JP2007101676A - Video display device and function adding device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent blanking at the time of switching between a moving picture and a still picture, and to display a high-definition video by making the most of resolutions inherent in the moving picture and the still picture when occurrence of blanking has a bare possibility. <P>SOLUTION: A video display device comprises: a video display part 3; a data storage part (memory card (MC) 20) storing data including a video; and a resolution conversion part 26 having a high-definition mode for maintaining the inherent resolutions of the moving picture and the still picture when the moving picture and the still picture are intermingled in the video and a low-definition mode, for converting the resolution of the still picture to that of the moving picture in the low-definition mode. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a video display device including a video display unit, and a function addition device that is detachably attached to the video display device and adds a data reproduction function to the video display device.

Some video contents are a mixture of moving images and still images.
The moving image has an image size (horizontal and vertical resolution) conforming to a video standard such as “420p” or “576p”. On the other hand, the resolution of a still image is various, and generally there are many having a higher resolution than a moving image.

Thus, when reproducing video data in which a moving image and a still image are mixed, it is necessary to switch between a resolution suitable for the moving image and a resolution suitable for the still image.
The switching is performed in a vertical blanking period between fields or frames. However, if time is required for resolution conversion, blanking occurs in which the screen is momentarily interrupted.
In a video in which moving images and still images frequently appear alternately, the blanking is a video in which the eyes are not settled.

By the way, video display devices are becoming thinner and lighter, and in recent years, the use of public displays that use a large number of display devices in department stores, exhibition halls, and the like is expanding.
For public display applications, for example, there is video content in which a scene where you want to display a high-quality still image that fills the screen for product explanation appears in the video, while there are video content centered on video such as advertisements. .
In the case of a public display, the quality of video is particularly important, and there is a high demand that video with frequent blanking cannot be used as described above.

  The problem to be solved by the present invention is to prevent the occurrence of blanking when reproducing video data in which moving images and still images are mixed, and when the possibility of blanking is low, moving images and still images are originally It is to provide a video display device that can display high-quality video by making full use of the resolution that it has, and a function addition device that adds a data playback function to the video display body.

  The video display device according to the present invention includes a video display unit, a data storage unit that stores data including video, and a moving image and a still image in a case where the video and the still image are mixed. It has a high-definition mode for maintaining resolution and a low-definition mode. In the low-definition mode, it has a resolution conversion unit that converts the resolution of a still image to the resolution of a moving image.

Preferably, the present invention further includes a data reproduction management unit that sets and switches either the high-definition mode or the low-definition mode in the resolution conversion unit.
More preferably, a network connection terminal is connected to the data reproduction management unit, and access to the data reproduction management unit based on an operation through a network is possible, and the access includes the high definition mode and the low definition mode. When the switching request is included, the data reproduction management unit switches the mode setting of the resolution conversion unit in response to the switching request.
More preferably, the management screen further includes a management screen storing an item capable of selecting either the high-definition mode or the low-definition mode, and the management screen stored in the management storage The mode setting items that can be switched by an operation via the network are included.
More preferably, the management screen is hierarchized and has a screen format adapted to the network.

  A function addition device according to the present invention is a function addition device that is detachably provided in a video display device including a video display unit, and includes a data storage unit that stores data including video, and a moving image and a still image in the video. When there is a mixture of images, it has a high-definition mode that maintains the original resolution of the video and still images, and a low-definition mode, and in the low-definition mode, the resolution of the still image is converted to the resolution of the video A resolution conversion unit; and a data reproduction management unit that sets and switches either the high-definition mode or the low-definition mode to the resolution conversion unit.

  According to the present invention, it is possible to prevent the occurrence of blanking at the time of reproduction of video data in which a moving image and a still image are mixed, and when the possibility of occurrence of blanking is low, the resolution inherent to the moving image or the still image It is possible to provide a video display device that can display high-quality video by making the best use of the above and a function addition device that adds a data reproduction function to the video display main body.

  Hereinafter, embodiments of the present invention will be described by taking as an example a case where a function addition device (hereinafter referred to as an option board) detachably provided as a storage medium as a storage medium and the option board mounted on a video display device (display device) This will be described with reference to the drawings.

<Configuration>
FIG. 1 is a block diagram showing the main configuration of a display device with an option board mounted.
The main body (device main body) 1A of the display device 1 has an option slot (not shown) in which the option board 2 is mounted, and the option board 2 is mounted in the option slot. The display device 1 includes a video display unit 3, a display control first control unit (D-CPU) 4, a light receiving unit 5, a remote controller (hereinafter abbreviated as "remote control") 6 as an operation unit, and a power source. The unit 7 is provided.

  The video display unit 3 includes, for example, a liquid crystal display panel and a drive circuit, and inputs a video signal from the option board 2 through necessary processing (a processing unit is not shown), and a video (video or video) based on the video signal. (Still image) is displayed.

  The power supply unit 7 supplies main power to the video display unit 3 and other components (not shown) according to the operation of the main power switch of the apparatus main body 1A. When it is detected that the option board 2 is connected, option power is supplied to the option slot. As long as the option board 2 is not extracted, the option power supply is controlled by the main power switch in the same manner as the main power supply. Further, standby power is supplied to the D-CPU 4 and a part of the option board 2 even when the main power switch is turned off.

  The light receiving unit 5 includes, for example, an infrared light receiving device, and its output is connected to the D-CPU 4. The remote controller 6 is an accessory for remote control that communicates with the D-CPU 4 through the light receiving unit 5 using, for example, infrared light.

