JP2004173101A - Video information display controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable a user to perform high-speed menu display that gives little stress to the user and perform a write processing and many processing other than the write processing by the same control means. <P>SOLUTION: A DVC is provided with a video signal processing circuit 1-5 for converting a video signal outputted from a camera signal processing circuit 1-3 into an image record signal and a monitor output signal, a bitmap information generation circuit 1-6 for generating attachment image information to be attached to the video signal, a bitmap memory 1-7 for storing a bitmap pattern of the attachment image information, and a microcomputer 1-13 for sequentially performing bitmap memory write processing that writes the bitmap pattern of the attachment image information in the bitmap memory 1-7 and processing other than the bitmap memory write processing and performing the processing other than the bitmap memory write processing in a mode 2 for reducing a processing load in the case of a menu display mode. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a video information display control device suitable for application to a method for generating additional image information in a video information recording / reproducing device that records and reproduces image information and audio information on a magnetic recording medium, for example.
[0002]
[Prior art]
Display items of the additional image information in the video information recording / reproducing device include a current mode display indicating the current state of the device such as recording / reproducing of video information, and recording / reproduction information such as a time code and a chapter for distinguishing a video scene. Display of position information indicating a position in the storage medium, a remaining amount display indicating the remaining storage capacity of the storage medium, a warning display indicating the end of the magnetic tape for recording / reproducing video information, and a zoom bar indicating a zoom position. There are various display items such as display (in the case of a recording device integrated with a camera).
[0003]
In general, a recording device integrated with a camera includes a recording mode (SP (Standard Play) / LP (Long Play)), a shutter speed, an audio mode, and a program AE (automatic exposure correction processing) mode. In many cases, a user interface function called “menu setting” is provided as a means for externally changing the setting of the apparatus. The menu setting function displays each setting item, the current setting state / setting possible state, a pointer for setting, etc. on the display unit of the recording device as a menu setting screen, and the user sets the recording device while watching the display. Is a function that can be freely changed.
[0004]
One example of a basic operation method of the menu setting is a method of selecting a display item on a menu setting screen with a “pointer moving key” and selecting the item with a “selection key”. In this menu setting screen, quick responsiveness is required to switch the pointer display position using the "pointer movement key". Also, when the display item is selected using the "selection key", the screen display changes greatly, It is necessary to change many character strings at once. 2 and 3 show examples of the menu setting screen. For example, when the “selection key” is pressed from the state of FIG. 2 in which the pointer is set to the “recording mode” item by the “pointer moving key”, the menu setting screen is largely switched to the “recording mode” selection screen of FIG. . In this case, it is necessary to change a large number of character strings to be displayed as described above.
[0005]
Conventionally, the above additional image information is generated by a character generation IC (hereinafter, CGIC) having an internal memory in which font information (font pattern) of a display character is written, and is added to a recorded video and a reproduced video to record video information. It was displayed and output on a monitor or the like of the playback device.
[0006]
FIG. 8 is a block diagram showing a system configuration capable of displaying additional image information using CGIC in a digital video camera according to a conventional example. The digital video camera includes a lens 7-1, a CCD 7-2, a camera signal processing circuit 7-3, a gyro sensor 7-4, a camera microcomputer (hereinafter a microcomputer) 7-5, a video signal processing circuit 7-6, and a user interface microcomputer. 7-7, CGIC 7-8, adder (adder) 7-9, recorder microcomputer 7-10, mechanical deck 7-11, digital interface (DI) 7-12, remote controller (hereinafter, remote control) input means 7-13 and key input means 7-14.
[0007]
The lens 7-1 guides an optical signal of the subject to the CCD 7-2. The CCD 7-2 converts an optical signal input through the lens 7-1 into an electric signal. The camera signal processing circuit 7-3 processes the electric signal output from the CCD 7-2. The gyro sensor 7-4 detects the vibration of the camera body. The camera microcomputer 7-5 controls an imaging system such as the lens 7-1 and the CCD 7-2. The video signal processing circuit 7-6 processes the digital video signal output from the camera signal processing circuit 7-3. The user interface microcomputer 7-7 controls the recorder microcomputer 7-10 and the camera microcomputer 7-5 in response to an input from a user interface such as a remote controller input unit 7-13 and a key input unit 7-14. The user interface microcomputer 7-7 controls the display of the additional image information such as the above-described menu display on the monitor by controlling the CGIC 7-8 at the same time.
