JPS61273585A - Resolution specification control system - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Summary] In a graphic processing system J- in which a processing device and a display unit are connected, it is easy to correct coordinate data of a figure when display units with different resolutions of 1iiiWJ are connected to the processing device. The aim is to

[Industrial application field]

The present invention relates to an improvement in a resolution specification control method for correcting coordinate data according to the resolution of a display device in a graphic processing system. There is a need for countermeasures that can be easily corrected based on data.

[Conventional technology]

A conventional example will be explained using figures. Figure 3 is a simplified diagram of a conventional example of a mouth figure processing system, in which coordinate data (X, Y) sent from a processing device 11 is stored in a display system 12 via a display control section 11. . Data j in the display memory 12 is read out and displayed on the display section 3.

In the case of Rusk scan display method, display memory 12t
The display control section 11 sequentially reads out this dot information and sends it to the display section 3, thereby displaying the figure.

When a cathode ray tube display device is used as the display section 3,
The screen resolution differs depending on the type of display device.

For example, the resolution of Kai model P is (model: 160, vertical: 160)
The resolutions of the screens are different, such as the resolution Fi (width: 600.vertical: 200) of another model Q.

! In Figure 3, the screen resolution of the display unit 3 is (horizontal: 1
28. Height: 100). Therefore, the maximum screen is point A-D
The coordinate data for displaying each point is as follows: Point A: CXg = 0-
Yt = O) 8 points: (Xt=1.Yt;99) 0 points: (Xs”127. Yn=127) 0 points:
(X4=127.Y number-0). The coordinate data (X, Y) as described above is sent from the processing device 1 to the display control unit 1.
1, and the dot information is written in the memory location (picture cell) in the display memory 12 according to the coordinate data.The dot information in the display memory 12 is sequentially read out and sent to the display unit 3. In such a graphic display processing system, a rectangle is displayed on the screen 4 by being scanned and displayed (rusk scan). , when the connection is changed to the display control unit 10, the graphics displayed on the screen 14 are shifted to the left half of the screen. That is, the display unit 3 received and displayed the coordinate data (X, Y) of the rectangle ABCD as the maximum size information of the screen 4, but when this is connected to the display unit 13, the same coordinate data (X, Y) is displayed. In Y), a square ABCD is displayed on the left half of the screen 14 as shown in the figure. The display unit 13 has twice the resolution only in the X direction. On the other hand, in the case of a display section with twice the resolution in both the X and Y directions, the same coordinate data will result in When switching to a different display section, that is, when switching to a display section with a higher resolution, the display screen is reduced in size, making it inconvenient to actually measure figures (signal waveforms, etc.) on the screen with a ruler. Conversely, when switching to a display section with a lower resolution, there were problems such as screen cutouts.

[Means for solving problems]

FIG. 1 is a diagram showing the principle of the present invention. The present invention provides a processing device 1
In a system for displaying figures on a screen 4 of a display unit 3 by receiving horizontal and vertical coordinate data 2 from a data table 7 in which coefficient data 6 of a ratio according to a resolution screen 40 division power 5 is set; ' An input section 9 having eight designating means for designating the resolution 5, and an arithmetic processing means 10 for multiplying the coordinate data 2 by the coefficient data 6 extracted from the data table 7 according to the input resolution 5. Operation processing means by entering the display device 30 -decomposition No 5 by specified means 8 of the input unit 9, when connected to the display portion 3 with a screen 4 that has a screen 4 of the resolution 5. 10
extracts the coefficient data 6 of the ratio according to the input resolution 5 from the data table 7, multiplies it by the coordinate data 2, and sends it to the display section 3.As a result, the display section with different resolution can be processed. Even when connected to a device, it is possible to display a figure of an appropriate size in accordance with the resolution ratio.

