JPH06291987A - Picture output device - Google Patents

Abstract

PURPOSE:To provide a picture output device in which processing time is considerably reduced with less memory capacity, deterioration in picture quality of image data is suppressed and a picture output with high picture quality is obtained. CONSTITUTION:When a magnification detection circuit 103 detects it that resolution of inputted compression image data exceeds resolution of a printer engine 116, an expansion circuit 105 expands it and a resolution conversion circuit 107 converts the resolution and then a compression circuit 109 applies compression processing to the data and the result is stored in a memory 112. On the other hand, when the resolution of the inputted compression image data is coincident with the resolution of the printer engine 116, no compression expansion processing is executed and the data are stored directly to the memory 112. Then the data read from the memory 112 are expanded by an expansion circuit 114 and printed out from the printer engine 116.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image output apparatus, for example, a means for storing image information in which text data such as characters and line drawings and image data such as photographs are stored, and resolution conversion of the image data. The present invention relates to an image output device having means for

[0002]

2. Description of the Related Art Image data such as photographs are transferred to JPEG (Joi
When input from the host computer after being compressed by encoding such as nt Photographic Expert Group), conventionally, each process is performed after once decoding and restoring the original image data. FIG. 3 is a block diagram of a conventional image processing system.

From the input terminal 301, text data such as characters and line drawings and the compressed image data are input. The image detection circuit 302 distinguishes the text data from the image data, and switches the switch 304 to the terminal a side for text data and to the terminal b side for image data. When text data (character code or the like) is input, it is expanded by the rasterizer 306 and input to the compression circuit 308. The compression circuit 308 compresses the data input from the rasterizer 306 by a known encoding method such as run length encoding, which is suitable for encoding text data, and stores the compressed data in the memory a 310.

On the other hand, when image data is input, if the image data is compressed data such as JPEG, it is expanded by the expansion circuit 305 and output to the reduction / enlargement circuit 307. When the resolution of the image data is different from the resolution of the printer engine 315, the reduction / enlargement circuit 307 reduces or enlarges the image data to the magnification detected by the magnification detection circuit 303. That is, when the resolution of the image data exceeds the resolution of the printer engine, the image data is reduced, and when the resolution of the image data is smaller than the resolution of the printer engine, the image data is enlarged.

The image data reduced or enlarged is
An encoding method suitable for image data compression in the compression circuit 309, for example, DCT (Discrete Cosine Transfor)
m) or the like, or compressed by a known encoding method such as block encoding, and stored in the memory b311. Next, when the printer engine 315 is started, the text data stored in the memory a 310 and the memory b are stored.
The image data stored in 311 is output to the expansion circuits 312 and 313, respectively. Expansion circuit 312,
313 returns the text data and the image data to the data before being compressed by the compression circuits 308 and 309,
Output to the synthesis circuit 314. The synthesizing circuit 314 synthesizes the text data and the image data and outputs the synthesized data to the printer engine 315.

[0006]

However, in the above conventional image output apparatus, the compressed input image data is once decoded and restored to the original image data, and then compressed and stored in the memory. . Therefore, there is a drawback that the processing takes a lot of time. In addition, there is a drawback that the image quality deteriorates due to repeated compression / expansion.

Further, when the resolution of the input image data is smaller than the resolution of the printer engine, the amount of data after the resolution conversion becomes large, and the use efficiency of the memory deteriorates.

[0008]

SUMMARY OF THE INVENTION The present invention has been made for the purpose of solving the above problems, and provides an image output apparatus capable of reducing the compression / expansion processing and effectively utilizing a memory. With the goal. The following configuration is provided as one means for achieving the above object and solving the above problem.

That is, the decompressing means for decompressing the input compressed data, the converting means for converting the resolution of the decompressed data in the expanding means, the compressing means for compressing the data whose resolution is converted by the converting means, and the compressing means. When the resolution of the storage means for storing data and the resolution of the input compressed data match the resolution of the connected image output means, the input compressed data is directly stored in the storage means, and the input compressed data is stored. Storage control means for storing the data compressed by the compression means in the storage means when the resolution does not match the resolution of the connected image output means.

Alternatively, decompression means for decompressing the compressed data, reduction means for reducing the resolution of the decompressed data in the decompression means, compression means for compressing the data whose resolution has been converted by the reduction means, and compressed data When the resolution of the input compressed data is less than or equal to the resolution of the connected image output means, the input compressed data is directly stored in the storage means, and the resolution of the input compressed data is stored. Storage control means for storing the data compressed by the compression means in the storage means when the resolution is not less than the resolution of the image output means connected to the storage means.

For example, when the resolution of the input compressed data exceeds the resolution of the image output means, the input compressed data is expanded by the expansion means and then reduced by the reduction means so as to match the resolution of the image output means. After that, the data is compressed by the compression means and stored in the storage means. For example, second decompression means for decompressing the data stored in the storage means,
And an enlarging means for enlarging the resolution of the decompressed data in the second decompressing means. When the resolution of the input compressed data is smaller than the resolution of the image output means, the data stored in the storage means is used as the second means. The image is expanded by the expansion means and expanded by the expansion means to match the resolution of the image output means.