[0008]
The CGIC 7-8 generates additional image information. The adder 7-9 adds the additional image information signal output from the CGIC 7-8 to the monitor output signal output from the video signal processing circuit 7-6, and outputs the result to the monitor. The recorder microcomputer 7-10 controls recording of an image recording signal in the mechanical deck 7-11. The mechanical deck 7-11 records the image recording signal generated by the video signal processing circuit 7-6 on a magnetic tape. The digital interface (DI) 7-12 controls an interface for digital signal input. The remote control input means 7-13 is used when performing a remote control operation of the camera. The key input unit 7-14 controls an interface for key input operated by the user.
[0009]
As other conventional examples, various techniques for displaying a character signal using a character generation circuit have been proposed (for example, see Patent Documents 1 and 2).
[0010]
[Patent Document 1]
JP-A-5-292358
[Patent Document 2]
JP-A-9-322025
[0011]
[Problems to be solved by the invention]
However, the prior art described above has the following problems. The display of the additional image information by the CGIC of the digital video camera has a problem that the type of color is limited, so that high-quality display cannot be performed, and display other than the font pattern written in the internal memory of the CGIC cannot be performed. .
[0012]
Therefore, in recent years, a display method called bitmap display that can write a bitmap pattern of additional image information into a memory and output graphical and high-quality additional image information has been used. In this case, since it takes a long time to rewrite the bitmap pattern, there is a problem that a state in which the bitmap pattern is being rewritten is output as image information or a screen flickers. Therefore, in general, a high-performance dedicated CPU writes a bitmap pattern into a memory at a high speed, or widens the memory area of the bitmap pattern and provides a large-scale drawing circuit to provide a plurality of layers (multiple layers are stacked). By operating a drawing sheet that performs display, the above-mentioned disadvantages are improved, and the apparent display quality and the responsiveness of rewriting many characters with a quick response are ensured.
[0013]
However, the above-described conventional bitmap display method requires a configuration that is difficult to incorporate into a recording / reproducing device such as a camera-integrated video recorder, which is becoming smaller in recent years, such as requiring a large-scale circuit configuration or an expensive CPU. And had In addition, performing the control of each block in the recording / reproducing apparatus and the bitmap display control with the same microcomputer requires a lot of characters to be rewritten with a quick response, especially in the case of menu display. Is difficult to increase.
[0014]
SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and enables a high-speed menu display with less stress for a user, and enables a writing process and many other processes to be performed by the same control unit. It is another object of the present invention to provide a video information display control device.
[0015]
[Means for Solving the Problems]
In order to achieve the above object, the present invention relates to a video information display control device for performing display control of video information, an additional image information generating means for generating additional image information to be added to a video signal, and a bit map of the additional image information. An additional image information storage unit for storing a pattern, a writing process of writing the bitmap pattern of the additional image information in the additional image information storage unit, and a process other than the writing process are sequentially executed, and a specific operation state is established. In this case, there is provided control means for executing processing other than the writing processing in a mode in which the processing load is reduced.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0017]
An embodiment in which the present invention is applied to a digital video camera (hereinafter, DVC) that records a digital video signal on a magnetic tape by a helical scan method (a method of recording an image on a track formed diagonally on a magnetic tape). explain. FIG. 1 is a block diagram showing the configuration of a DVC according to the present embodiment, which best represents the present invention. DVC includes a lens 1-1, a CCD 1-2, a camera signal processing circuit 1-3, a gyro sensor 1-4, a video signal processing circuit 1-5, a bitmap information generation circuit 1-6, a bitmap memory 1-7, It has an adder (adder) 1-8, a mechanical deck 1-9, a digital interface (DI) 1-10, a remote controller input unit 1-11, a key input unit 1-12, and a microcomputer 1-13. .