〔Example〕

Hereinafter, the present invention will be explained with reference to the drawings. FIG. 2 is a block diagram illustrating an embodiment of the present invention. In the present invention, an input section (keyboard) 9 is provided with a resolution and specifying means 8, as well as a data table 7 and an arithmetic processing means 102. ing. In the embodiment shown in FIG. 2, three types of display units, G, H, and I, are used. The resolutions of the three types of display sections G, H, and SEM shall be as follows.

Resolution model G......Horizontal: 128. Vertical: 128 models, horizontal: 256. Vertical = 256 models/
・・・・・・・・・Horizontal: 1024. Vertical: 1024 Therefore, the vertical and horizontal resolution of model H is twice that of model G,
In addition, the resolution of the model is eight times that of model G. This resolution ratio is set in the data table 7 as coefficient data. From this K, coefficient data corresponding to each model is stored and registered in the data table 7 as shown in the figure.

Note that the vehicle volume data (X.

Y) is coordinate data adapted to the display unit 3 of model G.

That is, when the display section 3 is connected to the display control section 11, the operator holds the handle 16 of the resolution specifying means 8 of the input section 9 at r.
Set it in the device marked GJ.

The control signal g thus input is sent from the control section 15 to the arithmetic processing section 10.

Upon receiving this control signal g, the arithmetic processing unit 10 accesses the data table 7 and takes out the coefficient data Nt (X〒rlJ, Y=rlJ) of the g term.

Then, the coordinate data (X, Y
) is multiplied by this coefficient data N, and the result is sent to the display control section 11. Note that the coefficient data N in this case is x
, y are K'knees, so the coordinate data values do not change.

When the coordinate data (X, Y) is on the maximum screen 4 of the display section 3, a rectangle abed is displayed on the display section 3 as shown in the figure.

Next, when the display section 3 of model G is connected to the display section 13 of model H, the operator should press the handle 16 of the input section 9 to
The control signal generated thereby is sent from the control section 15 to the arithmetic processing section 10.

The arithmetic processing unit 10 that receives this control signal calculates coefficient data N*(X= r2J
, Y= r2J). Then, the coordinate data (X, Y) from the processing device 1 is multiplied by this coefficient data Nyo and sent to the display control section 11.

Therefore, the square ABCD is displayed on the screen 14 of the display unit 13. That is, points A and B on the screen 14.

C and D correspond to points &, b, ( and dK on the screen 4 of the display unit 30, respectively; for example, the coordinates of point C are (12
7,127), while the seat material at point C is (255,
255).

As described above, in the present invention, even when display units with different resolutions are connected, the figures on the screen are displayed according to the resolution.
Displayed relatively enlarged.

〔Effect of the invention〕

The present invention has the advantage that display devices with different resolutions can be operated without changing the processing program in the processing device.

[Brief explanation of drawings]

Fig. 1 is a principle diagram of the present invention, Fig. 2 is a block diagram explaining an embodiment of the present invention, Fig. 3 is a block diagram of a conventional example, l is a processing device, 2 is coordinate data, 3.13ti display Department,
4.14 is the screen, 5 is the resolution, 6 is the coefficient data, 7 is the data table, 8 is the specifying means, 9 is the input section, 10 is the arithmetic processing section, 11 is the display control section, 12 is the display memory, 15 is the control 16 indicates a handle.

Claims (1)

[Claims] In a system that displays a figure on a screen 4 of a display unit 3 by receiving horizontal and vertical coordinate data 2 from a processing device 1, coefficient data 6 of a ratio according to a resolution 5 of the screen 4 is set. an input unit 9 having a specifying means 8 for specifying the resolution 5; and an arithmetic processing means for multiplying the coordinate data 2 by the coefficient data 6 extracted from the data table 7 according to the input resolution 5. 10, and a display section 3 having a screen 4 with a predetermined resolution 5 is connected to a processing device 1.
By inputting the resolution 5 of the display device 3 through the specifying means 8 of the input section 9, the arithmetic processing means 1
0 is the coefficient data 6 of the ratio according to the input resolution 5
is extracted from the data table 7, multiplied by the coordinate data 2, and sent to the display section 3.