  The D-CPU 4 controls the video display unit 3, the power supply unit 7, and other components in the apparatus main body 1 </ b> A related to image display.

On the other hand, the option board 2 of the present embodiment is selected according to the user's request in order to add a network communication function and a storage medium such as a memory card (MC) as a data storage unit to the display device 1 It is a part that is stored in a case and mounted in an option slot. Note that the option board 2 may be inserted into the printed circuit board in the device main body 1A without the option slot.
In this example, the option board 2 for adding the above two functions is shown. However, for the purpose of increasing the number of video input connectors (not shown) provided in the device main body 1A according to the video standard, the user can It can be changed to an option board having an arbitrary function.

With the addition of the network communication function, the option board 2 includes a network connection terminal 2A to which a wide area network such as the Internet or a local area network (LAN) is connected.
Further, although it is unnecessary when the storage medium is not removable, the removable memory card (MC) 20 has a slot (not shown).
The network may be configured to be established by wireless communication.

In the option board 2, a second control unit (C-CPU) 21 as a network operation management unit, a recording / reproducing unit 20A of a memory card (MC) 20 as a data supply unit, and data reproduction for controlling the recording / reproducing unit 20A An M-CPU 22 as a management unit and a hub IC 23 for branching a signal from the network connection terminal 2A to the C-CPU 21 and the M-CPU 22 are provided.
The memory card (MC) 20 and the M-CPU 22 are connected by, for example, a USB (Universal Serial Bus). The C-CPU 21 and the M-CPU 22 are connected to a serial communication line, for example, a UART (Universal Asynchronous Receiver-Transmitter) specification line (UART). Line).
The C-CPU 21 and the D-CPU 4 are connected by one alarm line 4A and a set of serial communication lines 4B composed of, for example, a UART line.

Further, for example, a non-volatile memory (NVRAM) 24 is connected to the C-CPU 21 as a management storage unit that holds a management screen having a screen adapted to network access software (browser).
Further, a RAM 25 is connected to the M-CPU 22. In the RAM 25, a list indicating resolution information of the video display unit 3, a playback procedure of content in the memory card (MC) 20, and the like are stored in advance.

A processing device such as a personal computer (PC) 200 is connected to the network connection terminal 2A via the hub device 100.
The display device 1 is preferably used for, for example, a public display. In this case, a plurality of display devices are connected to the PC 200 via the hub device 100, and the plurality of display devices are remotely operated by the PC 200.
The PC 200 and the plurality of display devices 1 constitute a “video display system” to which the present invention is applied.

The C-CPU 21 performs setting and operation management by operations via the network. Here, the setting includes the setting of the C-CPU 21 itself and the setting of the M-CPU 22, and the operation mainly refers to the operation of the M-CPU 22.
The M-CPU 22 manages settings and operations related to data reproduction performed by outputting data from the data supply unit (recording / reproducing unit 20A).

Next, the detailed hardware, software, and data structure of the option board 2 will be described.
FIG. 2 is an explanatory diagram illustrating this configuration together with the flow of signals and content data.

In the example illustrated in FIG. 2, a resolution conversion unit 26 and a display processing unit 27 are provided as a configuration that is not illustrated in FIG. 1. These are preferably realized by hardware because high processing speed is required.
The resolution conversion unit 26 may be referred to as a video filter (abbreviation: VF) or a scaler. The resolution conversion unit 26 converts the decoded moving image data to a resolution suitable for the original resolution, or converts the moving image or still image data to a resolution suitable for the video display unit 3.
The display processing unit 27 performs processing for display display. This processing includes processing for changing the input video data to a color space suitable for a moving image or a still image, and video data synchronization (Sync.) Processing suitable for the resolution of the video display unit 3.

In the M-CPU 22, a so-called demuxer is called a demuxer, for example, a VA separation means 28 for separating video (V) and audio (A) data from a reproduction file of MPEG (Motion Picture Experts Group) 2 specification, for example, MPEG. A moving picture decoding means 29 for decoding moving picture data such as a video file, a still picture decoding means 30 for decoding still picture data such as a JPEG file, and a reproduction control means 31 are incorporated.
It is desirable to provide these means 28 to 31 as tasks (part of software) of a reproduction program installed in the M-CPU 22 as in the illustrated example. The M-CPU 22 is preferably composed of a DSP (Digital Signal Processor) in order to process these tasks at high speed. Even in this case, in the DSP, a CPU function for decoding, transmitting, calculating, and the like is preinstalled in the DSP as in a normal CPU. The M-CPU 22 in FIG. 1 shows only the function of the CPU.

A RAM 25 is connected to the M-CPU 22, and a display list 25A and a reproduction list 25B are stored therein.
The display list 25A describes the resolution information of the video display unit 3, and the reproduction list 25B holds list data of contents that need to be reproduced, the reproduction procedure thereof, and the like. This list data has a tree-type data structure in which a folder is a higher level and a file is a lower level. When a file is specified, only one or a plurality of files are specified. When a folder is specified, a content list ( File list) is specified.
Note that the resolution information of the display list 25A is checked, for example, every time the main power switch is turned on and the display device 1 is activated, and is always changed to the contents corresponding to the currently connected video display unit 3.
Further, the playlist 25B can be changed by manual setting from the device main body 1A side, but is saved in the memory card (MC) 20 and automatically read into the NVRAM 24 when it is inserted. It may be. The same applies to the download described later.