[0018]
In the figure, 1-a is lens control, 1-b is camera signal processing circuit control, 1-c is gyro signal reading, 1-d is video signal processing circuit control, 1-e is mechanical mode control / mechanical servo control, f is a bitmap information generation circuit control, 1-g is a user interface input, 1-h is a bitmap memory write, 1-i is a VD / HD synchronization signal, and 1-j is a VD interrupt signal.
[0019]
The lens 1-1 guides an optical signal (optical image) of the subject to the CCD 1-2. The CCD 1-2 converts an optical signal input through the lens 1-1 into an electric signal. The camera signal processing circuit 1-3 processes the electric signal output from the CCD 1-2. The gyro sensor 1-4 is a sensor that detects vibration of the DVC main body so that the microcomputer 1-13 performs anti-vibration control. The video signal processing circuit 1-5 converts the digital video signal output from the camera signal processing circuit 1-5 into an image recording signal for recording on a magnetic tape and a video signal for outputting to a monitor (not shown). . The bitmap information generation circuit 1-6 generates an additional image information signal to be added to the video signal output to the monitor. The bitmap memory 1-7 is a memory for writing a bitmap pattern of an additional image information signal to be added to a video signal.
[0020]
The adder 1-8 mixes (MIX) the bitmap-added image information signal output from the bitmap information generation circuit 1-6 with the monitor output signal output from the video signal processing circuit 1-5. The bitmap information generating circuit 1-6 includes a vertical synchronizing signal (hereinafter referred to as VD) and a horizontal synchronizing signal indicating a horizontal video period generated by the video signal processing circuit 1-5. (Hereinafter referred to as HD) as a reference signal for operation timing (1-i), and based on these timings, a bitmap-added image information signal is output to the adder 1-8. The mechanical deck 1-9 records the image recording signal generated by the video signal processing circuit 1-5 on a track formed diagonally on a magnetic tape by a plurality of magnetic heads mounted on a drum motor rotating at high speed. . A digital interface (DI) 1-10, a remote controller input unit 1-11, and a key input unit 1-12 are user interfaces used when a user operates a DVC.
[0021]
The microcomputer 1-13 comprehensively controls each of the above blocks, and performs lens control (1-a) mainly including motor control for performing zoom / autofocus (hereinafter referred to as AF), auto white balance ( Camera signal processing circuit control (1-b) for controlling AWB) / program AE (hereinafter PAE), etc., and image stabilization (hereinafter IS) including reading (1-c) of the output signal of the gyro sensor 1-4. Video signal processing circuit control (1-d) for setting signal processing modes such as control, recording / reproduction, etc., and a capstan motor for running a magnetic tape and a video head for performing magnetic recording are mounted on the mechanical deck 1-9. Servo control and mechanical mode control (1-e) mainly including the rotation control of the drum motor, and bit map information generation circuit control (1-1- ) Is performed user reads the interface information (1-g) or DVC entire mode UI (User Interface such as determination of the) control, various controls and the like.
[0022]
The microcomputer 1-13 performs a bitmap memory write control for writing the bitmap pattern of the additional image information in the bitmap memory 1-7 in addition to the various controls described above. The microcomputer 1-13 receives the VD (1-j) as a synchronization signal from the video signal processing circuit 1-5, and uses the VD as an interrupt signal, whereby the video signal processing circuit 1-5, the bitmap information generation circuit 1 Control can be performed at a timing synchronized with the operation of peripheral circuits such as -6. Further, the microcomputer 1-13 executes the camera control process shown in the flowchart of FIG. 4 by controlling each unit shown in FIG. 1 based on a control program stored in an internal memory (not shown).
[0023]
FIG. 2 and FIG. 3 are diagrams showing display examples of a VTR setting menu screen displayed on a DVC monitor. FIG. 2 is a display example of a VTR setting menu screen. In the present embodiment, each setting of “recording mode”, “audio mode”, and “after-recording (after recording) input” can be performed from the VTR setting menu screen. The user can shift to the VTR setting menu screen by pressing a “menu key” from the normal screen in the VTR mode. 2-1 is a pointer display indicating a current selection item, and 2-2 is a display indicating a currently set state of each item. On the VTR setting menu screen, the user moves the pointer display 2-1 to a desired item by operating the key input unit 1-12 or the remote control input unit 1-11, and presses the "OK" key at the position of the desired item. By doing so, it is possible to switch to the setting screen for that item.
