JP2000148066A - Image display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make a display character easy to see even when an interlace video signal is converted to a non-interlace video signal to be displayed on a liquid crystal monitor. SOLUTION: The non-interlace video signal is formed from the interlace video signal, and a map is displayed on a liquid crystal screen 36 by the non- interlace video signal. In such a case, (1) when the map is scrolled manually and continuously for a prescribed time or above, the non-interlace video signal is generated at every (n) pictures by control of a memory controller 34, and the map is scroll displayed intermittently on the liquid crystal screen, and (2) at other times, the non-interlace video signal is formed at every one picture, and the map is scroll displayed continuously on the liquid crystal screen.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image display method, and more particularly, to an image display method in which a progressive scan video signal is created from an interlaced scan video signal and an image is displayed on a screen using the progressive scan video signal. .

[0002]

2. Description of the Related Art A navigation device that provides guidance for driving a vehicle so that a driver can easily reach a desired destination detects a position of the vehicle and detects a position of the vehicle on a map recording medium (for example, a CD).
-ROM, DVD disk) to read map data around a vehicle position, draw a map image on a display screen, and draw a vehicle position mark on a predetermined location on the map image in a superimposed manner. Then, as the vehicle position changes due to the movement of the vehicle, the vehicle position mark is fixed at a predetermined position on the screen and the map is scrolled, so that the map information around the vehicle position can always be understood at a glance. Such a navigation device searches for a guidance route from a starting point to a destination,
It has a route guidance function of displaying the guidance route on a map and performing intersection guidance (enlarged intersection, display of arrow in traveling direction). The navigation device has a function of scrolling a map by operating a joystick key. The map scroll function can be used when a destination is input with a cursor or when a point such as a home is registered.

FIG. 3 is a block diagram of a navigation device. 1 is a navigation control device for performing various navigation controls, 2 is a joystick key or a menu key,
Remote control with map reduction / enlargement keys, 3 is a map,
A liquid crystal color monitor for displaying a guide route, etc., 4 is a recording medium (for example, a CD-ROM) for storing map information, 5 is a position detecting device for measuring the current position of the vehicle, a vehicle speed sensor for detecting the moving distance, and moving. A gyro that detects the direction,
It is composed of a GPS receiver, a position calculation CPU and the like.

In the navigation control device 1, 11
Is a map readout control unit that calculates a cursor position (coordinate and latitude position at the center of the screen) when a map scroll operation or a map selection operation is performed using a joystick key, a map reduction / enlargement key, or the like, and a vehicle position (normal time). Alternatively, predetermined map information is read from the CD-ROM 4 based on the cursor position (during scrolling) or the like. 12 is CD-
It is a map buffer for storing map information read from the ROM. In the map buffer, map information of a plurality of sheets (a plurality of units) around the own vehicle position or the cursor position is read and stored so that the map can be scrolled. 13
Is a map drawing unit that generates a map image using map information stored in a map buffer, 14 is a VRAM that stores the map image, and 15 is based on a screen center position (own vehicle position or cursor position). A map cutout control unit that changes the position (window position) of one screen cut out from the VRAM 14 and scrolls and displays the map according to the movement of the vehicle position or the movement of the cursor.

Reference numeral 16 denotes a color palette, and a palette N
O. R, G, B values (R, G, B data) corresponding to
I remember. 16 map colors, 0 to 7 for each color
If the colors of the vehicle position mark and the like are set to 128 colors, the palette No. 0-255
, R, G, and B data are stored. 17
Denotes a color pallet control unit, which stores R, G, B data corresponding to image data (palette number) in a color pallet 1
An NTSC encoder (DA converter) 18 for converting the R, G, B data into an NTSC color monitor color signal and inputting it to the liquid crystal color monitor 3, and 19 a remote control controller is there.