<Features>
Next, features of the display device 1 shown in FIG.
First, in the option board 2, two C-CPUs 21 and an M-CPU 22 are provided as control units (management units) having a so-called server function.
Here, the “server function” is recognized as computer-based hardware connected to the network by having an address recognized on the network, for example, an IP (Internet Protocol) address, and via the network. A function that allows a user or a subordinate (managed object) component to transmit and execute a process or instruction intended by the operation by remote operation. In addition, when the server function is provided, it is possible to access other servers on the network, control the server, or obtain information and the like.

Second, the C-CPU 21 can be accessed based on, for example, an operation through the network by the PC 200. When the data reproduction instruction is included in the access, the C-CPU 21 manages the data reproduction to the M-CPU 22. Instruct.
That is, at the beginning of access, the C-CPU 21 accepts this, and if necessary, gives an operation opportunity to the management of the M-CPU 22, for example.
The advantages of such a so-called dual CPU will be described later.

  Third, the management screen stored in the NVRAM 24 has a hierarchical structure, and at least the management screen related to display control of the video display unit 3 and the management screen related to data reproduction are integrated by hierarchization. When the IP address of the C-CPU 21 is designated from the browser screen of the PC 200 via the network, the C-CPU 21 reads and transmits the management screen from the NVRAM 24 and is displayed on the PC 200 screen.

FIG. 3 shows an example of the management screen. This example is a local save screen for saving content data downloaded to a storage medium such as a memory card (MC) 20.
In the browser used by the PC 200, the management screen is displayed in a window between display spaces such as icons, and “Notification”, “Configuration”, “Control”, “Player”, “Setup”, “Update”, “Replay” “Activation” is a main item in the first hierarchy, and a hierarchical structure having a plurality of sub-items in the second hierarchy under each main item. In the example of FIG. 3, “streaming playback”, “local storage”, “local playback”, “PC demonstration”, and “playback setting” are sub-items.
In the column 201 in FIG. 3, the IP address under the control of the C-CPU 21, in this example, the IP address of the M-CPU 22 is displayed. In the column 203, the identification name of the local storage, in this example the memory card (MC) 20, is displayed. When there are a plurality of local storages, a browse 205 can be selected to display a list. In the column 202, the reproduction file name or reproduction folder name in the selected local storage is displayed. When there are a plurality of playback files or playback folders, the browse 204 can be selected to display a list.
Thereafter, the set information is saved by selecting the save key 206, and when the local reproduction screen is opened thereafter, the saved setting information is displayed.

  Note that such a management screen can be displayed on the video display unit 3 via the D-CPU 4 and the C-CPU 21 by access based on the operation of the operation unit such as the remote controller 6.

Fourth, the C-CPU 21 and the D-CPU 4 in the device main body 1A have one signal line 4A, for example, an alarm line for notifying the occurrence of a malfunction of the apparatus, and a set of communication lines, for example, a UART line 4B. Connected by.
The operation and advantage of this CPU communication will be described later.

Fifth, among the configurations in the option board 2, standby power can be supplied to the C-CPU 21 and the hub IC 23. Even when the optional power is supplied to the option board 2, the C-CPU 21 and the hub IC 23 receive standby power supply, and when the main power switch is turned on, the optional power is supplied from the power supply unit 7 to the M-CPU 22 and recording / reproducing. Supplied to the unit 20A and the like.
By doing so, access to the C-CPU 21 as the second feature can be performed even when the power of the display device 1 is turned off.

  Sixth, a storage medium such as a memory card (MC) 20 is built in or attachable. Then, it is possible to perform streaming reproduction of video (and audio) content data in the storage medium, or data reproduction (local reproduction) which is recorded on the medium and repeatedly output an arbitrary number of times at an arbitrary time. Here, “streaming playback” means that content data downloaded via a network is not stored in a storage medium (to temporarily store it in a buffer (not shown) in order to match the download speed and playback speed) And display on the video display unit 3 or the like.

Seventh, it has a function of automatically downloading data to the storage medium (in this example, the memory card (MC) 20) for data reproduction. This operation may be performed during a period when data reproduction is not performed, for example, when the power is turned off. Therefore, it is necessary to supply the standby power to the third feature, that is, the C-CPU 21 described above. The download target and time information are stored in the NVRAM 24, and the C-CPU 21 manages and executes based on the information.
Also, download playback that performs playback (local playback) following download is possible.

  Eighth, at the time of streaming playback, local playback or download playback, there are two playback modes, a high-definition (playback) mode and a low-definition (playback) mode, which can be selected and set. Here, the “high-definition mode” is set so that the resolution of the still image output from the recording / playback unit 20A and the resolution of the moving image are maintained at the time of display. This is a playback mode in which resolution conversion is frequently performed when the moving images are mixed. On the other hand, the “low-definition mode” is a mode in which the resolution of a still image is set to be reproduced at a moving image level, and is reproduced consistently at the resolution of the moving image when a still image and a moving image are mixed. In the high-definition mode, display can be performed at the original resolution of the content, but blanking frequently occurs where the screen is momentarily interrupted when the resolution is converted. On the other hand, in the low-definition mode, the frequency of blanking is low, but the still image becomes a rough screen lower than the original resolution. Which one to select can be set from the management screen described above depending on the user's preference.

  Hereinafter, the operation of the display device will be described by dividing it into items related to the first to eighth features. Since the first, second, and third features are basic features, they will be appropriately described in items related to other features.