[0024]
FIG. 3 is a display example of the setting screen of the “recording mode”. 3-1 is a pointer display indicating a selection item, and 3-2 is a list display of a settable state. On the setting screen, the user moves the pointer display 3-1 to the item to be set by operating the key input unit 1-12 or the remote control input unit 1-11, and presses the "OK" key at the position of the item to be set. Can be changed to the setting state. After the "confirmation key" is pressed, the setting screen of FIG. 3 is switched again to the VTR setting menu screen of FIG. 2, and other settings of the VTR function can be performed. When exiting from the VTR setting menu screen, move the pointer to the “← Return” position on the display of the VTR setting menu screen of FIG. 2 and press the “Enter key” or press the “Menu key” again. do it.
[0025]
As described above, in the menu display mode, it is necessary to switch the display of many character strings with a quick response according to the operation of the user. The display of these character strings is realized by the microcomputer 1-13 writing the bit map patterns of the character strings in the bit map memory 1-7. The circuit 1-6 will be described in detail.
[0026]
FIG. 5 is a block diagram showing an outline of the bitmap information generation circuit 1-6. The bitmap information generation circuit 1-6 includes a color palette 5-2, a selection switch 5-3, and a bitmap signal generation circuit 5-4. In the figure, reference numeral 1-7 indicates the concept of a bitmap memory, and the microcomputer 1-13 writes a bitmap pattern of additional image information in the bitmap memory 1-7. In the bitmap information generation circuit 1-6, the color palette 5-2 has a plurality of colors (transparent, blue, red, green, white, etc.). The microcomputer 1-13 can freely set the color of the color palette 5-2. The selection switch 5-3 is a switch for selecting a color set in the color palette 5-2.
[0027]
The bitmap signal generation circuit 5-4 receives HD (horizontal synchronization signal) and VD (vertical synchronization signal) from the video signal processing circuit 1-5, and generates an output signal according to the timing. Further, the bitmap signal generation circuit 5-4 sequentially scans the bitmap memory 1-7 by HD / VD and reads data from the bitmap memory 1-7. Then, the bitmap signal generation circuit 5-4 sequentially switches the selection switch 5-3 according to the value of the read data, and takes in the color of the color palette 5-2 selected by the selection switch 5-3. By outputting a signal corresponding to the captured color, additional image information to be added to the monitor output signal is generated.
[0028]
The operation of the bitmap information generation circuit 1-6 will be described with reference to FIG. FIG. 6 is a timing chart showing a read operation of the bitmap information generation circuit 1-6. 6-1 is a VD signal, and 6-2 is an HD signal. 6-3 shows the color of the color read by the bitmap information generation circuit 1-6 from the color palette 5-2 set as shown in FIG. 5 according to the value read from the bitmap memory 1-7 in FIG. Information. Upon receiving the VD signal 6-1, the bitmap information generating circuit 1-6 moves the read address of the bitmap memory to the upper left corner of the bitmap memory 1-7 corresponding to the upper left corner of the monitor screen. Data is read sequentially from the corresponding address. In the case of FIG. 5, the read data values are 0, 0, 0, 3, 3,. When the data of the corresponding color is sequentially read from the position of the color pallet 5-2 corresponding to this value, the data becomes transparent, transparent, transparent, green, green, and so on.
[0029]
Next, when the bitmap information generation circuit 1-6 receives the HD signal 6-2, the bitmap memory read address is lowered by one line from the upper end of the bitmap memory 1-7, and data is sequentially read from the address corresponding to the left end. read out. In the case of FIG. 5, the read data values are 0, 0, 2, 2, 2,. When the data of the corresponding color is sequentially read from the position of the color pallet 5-2 corresponding to this value, it becomes transparent, transparent, red, red, red,. The bitmap signal generation circuit 5-4 in the bitmap information generation circuit 1-6 converts the color data read by such a procedure into a signal format that can be added to the monitor output image, thereby adding the color data. Generate image information cyclically.