FIG. 4 is a diagram for explaining the timing of generation of an adjacent map during a scroll operation. When scrolling by operating the joystick key provided on the remote control 2 starts,
The map readout control unit 11 reads out map data over a wide area around the cursor position, stores it in the map buffer 12, and notifies the map extraction control unit 15 of "being scrolled" and the cursor position (screen center position). The map drawing unit 13 generates a map image and draws the map image on the VRAM 14, and the map cutout control unit 15 uses the VRAM 14 to display one screen (window W) based on the cursor center position.
The image of D) is cut out, and the color palette control unit 17
Input is made to the color monitor 3 via the TSC encoder 18, and the color monitor 3 displays a map.

The map reading control unit 11 checks whether the window WD has reached an adjacent area map generation line BL set in advance around the outer periphery of the VRAM as shown in FIG. If not, it is checked whether the map scroll operation has been completed. If the scroll operation has not been completed, the map scrolling position is changed and the map scroll display is performed. That is, the map reading control unit 11 calculates the cursor position in accordance with the scroll speed and calculates the map cutout control unit 1.
5, the map cutout control unit 15 cuts out an image for the next one screen from the VRAM 14 based on the cursor center position, inputs the cutout image to the color monitor 3, and displays a map.

Thereafter, when the map scrolling is continued and the window WD reaches the adjacent area map generation line BL, the map reading control unit 11 converts the map data of the adjacent area in the scroll direction (the hatched area in FIG. 4A) into a map. The data is read from the recording medium 4 and stored in the map buffer 12. Thus, the map drawing unit 13 generates a map image using the map data of the adjacent area and stores the map image in the VRAM 14 (FIG. 4B). Thereafter, the above processing is repeated to scroll the map.

By the way, in television broadcasting, the number of scanning lines is set to 525 and 30 images are formed per second. Therefore, a solid line 1-263 and a dotted line 2 in FIG.
By alternately performing the scans 63 'to 525' (interlaced scan), 60 vertical scans (field scans) are performed per second to create 60 images. Since two fine scanning line images form one fine scanning line image,
As a result, 30 fine scanning line images are created per second.
That is, two-field scanning becomes one-frame scanning.
The reason why the interlaced scanning is performed is that the time required for scanning one sheet can be shortened, and thereby flickering of the image can be eliminated. A video signal by interlaced scanning (interlaced scanning) is also input to the liquid crystal color monitor 3 in FIG. However, since the number of scanning lines of the conventional liquid crystal color monitor 3 is as small as 240, a pseudo non-interlaced display is performed as shown in FIG.

[0010] Recently, the number of scanning lines of the liquid crystal color monitor has doubled to 480, so that the conventional pseudo non-interlaced display cannot be performed. On the other hand, a liquid crystal color monitor cannot perform interlace display but can only perform non-interlace display due to its drive control. For this reason,
A video signal by interlaced scanning input to the liquid crystal color monitor must be converted into a non-interlaced video signal and input to the liquid crystal color monitor.

FIG. 7 is a configuration diagram of a liquid crystal color monitor for converting a video signal by interlaced scanning into a video signal of non-interlaced scanning and displaying the converted video signal. Reference numeral 21 denotes an AD converter for converting a video signal obtained by interlaced scanning into a digital signal; 22a, a first field memory for storing an interlaced video signal obtained by interlaced scanning in the first field; and 22b, a second field memory for interlaced scanning.
A second field memory for storing an interlaced video signal obtained by field scanning, 23 is a memory control circuit, 24 is a buffer, and 25 is an LCD display panel. The memory control circuit 23 stores (1) the interlaced video signal obtained by the first field scan in the first field memory 22a, and stores the interlaced video signal obtained by the second field scan in the second field memory 22a.
b, (2) first and second field memories 22
A non-interlaced video signal is generated by alternately reading a video signal from a and 22b for each scanning line and storing the video signal in a buffer 24 and inputting it to an LCD display panel 25.