<IP address setting>
First, an IP address setting method using the fourth feature will be described. This setting method can be applied to other than IP address setting.
4 to 8 are explanatory diagrams showing active areas at the time of IP address setting. In these drawings, the active configuration related to the operation is indicated by diagonal lines, and the active wiring is indicated by bold lines. The same applies to other explanatory diagrams described later.

Here, the setting of the IP address is started based on a user operation on the OSD (menu screen) of the apparatus main body 1A (FIG. 4), and is notified to the C-CPU 21 via the D-CPU 4 (FIG. 5). The set IP address is stored in association with the management screen stored in the NVRAM 24 (see FIG. 1) of the C-CPU 21. As a specific setting method, there are a case where the user manually sets within a predetermined range on the menu screen and a case where automatic acquisition is performed from a DHCP (Dynamic Host Configuration Protocol) server or the like on the network.
With either of these methods, the IP address of the C-CPU 21 and the IP address of the M-CPU 22 are set.
Hereinafter, the operation will be described taking the IP address setting of the C-CPU 21 as an example.

  In the case of manual setting, the user opens the menu screen and selects “Manual” in the IP address setting item. On the screen opened by selection, an unused combination of numerical values is input to the IP address for the C-CPU 21 and the execution key is pressed. Thereby, it preserve | saves in RAM (not shown) connected to D-CPU4.

The D-CPU 4 starts notification for transferring the IP address set when the processing load is relatively small to the C-CPU 21 because the processing load is large. As shown in FIG. 5, the notification is started by the D-CPU 4 sending a communication trigger signal S4 to the C-CPU 21 via the alarm line 4A.
The C-CPU 21 having received the communication trigger signal S4 inquires of the D-CPU 4 about the communication contents and notifies the C-CPU 21 of the IP address set by the D-CPU 4 accordingly. The C-CPU 21 stores the notified IP address in the NVRAM 24 in association with the management screen.

In the case of automatic acquisition, when the user selects automatic acquisition on the menu screen instead of the IP address setting of FIG. 4, in response to the inquiry of FIG. 6, the D-CPU 4 informs the C-CPU 21 that automatic acquisition has been selected. Notice. Also in this case, as shown in FIG. 5, the D-CPU 4 starts the notification by transmitting the communication trigger signal S4 when the processing load is relatively small.
When the automatic acquisition is notified, the C-CPU 21 accesses the DHCP server 300 on the network and automatically acquires the IP address as shown in FIG. The acquired IP address is stored in the NVRAM 24 in association with the management screen by the C-CPU 21.
Thereafter, as shown in FIG. 8, the C-CPU 21 notifies the D-CPU 4 via the serial communication line 4B that the automatic acquisition of the IP address has been completed. If the D-CPU 4 does not respond at this time, the notification is made after waiting for reception of the communication trigger signal S4 from the D-CPU 4.

<Streaming playback>
FIG. 9 is an explanatory diagram of streaming reproduction regarding the sixth feature.
At the start of streaming playback, although not particularly shown, the PC 200 accesses the C-CPU 21 and acquires a management screen. Then, the main item of the player on the management screen shown in FIG. 3 is selected, and the sub-item “streaming playback” is selected. Although not specifically shown, the IP address of the M-CPU 22 is displayed on the streaming screen, and the file name or folder name in the storage medium under the control of the M-CPU 22, its search key (browse), repeat check box, play Keys, stop keys, save keys for setting information, and the like are arranged.
When streaming playback is selected, the C-CPU 21 instructs the M-CPU 22 to perform management.
Thereafter, when the play key is selected, as shown in FIG. 9, data of the playback content is output from the M-CPU 22 to the device main body 1A as it is via the network and the hub IC 23, and the video is processed through a predetermined process. Display and audio output are performed.

<Local playback>
FIG. 10 is an explanatory diagram of local reproduction regarding the sixth feature.
The local reproduction can be started on the management screen in addition to the operation by the remote controller 6 in FIG. The main item of the player on the management screen shown in FIG. 3 is selected, and the sub-item “local playback” is selected. Although not shown in particular, the local playback screen includes a display column for a file name and a folder name to be played, a browse key thereof, a repeat check column similar to the streaming playback screen, a play key, a stop key, and setting information. A save key and the like are arranged.
When local reproduction is selected, the C-CPU 21 instructs the M-CPU 22 to perform management.
Thereafter, when the play key is selected, as shown in FIG. 10, the recording / reproducing unit 20A starts reproducing the memory card (MC) 20, and the reproduction data is output from the M-CPU 22 to the device main body 1A, and a predetermined value is obtained. Through the process, video display and audio output are performed.

<Download playback>
FIG. 11 is an explanatory diagram of download and download reproduction regarding the seventh feature. FIG. 12A to FIG. 12D are diagrams showing download schedule setting items.
The download schedule is set using the screen in the sub-item “Playback Settings” in FIG. At the start of the schedule setting, although not particularly shown, the PC 200 accesses the C-CPU 21 and acquires a management screen. Then, when the “player” main screen and the “playback setting” screen therein are sequentially opened, items shown in FIG. 12A are displayed. If “scheduled download” is to be performed, “On” is selected. Otherwise, “Off” is selected. When “On” is selected, “Day of the week” selection (FIG. 12B), “Time” selection (FIG. 12C), and “Interval” selection (FIG. 12D) are continued. Do. When automatic reproduction (download reproduction) is performed, the selection is set to “On”. When all selections are completed, the “apply” key is operated.
In the case of reproduction of a still image, items such as a slide show, background music, and resolution setting can be set on the reproduction setting screen.