[0030]
Next, control other than the display processing control in the microcomputer 1-13 that performs the display processing control as described above will be described. Each of the controls 1-a to 1-g in FIG. 1 described above is realized by the microcomputer 1-13 performing multi-processing in the form of "tasks", and these tasks are performed according to the urgency. Priorities are set in advance.
[0031]
FIG. 7 is a diagram showing a microcomputer processing task list showing types of tasks to be processed by the microcomputer 1-13, processing outlines, and task priorities. In the present embodiment, the task with the highest priority is the “mechanical servo control” task. The mechanical servo control is started by DFG and CFG pulses output in accordance with the rotation of the drum motor and the capstan motor, and generates a control voltage for rotating these motors at a constant speed. When recording and reproducing video information, it is necessary to stably control these motors. For that purpose, it is indispensable to perform processing in response to a pulse of the above DFG (Dram Frequency Generator) / CFG (Capstan Frequency Generator) instantaneously. Therefore, the priority of the mechanical servo control task is the highest priority.
[0032]
The DVC needs to perform zoom / AF (automatic focus adjustment processing) control in the camera mode (shooting mode), and these controls are also performed according to sampling of the AF evaluation value output from the camera signal processing circuit 1-3. It is necessary to perform control with high responsiveness. For this purpose, the lens control (zoom / AF control) task has the following priority. The image stabilization (IS) control is also a control performed in the camera mode, and it is necessary to generate an output related to the IS control in quick response to the read timing of the gyro sensor 1-4. In order to achieve higher performance, this IS control task is set to the next priority.
[0033]
The next highest priority task is the camera signal processing task. The camera signal processing task is a task for controlling an automatic exposure correction process (hereinafter, AE) and an automatic white balance process (hereinafter, AWB). The task is to quickly respond to a constantly changing subject state and maintain an appropriate image state. Therefore, it is necessary to perform processing with a higher priority.
[0034]
In the present embodiment, the priority of the bitmap memory writing task is set next to the above task that needs to be processed at high speed. Therefore, in the camera mode, the bitmap memory writing task is performed in a state where the lens control task, the IS control task, and the camera signal processing task for performing the AE / AWB are fully operated. It is difficult to switch many character strings with quick response.
[0035]
Therefore, in this embodiment, two modes are provided for each of the lens control, IS control, and camera signal processing tasks, and the menu display mode is operated in a mode in which the processing load of the microcomputer 1-13 is reduced. This has improved this problem. The DVC according to the present embodiment includes a mode 1 in which AE, AWB, AF, and IS processes are sequentially performed (a mode in which the processing load of the microcomputer 1-13 increases), and a predetermined mode among AE, AWB, AF, and IS processes. Mode 2 (mode in which the processing load of the microcomputer 1-13 is reduced).
[0036]
In the present embodiment, the task is divided into a bitmap memory writing task (processing) and a task having a plurality of processing modes other than the bitmap memory writing task. The plurality of processing modes include a high-precision control mode in which processing is performed for each field image forming a video, and a low processing load in which processing is performed for each frame forming a video or processing is performed at a reduced processing rate. Control mode.
[0037]
Next, a camera control process in the DVC according to the present embodiment will be described with reference to the flowchart in FIG. The camera control process shown in this flowchart is executed by the microcomputer 1-13 based on a control program stored in an internal memory (not shown).
[0038]
The camera control process is executed by a VD (1-j) interrupt process. First, in step S4-1, the microcomputer 1-13 determines whether a menu is being displayed on the monitor. If it is determined in step S4-1 that the menu is not being displayed, the process proceeds to step S4-11, and the microcomputer 1-13 operates in the normal mode, that is, the mode 1 in which the AE, AWB, AF, and IS processes are sequentially performed. To control. In mode 1, high-precision control is possible because all processing is performed at the same VD timing, but the processing load on the microcomputer 1-13 increases. In step S4-11, AE processing is performed in step S4-7, AWB processing is performed in step S4-8, AF processing is performed in step S4-9, IS processing is performed in step S4-10, and this processing ends. I do. Note that the AE processing, the AWB processing, the AF processing, and the IS processing are well-known processing, and thus the details are omitted.