[0012]

When an image is displayed by the configuration shown in FIG. 7, the image is out of focus (the image is displayed with a shift).
In particular, when the map image is scrolled at a high speed in the direction a as shown in FIG. 8, the display becomes blurred as if an afterimage remains on the display screen, and the displayed characters cannot be read. This is because the first field image and the second field image that are temporally shifted are overlapped and displayed. As the scroll speed increases, the degree of the shift increases, and the picture flows, making it difficult to read the characters. become. In view of the above, it is an object of the present invention to prevent the flow of a picture and make the displayed characters easy to see.

[0013]

According to the present invention, when scrolling at a high speed, a non-interlaced scanning video signal is generated every n screens (n is an integer of 2 or more), and an image is displayed on a screen by the video signal. I do. If you do this,
Since the image is scrolled and displayed intermittently like frame advance, the flow of the picture can be prevented to make the displayed characters easier to see.

In the present invention, when a map image is continuously scrolled for a predetermined time or more by a manual operation, a non-interlaced scanning video signal is generated every n screens, and the map is displayed on the screen. At the time, a non-interlaced scanning video signal is generated for each screen and a map is displayed on the screen. With this configuration, even when the map is scrolled at high speed, the map can be scrolled intermittently, so that the flow of the picture can be prevented and the displayed characters can be easily viewed. When it is not necessary to scroll the map at a high speed, for example, when the map is scrolled according to the traveling of the vehicle, a non-interlaced scanning video signal is generated for each screen and the map is displayed on the screen. From
Continuous map scroll display is possible.

[0015]

FIG. 1 is a block diagram of a liquid crystal monitor for realizing an image display method according to the present invention. In the figure, reference numeral 31 denotes an amplifier for amplifying an analog video signal by interlaced scanning input from a navigation device, and 32 denotes an AD.
A converter for converting an analog interlaced video signal into a digital signal. Reference numeral 33 denotes a memory for storing an interlaced scanning video signal. Reference numeral 33a denotes a video signal (first video signal) obtained by interlaced scanning first field scanning. A first field memory for storing a field image), a second field memory 33b for storing a video signal (second field image) obtained by interlaced second field scanning, a memory control circuit 34, and a non- A buffer memory for storing an interlaced video signal, 36 is an LCD display panel, 37 is a scroll operation detecting unit for detecting a manual scroll operation from a remote control signal, and 38 is whether to scroll the map image intermittently (frame feed). , A frame feed determining unit for determining whether to make the frame continuous.

The higher the scroll speed of the map image, the greater the degree of displacement between the first field image and the second field image, causing the picture to flow, making it difficult to read the characters. On the other hand, even if the scroll speed increases, if the time of the high-speed scroll is short, the character can be read after the time. Therefore, the frame advance determination unit 38 instructs the memory controller 34 to advance a frame only when a manual scroll operation is instructed for a predetermined time or more (1 second or more), and instructs a continuous feed otherwise.

The memory controller 34 generates (1) a non-interlaced video signal from an interlaced video signal input from a navigation device for each screen unless a frame advance is instructed, and an image is formed by the interlaced video signal. Is displayed on the screen. (2) If frame advance is instructed, every n screens (n is an integer of 2 or more)
Then, a non-interlaced video signal is created from the interlaced video signal input from the navigation device, and control is performed so that an image is displayed on a screen by the interlaced video signal.

That is, the memory control circuit 34
(1) If the frame feed is not instructed, the interlaced video signal obtained by the first field scan is stored in the first field memory 33a, and the interlaced video signal obtained by the second field scan is stored in the second field memory 33.
b, and thereafter, the video signal is alternately read out from the first and second field memories 33a and 33b for each scanning line and stored in the buffer 35 to generate a non-interlaced video signal. Race video signal to LC
Input to the D display panel 36. As a result, when it is not necessary to scroll the map at high speed, for example, when scrolling the map according to the driving of the vehicle, a non-interlaced video signal is generated for each screen and the image is displayed on the screen. The map can be scrolled continuously.

