JPH065871B2 - Image data storage - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image data storage device, and in particular, can store binary or multi-valued image data in a memory having a smaller capacity, and can relatively easily input / output and edit ( Image data storage device that can be partially moved).

As conventional image data storage methods, there have been many methods of storing image data read in time series in the main scanning direction as they are and compressing data in the one-dimensional (main scanning) direction.

However, as described above, the method of storing image data as it is has a drawback that a very large capacity memory is required, while the one-dimensional direction data compression method is advantageous for communication, When editing, there is the drawback that it is unwieldy and unsuitable.

Note that editing here means moving the image partially,
It means overlapping or rotating, reducing or enlarging images.

It is an object of the present invention to provide an image data storage device which can store image data in a memory having a relatively small capacity and can be easily edited.

Hereinafter, the present invention will be described in detail with reference to the drawings.

First, the technique underlying the present invention will be described.

FIG. 1 is a schematic diagram showing a state in which an image is divided into units, and 1 is an image. As is clear from the figure, image 1
Is composed of M × p dots in the horizontal direction and N × q dots in the vertical direction. Therefore, image 1 is divided into p × q units.

FIG. 2 is a schematic diagram showing an example of the map memory. As is clear from the figure, the map memory 2 includes p × q unit memories corresponding to the positions of the units in FIG. 1 on the image.

Then, the following information is stored in each unit memory.

1) 0 when the image information of the corresponding unit is all 0 (white), or a specific number 2) When the image information of the corresponding unit is not all 0, the image data of the corresponding unit is stored Pointer or link address to the existing data memory (for example, the start address of the data memory described later) FIG. 3 is an explanatory diagram of the data memory. Data memory 3
Stores the image information in units of M × N dots for the units whose image information is not all 0 among the units shown in FIG. The storage address is the position designated by the map memory.

For example, on the screen of FIG. 1, (i, j) and (l, m)
Assuming that the unit includes image information, the information of the (M × N) dots is stored in the memory areas 3-1 and 3-2 of FIG. 3, respectively. Then, pointers to the memory areas are stored at the (i, j) (l, m) positions of the map memory, respectively.

As is clear from the above, the map memory 2 must correspond to the position on the image of each unit, but the data memory 3 is only required to be grouped for each unit.
The arrangement may be random.

Below, such an image data storage system
A more detailed description will be given of the case where a B4 size binary image read by the resolution of a book is compressed by the above-described method using 16 dots × 16 dots as one unit and stored in a memory of 1 word = 16 bits. .

As shown in FIG. 4, the image 1 has 4064 dots × 2816 dots, which is 254 × 176 units. Therefore, as shown in FIG. 5, a map memory 2 of 254 × 176 words (1 memory unit = 1
Prepare). And in the maximum case-that is, the data memory when all units are not white, requires 715 kilowords (= AEA 00 hex).

As the pointer to the data memory stored in each unit memory of the map memory 2, it is appropriate to use the start address of the data memory in which the image data of the corresponding unit is stored.

However, 1 word = 16 bits is insufficient. Therefore, here, one unit of image data is 16 words (10 hex).
Considering that, as a pointer, To use.

In the example of FIG. 4, since the units A and D of the image 1 are all 0, the map memory 2 (the fifth
0 is stored in the areas A-1 and D-1 in the figure). Further, since the units B and C of the image 1 include image information, the information of each 16 dots × 16 dots is stored in the data memory 3 (FIG. 6) at the address 120 (hex) and 270.
Store from (hex) address.

Then, as shown in FIG. 5, the corresponding unit memories of the map memory 2 store the addresses 12 (hex) and 27 (hex) respectively representing the data storage areas.

Obviously, in this example, the map memory 2 has 254
Although it is constant at × 176 words, the size of the data memory 3 varies depending on the nature of the image.

In the above-mentioned method, information about whether all white (0) or not for a unit composed of M × N dots is stored in the map memory, but this is supplemented for a wider range (M ′ × N ′ unit). Information can also be added.

Examples of the auxiliary information include the following.