[0039]
On the other hand, when it is determined in step S4-1 that the menu is being displayed (menu display mode), the process proceeds to step S4-12, and the microcomputer 1-13 controls to operate in the mode 2 in which the processing is thinned out. In mode 2, the processing load on the microcomputer 1-13 is reduced as described later. In step S4-12, in step S4-2, the microcomputer 1-13 determines whether or not the menu display screen is currently the first field (one of the two fields forming the video frame). If it is determined in step S4-2 that the field is the first field, AE processing is performed in step S4-3, AWB processing is performed in step S4-4, and this processing ends. If it is determined in step S4-2 that the field is not the first field, AF processing is performed in step S4-5, IS processing is performed in step S4-6, and this processing ends.
[0040]
As described above, in the mode 2, predetermined processes among the AE process, the AWB process, the AF process, and the IS process are thinned out (in steps S4-3 to S4-4, the AF process and the IS process are thinned out and step S4 is performed). -5 and step S4-6, the AE processing and the AWB processing are thinned out), which is inferior to the mode 1 in accuracy. However, since the processing load of the microcomputer 1-13 can be reduced, Accordingly, the bitmap memory writing task can perform many processes. Therefore, in the above-described menu display mode, it is possible to switch (rewrite) many character strings with a quick response.
[0041]
As described above, according to the present embodiment, when executing the menu display mode in which many character strings need to be rewritten with a quick response, the camera-related processing is performed in a mode in which the load on the microcomputer 1-13 can be reduced. , A high-speed menu display with less stress on the user can be performed. At the same time, the bitmap memory writing process and many other processes can be performed by the same CPU.
[0042]
[Other embodiments]
In the above embodiment, the case where the priorities of the respective tasks executed by the digital video camera are set to the priorities shown in FIG. 7 has been described as an example, but the present invention is not limited to this, and the digital video camera is not limited to this. Priority can be set according to the specifications of the camera.
[0043]
In the above embodiment, the case where the recording system of the digital video camera is the helical scan system has been described as an example, but the present invention is not limited to this, and can be applied to other recording systems.
[0044]
In the above embodiment, the case where the present invention is applied to a digital video camera has been described as an example. However, the present invention is not limited to this, and various camera-integrated video recording devices or camera-integrated video recording / reproducing. Applicable to the device.
[0045]
Another object of the present invention is to supply a storage medium storing program codes of software for realizing the functions of the embodiments to a system or an apparatus, and a computer (or CPU, MPU, or the like) of the system or the apparatus stores the storage medium. It is also achieved by reading and executing the program code stored in the.
[0046]
In this case, the program code itself read from the storage medium realizes the functions of the above-described embodiment, and the storage medium storing the program code constitutes the present invention.
[0047]
Examples of a storage medium for supplying the program code include a floppy (registered trademark) disk, hard disk, magneto-optical disk, CD-ROM, CD-R, CD-RW, DVD-ROM, DVD-RAM, and DVD. -RW, DVD + RW, magnetic tape, nonvolatile memory card, ROM, and the like can be used.
[0048]
When the computer executes the readout program code, not only the functions of the above-described embodiment are realized, but also an OS (Operating System) running on the computer based on the instruction of the program code. This also includes a case where some or all of the actual processing is performed and the functions of the above-described embodiments are realized by the processing.
[0049]
Further, after the program code read from the storage medium is written into a memory provided in a function expansion board inserted into the computer or a function expansion unit connected to the computer, the function expansion is performed based on the instruction of the program code. This also includes the case where the CPU or the like provided in the board or the function expansion unit performs part or all of the actual processing, and the processing realizes the functions of the above-described embodiments.
[0050]
[Example of Embodiment]
Examples of embodiments of the present invention are listed below.
