream from the stream storage means,
The network-compatible video according to any one of claims 1 to 6, wherein the other transport stream input to the switching unit includes a transport stream read by the stream read control unit. machine.   8. The network-compatible video device according to claim 7, wherein the screen data storage unit and the stream storage unit comprise a single hard disk drive.   9. The network compatible video device according to claim 7, wherein the network compatible video device is an image recording / reproducing apparatus.   The network-compatible video device according to claim 1, wherein the transport stream is an MPEG-2 transport stream. A network-compatible video device according to any one of claims 1 to 10,
An operation-side device that displays an image based on a transport stream transmitted from the network-compatible video device via a network and transmits a control command for the network-compatible video device via the network. Network compatible video system. A network-compatible video device according to any one of claims 1 to 10,
An operation side device for displaying an image based on a transport stream transmitted from the network compatible video device via the network;
A network compatible video system, comprising: a control unit that transmits a control command for the network compatible video equipment via the network.

Images