When the “apply” key is operated, the setting information of the download schedule is sent from the PC 200 to the C-CPU 21 via the network and the hub IC 23. The C-CPU 21 stores the download schedule information, for example, in the NVRAM 24 shown in FIG.
The C-CPU 21 periodically inquires the D-CPU 4 having a timer about the current date, day of the week, and time. As a result, when the scheduled time comes, the C-CPU 21 instructs the M-CPU 22 to control the download. Under the control of the M-CPU 22, the download is started as shown in FIG. The data is sent to the recording / reproducing unit 20A via the hub IC 23 and the M-CPU 22 and written to the memory card (MC) 20 (local storage).

  When “automatic reproduction” is on, after the writing is completed, as shown in FIG. 11, the recording / reproducing unit 20A reads the content data in the memory card (MC) 20, and the reproduced data is transferred from the M-CPU 22 to the device. The video is output to the main body 1A, and video display and audio output are performed through predetermined processing. This automatic reproduction is convenient when the content data to be reproduced on that day is downloaded immediately before the start of the morning, for example, and repeatedly reproduced after activation.

  Next, power switching as the fifth feature will be described by taking local reproduction and download based on network operation as an example. This download is automatically started at a preset date and time, day of the week, and time.

<Power switching during local playback>
FIG. 13 is an explanatory diagram during standby.
When the main power switch is turned off to shift to the standby state, as shown in FIG. 13, the power supply unit 7 (see FIG. 1) under the control of the D-CPU 4 turns off the optional power supply and maintains the standby power supply. . Thereafter, the power supply unit 7 also turns off the main power supply. However, standby power is also supplied to the D-CPU 4.
In this state, as shown in FIG. 13, when there is an access from the PC 200, the standby C-CPU 21 is activated via the hub IC 23 and performs control according to the access contents. Thereby, even when the main power supply of the apparatus main body 1A is not turned on, the PC 200 can call the management screen and change a predetermined setting.

FIG. 14 is an explanatory diagram for instructing the start of local playback after the main power is turned on.
The C-CPU 21 notifies the D-CPU 4 that there has been an instruction for local reproduction. At this time, since the D-CPU 4 is in a standby state, there is almost no processing load, and a response immediately returns. In response to this notification, the D-CPU 4 activates the device main body 1 </ b> A including the power supply unit 7 and the video display unit 3. Also, option power is supplied to the option board 2, and all the components in the option board 2 are ready to be activated.
In the meantime, the C-CPU 21 instructs the M-CPU 22 to control local reproduction. Thereafter, control of local reproduction is performed by the M-CPU 22.

FIG. 15 is an explanatory diagram for local reproduction.
As described above, when a file or folder to be played is selected on the PC 200 on the local playback sub-item screen of the management screen, the information (including the playback procedure) is stored in the network and hub as shown in FIG. It is sent to the M-CPU 22 via the IC 23. This information is also sent to the C-CPU 21, but since the local reproduction control has already been instructed to the M-CPU 22, the control is left to the M-CPU 22.
The M-CPU 22 stores the information in the RAM 25 and controls local reproduction accordingly.
Thereafter, when a play key is selected on the local playback screen of the PC 200, the information is similarly transmitted to the M-CPU 22, and the recording / playback unit 20A plays back the memory card (MC) 20 as shown in FIG. The reproduction data is output from the M-CPU 22 to the apparatus main body 1A, and video display and audio output are performed through predetermined processing.

<Switching power when downloading>
FIG. 16 is an explanatory diagram during standby. The power supply during standby is the same as that in FIG. 13, but access from the PC 200 is not performed because the download is based on the schedule.
Since the D-CPU 4 has a timer, it is supplied with standby power similarly to the C-CPU 21. During this standby, the C-CPU 21 periodically inquires the D-CPU 4 about the current date and time, and monitors whether the download date and time determined by the schedule has been reached.

FIG. 17 is an explanatory view when the download date and time is adapted.
When it is detected by the C-CPU 21 that the download date / time has come, the C-CPU 21 issues a power-on command to the D-CPU 4.
The D-CPU 4 activates the device main body 1A including the power supply unit 7 and the video display unit 3 in response to the power-on command. Also, option power is supplied to the option board 2, and all the components in the option board 2 are ready to be activated.
Meanwhile, the C-CPU 21 instructs the M-CPU 22 to control download. Thereafter, the download control is performed by the M-CPU 22.

FIG. 18 is an explanatory diagram of download.
The M-CPU 22 refers to the download target file or folder name stored in the RAM 25, accesses the PC 200 via the network, and downloads desired content data from the PC 200. The M-CPU 22 sends the content data to the activated recording / reproducing unit 20A, which is written to the memory card (MC) 20 by the recording / reproducing unit 20A.
If automatic playback is set, the content data is read from the memory card (MC) 20 and output from the M-CPU 22 after the writing is completed. The content data is provided for video display and audio output through a predetermined process.

FIG. 19 is an explanatory diagram at the end of download or downloader playback, and FIG. 20 is an explanatory diagram at the time of power-off.
When the download (or download reproduction) is completed, the M-CPU 22 issues an end report to the C-CPU 21 as shown in FIG.
In response to this report, the C-CPU 21 issues a power-off command to the D-CPU 4 as shown in FIG.
Then, the power supply unit 7 turns off the optional power supply under the control of the D-CPU 4 and subsequently turns off the main power supply. Thereby, the power supply of the apparatus main body 1A including the video display unit 3 is stopped. However, the standby power supplied to the D-CPU 4, C-CPU 21 and hub IC 23 is maintained.