(1) Information indicating whether the units corresponding to one row of the map memory are all white (0) (Using this information, the reading speed can be increased.) (2) Included in one row of the map memory , The number of units that are not white (0) (the reading speed can be similarly increased.
In other words, if the same number of data is read in the same row, it is possible to immediately move to the next row. Also, using this, error checking is possible. Further, according to the present invention, it is possible to share the data memory among the units having the same image data.

By the way, with such a technique, an all-white unit cannot be treated in the same manner as a unit that does not, so that control of the image data storage device becomes complicated. The present invention also solves such a problem.

That is, according to the present invention, as shown in FIG. 6, an area 31 for storing image data of all white (all 0) is prepared in the data memory 3 for one unit and the unit is all white (all 0). In the case of (4), the area 31 in the data memory 3 is pointed from the map memory 2.

This has the advantage that all-white units can be treated exactly the same as non-white units.

As described above, in the present invention, the position on the image plane of each unit and the map memory correspond directly. Therefore, the unit memory position on the map memory representing the unit can be immediately known from the position on the image plane, and the image data of the unit can be quickly referred to through the pointer stored therein.

Further, since the storage position of the image data of each unit is not particularly limited, it is possible to share the data memory as long as the units have the same image data. As is apparent, such sharing of image data is possible between multiple units of one image and between multiple units of multiple images.

Further, the partial movement of the image can be performed only by moving the data on the map memory. Therefore, it is simpler and faster than the method of storing the image data as it is.

In addition, when the logical sum or logical product of binary images is obtained, it can be performed in unit. At this time, if the information on the map memory that one unit, that is, M × N dots are all 0, is utilized, these logical operations can be performed at higher speed. These operations can be performed on the same image as well as between the two images.

In the storage system of the present invention, after the image data of one sheet or N scanning lines is read and stored, the presence or absence of image information is discriminated for each unit in FIG. 1 and stored in the map memory and the data memory. However, the presence or absence of information belonging to each unit may be determined for each scanning line,
Storage in map memory and data memory can also be performed. The latter has the effect of reducing the buffer memory capacity.

As described above, in the present invention, an area for storing image data of one unit (M × N dots) of only a predetermined level (white data) is prepared in advance in the data memory. If the minute image data is data of a predetermined level only, the image data is not stored in the data memory, but the position where the image data for one unit is stored is stored in the map memory and stored. Should be 1
When the image data for a unit is not the data of a predetermined level, the image data is stored in the data memory and the storage location is stored in the map memory. )
The capacity of can be greatly reduced.

Further, at the time of storing the image data, the storage operation of the image data of the unit of only the predetermined level can be omitted, so that the storage operation of the image data is simplified as a whole. Further, since the image data can be handled in matrix units, the image data can be easily edited.

Furthermore, whether or not the image data to be stored is data of a predetermined level or not, since the position on the data memory is stored in the map memory, the data of all units are stored. It can be handled in exactly the same manner, and the control of the image data storage device can be further simplified.

[Brief description of drawings]

1 and 4 are schematic diagrams showing a state in which an image is divided into units, FIGS. 2 and 5 are schematic diagrams showing an example of a map memory, and FIGS. 3 and 6 are explanatory diagrams of a data memory. Is. 1 ... Image, 2 ... Map memory, 3 ... Data memory, A ...
D ... Unit, A-1, B-1 to D-1 ... Unit memory

Claims (1)

[Claims] 1. An image data storage device for storing arbitrary two-dimensional image data, which is associated with each unit of arbitrary two-dimensional image data divided into a large number of units of a matrix of M × N dots. A map memory including a unit memory, and a data memory for storing image data of the unit and storing image data of only one unit at a predetermined level at a known position, which should be stored arbitrarily. When the image data of the unit is not only data of a predetermined level, the image data of the unit is stored in the data memory, and information indicating the storage position in the unit memory of the map memory corresponding to the unit. Is stored and the image data of any unit to be stored is only data of a predetermined level, Of Ppumemori, the unit memory corresponding to the unit, the image data storage device, wherein the information indicating the known position is stored.