The memory control circuit 34
(2) If frame advance is instructed, an interlaced video signal by the first field scan is stored in the first field memory 33a for every n screens, and an interlaced video signal by the second field scan is stored. The video signal is stored in the second field memory 33b. Thereafter, the video signal is alternately read out from the first and second field memories 33a and 33b for each scanning line and stored in the buffer 35 to generate a non-interlaced video signal. . Thereafter, the non-interlaced video signal is repeatedly read from the buffer memory 35 and input to the LCD display panel 36. As a result, if the frame feed is instructed, even if the map is scrolled at a high speed, the map is scrolled intermittently, so that the flow of the picture can be prevented and the displayed characters can be easily viewed. That is, as shown in FIG.
At t ₂ and t ₃ , the characters are displayed without overlapping at different positions on the screen, so that the displayed characters can be easily read.

In the above, whether or not the high-speed scroll is instructed for a set time or more in the navigation device is determined.
In this case, it is determined whether to perform the frame-feed scroll control or the continuous-feed scroll control. However, the present invention is not limited to such a case, and the frame-feed scroll control can be performed as needed. As described above, the present invention has been described with reference to the embodiments. However, the present invention can be variously modified in accordance with the gist of the present invention described in the claims, and the present invention does not exclude these.

[0021]

As described above, according to the present invention, every n screens (n is 2
A video signal of progressive scanning (non-interlaced scanning) is created from a video signal of interlaced scanning (interlaced scanning), and an image is displayed on a screen by the video signal. As shown in the figure, scroll display can be performed intermittently, and the flow of the picture can be prevented to make the displayed characters easy to see.

Further, according to the present invention, when the map is scrolled at high speed continuously for a predetermined time or more by a manual operation, n
A non-interlaced scanning video signal is generated for each screen and a map is displayed on the screen. At other times, a non-interlaced scanning video signal is generated for each screen and the map is displayed on the screen. As a result, the map can be intermittently scroll-displayed, so that the flow of the picture can be prevented and the displayed characters can be easily viewed. In addition, when it is not necessary to scroll the map at high speed, for example, when scrolling the map according to the driving of the vehicle, a non-interlaced scanning video signal is generated for each screen and the image is displayed on the screen. By doing so, the map can be continuously scroll-displayed.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a liquid crystal monitor device that realizes an image display method of the present invention.

FIG. 2 is an explanatory diagram of a character display according to the present invention.

FIG. 3 is a configuration diagram of a navigation device.

FIG. 4 is an explanatory diagram of timing of generation of an adjacent map.

FIG. 5 is an explanatory diagram of interlaced (interlaced) scanning.

FIG. 6 is an explanatory diagram of a pseudo non-interlaced display on a liquid crystal monitor.

FIG. 7 is a configuration diagram of a liquid crystal color monitor that converts a video signal by interlaced scanning into a video signal of progressive scanning and displays the video signal.

FIG. 8 is an explanatory diagram of a conventional problem.

[Explanation of symbols]

 31 ••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••• Part 38 ・ ・ frame advance decision part

 ──────────────────────────────────────────────────続 き Continued on front page F term (reference) 2H093 NA44 NC16 NC24 NC28 NC29 ND12 ND34 NG03 5C058 AA08 AA18 BA18 BB13 BB15 BB16 BB17 BB23 5C080 AA10 BB05 CC03 DD02 EE29 EE30 FF09 GG02 GG08 GG01 GG02

Claims (2)

[Claims] 1. An image display method for producing a progressively scanned video signal from an interlaced video signal and displaying an image on a screen by the progressively scanned video signal, wherein every n screens (n is an integer of 2 or more) An image display method, comprising: generating a video signal of progressive scanning, and displaying an image on a screen using the video signal. 2. The image is a map image of a navigation device. When the map image is scrolled continuously for a predetermined time or more by a manual operation, a video signal of sequentially scanning is generated every n screens and the image is displayed on a screen. 2. The image display method according to claim 1, further comprising the steps of: generating a progressively scanned video signal for each screen, and displaying the image on a screen otherwise.