<Mode switching>
As described above, the display device 1 of this example has four types of data playback modes: local playback, streaming playback, download playback, and normal playback according to remote control operations.
In any of these playbacks, it is possible to switch between “high-definition mode” in which resolution conversion is performed appropriately for playback at the original resolution of moving images and still images and “low-definition mode” in which still images are output at the resolution of moving images. It is.
In the “high-definition mode”, since the moving image is displayed at the original low resolution and the still image is displayed at the original high resolution, resolution conversion is not performed. On the other hand, in the “low-definition mode”, a moving image has an original low resolution and a still image has an original high resolution. However, data is thinned out in units of pixels to reduce the data size and convert it to a moving image resolution. At this time, if the pixel is not a square pixel, the horizontal and vertical sizes cannot be made equal, and the magnification is converted (reduced) according to the aspect ratio of the pixel.

  This mode switching can be changed by selecting “Control” in the management drawing shown in FIG. 3 and “Picture Mode” in the displayed control screen. Note that image quality adjustment items such as contrast are also arranged on the control screen, and fine image quality adjustment can be executed by remote operation from the PC 200.

Prior to mode switching, acquisition of resolution information of the video display unit 3 necessary for the processing will be described.
FIG. 21 is an explanatory diagram of acquisition of resolution information.
This acquisition of resolution information is performed when the main power supply is turned on. The main power supply may be activated based on access via a network during standby, or may be performed based on power key operation of the device main body 1A or the remote controller 6. In the former case, the activation trigger is given by the C-CPU 21, and in the latter case, the activation is controlled by the D-CPU 4.
In the case of activation via the network, a resolution information notification request is issued from the C-CPU 21 to the D-CPU 4, and in response thereto, the D-CPU 4 notifies the C-CPU 21 of the resolution information of the video display unit 3. The C-CPU 21 gives the notified resolution information to the M-CPU 22, and the M-CPU 22 stores it in the display list 25 </ b> A in the RAM 25.
In the case of activation based on the power key operation, the C-CPU 21 that has detected the supply of optional power issues the above notification request, acquires resolution information from the D-CPU 4, and similarly stores it in the display list 25A. When the power key operation is used, the resolution information may be unilaterally notified from the D-CPU 4 to the C-CPU 21 after the power is turned on.
Since the resolution information varies depending on the type of the apparatus main body 1A, it is desirable to check each time the power is turned on in any of the above cases, and rewrite the display list 25A if there is a change.

FIG. 22 is a processing flow diagram when a moving image and a still image are reproduced in the low-definition mode. Each part or means shown in FIG. 2 is indicated by reference numerals at the top of FIG.
The process of FIG. 22 will be described below with reference to FIG. 2 as appropriate. Note that control command output and timing control are performed by a CPU function unit (or reproduction control means 31) not shown in FIG. In the following description, a case where moving image compression is performed by MPEG2 is exemplified, but moving image compression is not limited to this.

First, moving image reproduction in the low-definition mode will be described along the flow shown in the upper part of FIG.
When an MPEG2 playback request is issued (step ST1), a playback list (Play list) 25B in the RAM 25 is read by the playback control means (Play Ctrl) 31.
The video display unit 3 determines the current mode (step ST2). The current mode is set, for example, as a flag in a display list (hereinafter abbreviated as DL) 25A. The initial setting is “low-definition mode (hereinafter abbreviated as LM)”, but during playback, the flag is inverted as “high-definition mode (hereinafter abbreviated as HM)” in the previous processing. In some cases, mode determination is required here.

When the high definition mode (HM) is set before the moving image reproduction, the reproduction control means 31 sets the resolution to be converted by the resolution conversion unit (Video Filter, hereinafter abbreviated as VF) 26 to “480p”. Alternatively, “576p” low-definition mode (LM) is set (step ST3). Which of these is set is determined according to the video signal standard. Further, the reproduction control unit 31 sets the setting in the display processing unit 27 to the MPEG2 color space, and sets the DL setting of the display list 25A to correspond to the low definition mode (LM) (step ST4). Thereby, setting corresponding to mode switching is performed.
Note that steps ST3 and ST4 are skipped if the setting corresponds to the low-definition mode (LM) before the moving image reproduction.

In step ST5, file data is read by the recording / reproducing unit 20A of FIG. 2 (File Read).
The read foil data is transmitted in packet units to VA separating means (hereinafter referred to as “Demuxer”) 28 (step ST6), where the audio data and video data are separated in packet units (step ST7). Among these, the audio data packet is sent to an audio decoder (not shown), and is output to a speaker (not shown) after processing.

  On the other hand, the video data packet is sent to the moving picture decoding means (Video Dec) 29, decoded there (step ST8), and further sent to the resolution converter (Video Filter) 26 (step ST9). At this time, the video decoding means 29 registers in the packet queue, waits for an interrupt, and transmits the data from the registered one by prefetching first out (FIFO).

The resolution conversion unit 26 resizes the transmitted moving image data packet to a size corresponding to the horizontal and vertical resolutions indicated by the display list (DL) setting performed by the reproduction control unit 31, and then the display processing unit 27. (Step ST10).
After that, the moving image data packets are rearranged based on the packet queue after display processing such as MPEG2 color space setting, and are output to the video display unit 3.
The processing from step ST5 onward is repeated until the end of the MPEG2 reproduction, whereby a moving image is displayed on the video display unit 3.