[0051]
"Embodiment 1"
In a video information display control device that performs display control of video information,
Additional image information generation means for generating additional image information to be added to a video signal; additional image information storage means for storing a bitmap pattern of the additional image information; and a bitmap of the additional image information stored in the additional image information storage means. Control means for sequentially executing a write process for writing a pattern and a process other than the write process, and executing a process other than the write process in a mode in which a processing load is reduced when a specific operation state is reached,
The video information display control device, wherein the mode in which the processing load is reduced is a mode in which a predetermined process is thinned out of processes other than the writing process.
[0052]
With this configuration, a screen display using many characters is performed using a bitmap display, which is a display method of writing a bitmap pattern of additional image information into a memory (additional image information storage unit) and outputting high-quality graphical information. Can be realized by the same CPU (control means) together with many other processes.
[0053]
"Embodiment 2"
The video information display control device according to claim 1, wherein the specific operation state is a menu display state for displaying a menu relating to the additional image information for performing a predetermined setting from outside.
[0054]
With this configuration, menu display using a bitmap and many other processes can be realized by the same CPU.
[0055]
"Embodiment 3"
3. The video information display control device according to claim 1, wherein the processing other than the writing processing includes processing related to an imaging unit, such as automatic focus adjustment processing, automatic white balance processing, and image stabilization processing.
[0056]
With this configuration, menu display using a bitmap and camera-related control processing can be realized by the same CPU.
[0057]
"Embodiment 4"
The processing other than the writing processing has a plurality of processing modes, and the plurality of processing modes include a high-precision control mode in which processing is performed for each field image forming a video, and a The video information display control apparatus according to the first or third embodiment, further comprising: a low processing load control mode in which the processing is performed at a lower rate or the processing rate is reduced.
[0058]
With this configuration, it is possible to realize the menu display and the video-related control processing using the bitmap by using the same CPU by using the low processing load control mode in which the processing rate of the video-related control is reduced. .
[0059]
"Embodiment 5"
In a video recording device that records a video signal output from an imaging unit on a magnetic recording medium,
Signal processing means for converting the video signal into a recording signal on the magnetic recording medium; additional image information generating means for generating additional image information to be added to the video signal; and storing a bitmap pattern of the additional image information. An additional image information storage unit, a writing process for writing the bitmap pattern of the additional image information in the additional image information storage unit, and a process other than the writing process are sequentially executed. Control means for executing processing other than processing in a mode in which the processing load is reduced.
[0060]
With this configuration, in the camera-integrated video recording device, control processing for switching the screen display using many characters at once using bitmap display is realized by the same CPU together with many other processes. It becomes possible.
[0061]
"Embodiment 6"
The video recording apparatus according to claim 5, wherein the mode in which the processing load is reduced is a mode in which a predetermined process is thinned out of processes other than the writing process.
[0062]
"Embodiment 7"
The video recording apparatus according to claim 5, wherein the specific operation state is a menu display state for displaying a menu related to the additional image information for setting the video recording apparatus from outside.
[0063]
With this configuration, in the camera-integrated video recording device, menu display using a bitmap and many other processes can be realized by the same CPU.
[0064]
"Embodiment 8"
6. The video recording apparatus according to claim 5, wherein the processing other than the writing processing includes processing related to the imaging unit, such as automatic focus adjustment processing, automatic white balance processing, and image stabilization processing.
[0065]
With this configuration, in the camera-integrated video recording apparatus, menu display using a bitmap and camera-related control processing such as automatic focus adjustment processing, automatic white balance processing, and image stabilization processing are realized by the same CPU. It becomes possible.
[0066]
"Embodiment 9"
The processing other than the writing processing has a plurality of processing modes, and the plurality of processing modes include a high-precision control mode in which processing is performed for each field image forming a video, and a The video recording apparatus according to the fifth or eighth embodiment, further comprising: a low processing load control mode for performing processing at a reduced processing rate or performing processing at a reduced processing rate.
[0067]
With this configuration, the menu display using the bitmap and the camera-related control processing can be realized by the same CPU by using the low processing load control mode in which the processing rate of the camera-related control is reduced. .
[0068]
"Embodiment 10"
The recording system according to any one of the fifth to ninth embodiments, further comprising a recording system for recording a video signal output from the imaging unit on a track formed obliquely on a magnetic tape by a plurality of magnetic heads mounted on a drum motor. The video recording device according to any one of the above.