In the low-definition mode playback of the still image shown in the lower part of FIG. 22, steps ST1 and ST2 are the same as those for the moving image.
Next, step ST11 (corresponding to step ST3 in the case of a moving image) is executed, but here, contrary to the case of a moving image, the resolution conversion unit (VF) 26 converts it before the still image reproduction. Only when the power resolution (VF setting) is “480p” or “576p” compatible with the low definition mode (LM), this VF setting is changed to the high definition mode (HM).
In the next step ST12, the playback control means 31 sets the setting in the display processing unit 27 to the color space for JPEG, and sets the DL setting of the display list 25A to be compatible with the low definition mode (LM). Thereby, setting corresponding to mode switching is performed.
Note that steps ST11 and ST12 are skipped if the setting corresponds to the low-definition mode (LM) before the still image reproduction.

After reading the file as in the case of the moving image (step ST5), the read still image data is sent to the still image decoding means (JPEG Dec) 30. At this time, in the case of a still image, since there is no normal audio data, the processing by the demultiplexer is skipped.
Usually, since the decoding image size is fixed in the decoder, if the read image size does not match the decoding image size, the image size of the read data is reduced so as to be applicable (step ST13). For example, when the decoding image size is fixed to WXGA, three types of reduction magnifications of 1/2, 1/4, and 1/8 are prepared corresponding to the original image size.
After decoding by the still image decoding means 30 (step ST14), the decoded still image data packet is transmitted to the resolution conversion unit (Video Filter) 26 after completing packet queue registration as in the case of a moving image ( Step ST9).
The processes in steps ST5, ST13 and ST14 are repeated until the decoding is completed.

In the resolution conversion unit 26, the image size is reduced so that the still image matches the size of the moving image, and the processed still image data packet is sent to the display processing unit 27 (step ST15). In this pixel number conversion process, when the pixels of the video display unit 3 are not square, it is necessary to change the reduction magnification in the vertical and horizontal directions. In addition, “480p” and “576p” need to be aligned to the same size. For example, when the ratio of the vertical and horizontal pixel sizes is 27:32, the width is (27/32) times if “480p”, and the width is (27/32 × 5/6) times if “576p”. To convert the resolution.
Thereafter, the data packets of the still image are rearranged based on the packet queue after display processing such as JPEG color space setting, and are output to the video display unit 3.

FIG. 23 shows a processing flow diagram in the case of reproducing a moving image and a still image in high definition mode.
The high-definition mode playback in FIG. 23 differs from the low-definition mode playback in FIG. 22 in that, in the case of still image playback, the display list (DL) is set not in the low-definition mode (LM) but in the high-definition mode (HM). ) Set to be compatible (step ST20) and, at the time of resolution conversion, do not perform size reduction to match the still image size to “480p” or “576p” of the moving image specification, but simply adapt to the resolution of the video display unit 3 In order to make this happen, conversion to a size corresponding to the high definition mode (HM) set in the display list (DL) is performed (step ST21). In step ST21, DL-compatible image size conversion is performed only when necessary.

  Since the other steps are the same as in the low-definition mode reproduction, the explanation here is omitted.

According to this embodiment, the following benefits can be obtained.
As shown in FIG. 1, a C-CPU 21 as a network operation management unit and an M-CPU 22 as a data reproduction management unit each have a server function, and IP addresses are assigned separately. Further, the C-CPU 21 accepts access via the network. For this reason, the M-CPU 22 can concentrate on management and control related to data reproduction, and can set the C-CPU 21 based on operations via the network at any time without causing any trouble in data reproduction.

In addition, a management screen having a hierarchical structure is stored in the NVRAM 24 as a management storage unit connected to the C-CPU 21. This management screen has a display screen format similar to that of a normal browser.
Therefore, if it is permitted, the management screen can be accessed via the network. That is, the management screen is opened to the network for the PC 200 as a processing apparatus to which access is permitted, and the PC 200 can display the management screen on its own display screen. At that time, since the management screen adopts the same display screen format as that of the browser, it is possible to change the setting of the management screen comfortably without taking time and trouble.

In particular, when the network is a local area network (LAN) different from the Internet, the download setting can be performed on the LAN without requiring access to the Internet (web access) at the time of downloading.
At this time, as described above, if the PC 200 holding the download content is connected to the LAN, the C-CPU 21 is connected to the LAN in response to an access from the PC 200 or an access from the OSD (menu screen). For example, a management screen corresponding to HTML (Hyper Text Markup Language) is opened. Therefore, regardless of whether the Internet is connected to the LAN and without requiring a download web server on the Internet, downloading with the same operability as the downloading from the Internet is possible. At this time, dedicated software for web display is not required.

The management screen is accessed by the IP address of the network operation management unit (C-CPU 21). However, the IP address of the data reproduction management unit (M-CPU 22) is embedded in the management screen and is saved by an arbitrary operation. ing. For this reason, even when the PC 200 accesses the M-CPU 22 during data reproduction, there is no need to input the IP address.
On the management screen, other necessary management items related to download schedule, playback schedule, playback of storage media such as memory card (MC) 20, identification of playback target, selection of automatic playback, etc. are unified, and setting changes thereof can be made. Easy.
The management screen can also be displayed on the video display unit 3 via a display CPU (D-CPU 4) as the first control unit.