[0069]
"Embodiment 11"
A video recording / reproducing apparatus comprising: the video recording apparatus according to any one of Embodiments 5 to 10; and a video reproducing apparatus for reproducing a video from the magnetic recording medium.
[0070]
"Embodiment 12"
An additional image information generating step of generating additional image information to be added to the video signal, a writing process of writing the bitmap pattern of the additional image information in the additional image information storage unit, and a process other than the writing process are sequentially executed and specified. And a control step of executing a process other than the writing process in a mode in which the processing load is reduced when the operation state of (1) is reached.
[0071]
"Embodiment 13"
A function of generating additional image information to be added to the video signal, a write process of writing the bitmap pattern of the additional image information in the additional image information storage means, and a process other than the write process are sequentially executed to set a specific operation state A program for causing a computer to execute a function other than the writing processing in a mode in which the processing load is reduced when the processing becomes lighter.
[0072]
"Embodiment 14"
In a computer-readable storage medium storing a program for executing the video information display control method,
The video information display control method includes: a step of generating additional image information to be added to a video signal; a writing process of writing a bitmap pattern of the additional image information in an additional image information storage unit; and a process other than the writing process. And executing a process other than the write process in a mode in which the processing load is reduced when the specific operation state is reached.
[0073]
【The invention's effect】
As described above, according to the present invention, the control unit of the video information display control device sequentially executes a writing process of writing the bitmap pattern of the additional image information in the additional image information storage unit and a process other than the writing process. However, when a specific operation state is reached, processing other than the write processing is executed in a mode in which the processing load is reduced. That is, it is necessary to rewrite many character strings with a quick response by using a bitmap display, which is a display method of writing bitmap patterns of additional image information into a memory (additional image information storage means) and outputting high-quality graphical information. When a certain menu display is executed, a process other than the writing process is executed in a mode in which the load on the control unit is reduced, whereby a high-speed menu display with which the user does not feel stress can be performed. At the same time, the same control unit can perform the writing process of writing the bitmap pattern of the additional image information in the additional image information storage unit and many other processes.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a digital video camera according to an embodiment of the present invention.
FIG. 2 is a diagram showing a display example of a menu setting display screen.
FIG. 3 is a diagram illustrating a display example of a menu setting display screen.
FIG. 4 is a flowchart illustrating a camera control process.
FIG. 5 is a block diagram illustrating a configuration of a bitmap information generation circuit.
FIG. 6 is a timing chart showing a read operation of the bitmap information generation circuit.
FIG. 7 is a diagram showing a microcomputer processing task list showing types of tasks to be processed by the microcomputer, processing outlines, and task priorities;
FIG. 8 is a block diagram showing a configuration of a digital video camera according to a conventional example.
[Explanation of symbols]
1-1 Lens
1-2 CCD (imaging means)
1-3 Camera signal processing circuit
1-4 Gyro sensor
1-5 Video signal processing circuit (signal processing means)
1-6 Bitmap information generation circuit (additional image information generation means)
1-7 Bitmap memory (additional image information storage means)
1-8 Adder
1-9 Mechanical deck
1-10 Digital interface
1-11 Remote control input means
1-12 Key input means
1-13 Microcomputer (control means)
1-a Lens control
1-b Camera signal processing circuit control
1-c Gyro signal read
1-d Video signal processing circuit control
1-e Mechanical mode control / mechanical servo control
1-f Bitmap information generation circuit control
1-g User interface input
1-h Write bitmap memory
1-i VD, HD synchronization signal
1-j VD interrupt signal

Claims (1)

In a video information display control device that performs display control of video information,
Additional image information generation means for generating additional image information to be added to a video signal; additional image information storage means for storing a bitmap pattern of the additional image information; and a bitmap of the additional image information stored in the additional image information storage means. Control means for sequentially executing a write process for writing a pattern and a process other than the write process, and executing a process other than the write process in a mode in which a processing load is reduced when a specific operation state is reached. Characteristic video information display control device.

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