  Communication between the D-CPU 4 and the C-CPU 21 is possible with one signal line (alarm line 4A) and one serial communication line 4B, and the connection is simple. Further, by giving a communication opportunity to the C-CPU 21 only when the processing load of the D-CPU 4 is relatively small, communication that does not hinder the processing of the D-CPU 4 is possible. Such a method is sufficient because the C-CPU 21 communicates with the D-CPU 4 because the content is related to the setting and thus does not require urgency.

  The C-CPU 21 is always supplied with standby power that can be activated even when the main power is turned off, and can always be accessed based on operations via the network. This is important in that various settings and downloads can be made for the next playback even at night when data playback is not performed or when the display is not used.

  There are various playback modes for data playback, such as streaming playback that plays back data downloaded from the network in near real time, download playback that saves and plays back downloaded data, and normal playback (local playback). It is possible to reproduce data according to

At the time of playback, it has a high-definition (playback) mode that plays back moving images and still images at their original resolution, and a low-definition (playback) mode that converts the resolution of still images to the moving image level for playback. Selection setting is possible on the management screen. For this reason, depending on the user's preference, resolution switching cannot be processed in the blanking period, and the screen is momentarily interrupted.There is a high probability of blanking occurrence. Mode selection is possible.
In particular, in an example of a department store that performs public display, for example, you can select a high-definition mode when you want to display a still image of a product beautifully, and a low-definition mode for content that is mainly a video such as a store commercial, Optimal display according to the content is possible.

  In addition, the network connection and data playback functions described above are provided as optional parts, so the cost of the display device can be reduced, and it can be used in a wide range of applications, providing products that are versatile and useless. It is.

  In addition, since two management units (network operation management unit and data reproduction management unit) are provided in the function-added device, the development assets of the device itself and other function-added devices are newly developed. Work can be done by adding parts, and there is no work process for duplicating common hardware and software, so that the development is easy.

It is a block diagram which shows the main structures of the display apparatus of embodiment. It is a block diagram of the option board of the embodiment. It is a figure which shows the example of a management screen. It is explanatory drawing of IP address setting on OSD. It is explanatory drawing of the notification start of an IP address. It is explanatory drawing of the IP address notification according to an inquiry. It is explanatory drawing of the automatic acquisition of an IP address. It is explanatory drawing of completion of automatic acquisition. It is explanatory drawing of streaming reproduction. It is explanatory drawing of download (reproduction | regeneration). It is explanatory drawing of local reproduction | regeneration. (A)-(D) are figures which show the schedule setting item of a download. It is explanatory drawing of standby. It is explanatory drawing of the start instruction | indication of local reproduction | regeneration. It is explanatory drawing of local reproduction | regeneration. It is explanatory drawing of standby. It is explanatory drawing when it adapts to the setting date of download. It is explanatory drawing of download (reproduction | regeneration). It is explanatory drawing at the time of completion | finish of download (reproduction | regeneration). It is explanatory drawing of power-off. It is explanatory drawing of resolution information acquisition. It is a processing flow figure of low-definition mode reproduction. It is a processing flowchart of high-definition mode reproduction.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Display apparatus, 1A ... Device main body, 2 ... Option board, 2A ... Network connection terminal, 3 ... Video display part, 4 ... D-CPU, 4A ... Alarm line, 4B ... Serial communication line, 6 ... Remote control, 7 ... Power unit, 20 ... Memory card (MC), 20A ... Recording / playback unit, 21 ... C-CPU, 22 ... M-CPU, 23 ... Hub IC, 24 ... NVRAM, 25 ... RAM, 25A ... Display list, 25B ... Playback List: 26 ... Resolution conversion unit, 27 ... Display processing unit, 28 ... VA separation means, 29 ... Video decoding means, 30 ... Still picture decoding means, 31 ... Playback control means, 200 ... PC

Claims (8)

A video display unit;
A data storage unit storing data including video, and
When the video contains a mixture of video and still images, the video has a high-definition mode that maintains the original resolution of the video and still images, and a low-definition mode. A resolution converter for converting to video resolution;
A video display device. The video display apparatus according to claim 1, further comprising a data reproduction management unit that sets and switches either the high-definition mode or the low-definition mode in the resolution conversion unit. A network connection terminal is connected to the data reproduction management unit,
When the access to the data reproduction management unit based on an operation through a network is possible and the access includes a switching request between the high-definition mode and the low-definition mode, the data reproduction management unit The video display device according to claim 2, wherein the mode setting of the resolution conversion unit is switched according to. A management storage unit that stores a management screen having items capable of selecting either the high-definition mode or the low-definition mode;
The video display device according to claim 3, wherein the mode setting item that can be switched by an operation via a network is included in a management screen stored in the management storage unit. The video display device according to claim 4, wherein the management screen is hierarchized and has a screen format suitable for the network. The video display according to claim 3, wherein the data supply unit, the resolution conversion unit, the data reproduction management unit, and the network connection terminal are provided in a function addition device that can be attached to and detached from an apparatus main body including the video display unit. apparatus. The video display device according to claim 6, wherein the data storage unit is detachable from the additional function device. A function addition device detachably provided in a video display device including a video display unit,
A data storage unit storing data including video, and
When the video contains a mixture of video and still images, the video has a high-definition mode that maintains the original resolution of the video and still images, and a low-definition mode. A resolution converter for converting to video resolution;
A data reproduction management unit that sets and switches either the high-definition mode or the low-definition mode in the resolution conversion unit;
Added function device.

Images