[0012]

With the above configuration, it is possible to reduce the processing time and prevent the image quality from deteriorating, further reduce the number of pixels to be stored in the memory, and to provide the image output device in which the memory can be effectively utilized. It becomes possible.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment according to the present invention will be described in detail below with reference to the drawings. (Embodiment 1) FIG. 1 is a block diagram showing a first embodiment according to the present invention. In the figure, 101 is an input terminal, 102 is an image detection circuit, 103 is a magnification detection circuit, and 104 and 11.
0 is a signal switching switch, 105, 113 and 114 are decompression circuits, 106 is a rasterizer, 107 is a resolution conversion circuit, 108 and 109 are compression circuits, 111 and 112 are memories, 115 is a synthesis circuit, and 116 is a printer engine.

The print data in which the text data and the image data input from the input terminal 101 are mixed,
The image detection circuit 102 distinguishes between text data and image data. When the print data is text data, the image detection circuit 102 switches the switch 10.
4 to the terminal a side, switch 1 for image data
04 is switched to the terminal b side. Therefore, when the text data is input, the text data is expanded into a bit map by the rasterizer 106 via the terminal a of the switch 104 and output to the compression circuit 108.

The compression circuit 108 compresses the text data by a known encoding method suitable for encoding the text data such as run length encoding. The compressed text data is stored in the memory a111. On the other hand, when the image data is input, the image detection circuit 102 switches the switch 104 to the terminal b side and inputs the image data to the switch 110 and the expansion circuit 105. Further, the resolution of the image data is set in the magnification detection circuit 103. Since the magnification detection circuit 103 matches the input image data with the resolution of the printer engine, the magnification of the image data is detected from the resolution of the image data. When the resolution of the image data matches the resolution of the printer engine, the switch 110 is connected to the terminal. Switch to a side,
The compressed image data is stored in the memory b112 as it is.

On the other hand, when the resolution of the image data and the resolution of the printer engine are different, the switch 110 is switched to the terminal b side to expand the image data.
Is expanded, and the resolution conversion circuit 107 converts the resolution of the image data to the resolution of the printer engine (converts at the magnification input from the magnification detection circuit 103), and the resolution-converted image data is compressed. J at 109
The image data is compressed by an encoding method suitable for compressing image data such as PEG and stored in the memory b112.

Next, when the printer engine 116 is activated, the text data and the image data stored in the memory a111 and the memory b112 are respectively decompressed by the decompression circuit 1.
13 and 114 restore the original data, and the synthesizing circuit 11
5, and is output to the printer engine 116. As described above, according to the present embodiment, when the resolution of the compressed input image data matches the resolution of the printer engine 116, decompression / compression processing is not performed,
The compression circuit 108 stores the data directly in the memory.
109 are memories 111 and 11 for storing image data
The expansion circuit 113, 114 is provided in the front stage of the memory 2
If the resolution of the input image data exceeds the resolution of the printer engine 116, it is provided in the latter stage of 1, 112.
In the resolution conversion processing, the image data is stored in the memories 111, 1
If the resolution of the input image data is smaller than the resolution of the printer engine 116, the resolution conversion process is performed after the image data is stored in the memories 111 and 112, thereby reducing the processing time. The number of pixels stored in the memory can be reduced, and the memory can be effectively used.

(Embodiment 2) FIG. 2 is a block diagram showing a second embodiment according to the present invention. In the figure, 201 is a reduction circuit, 202 is an enlargement circuit, and other configurations are shown in FIG.
The second embodiment has the same configuration as that of the first embodiment shown in FIG. When the compressed image data is input from the input terminal 101, the image detection circuit 102
Switches the switch 104 to the terminal b side and sets the resolution of the image data in the magnification detection circuit 103. When the resolution of the image data is lower than the resolution of the printer engine, the magnification detection circuit 103 switches the switch 110 to the terminal a side and stores the compressed image data in the memory b112 as it is.

On the other hand, when the resolution of the image data exceeds the resolution of the printer engine, the switch 110 is switched to the terminal b side to expand the image data by the expansion circuit 105.
The image data is decompressed, and the reduction circuit 201 converts the resolution of the image data into the resolution of the printer engine (converted by the magnification input from the magnification detection circuit 103). The image data is compressed by an encoding method suitable for compressing image data such as JPEG and stored in the memory b112. The text data is the same as that in the first embodiment, and therefore its explanation is omitted.

Next, when the printer engine 116 is activated, the text data and the image data stored in the memory a111 and the memory b112 are respectively decompressed by the decompression circuit 1.
The original data is restored by 13, 114. When the resolution of the expanded image data is smaller than the resolution of the printer engine, the enlargement circuit 202 enlarges the image data to the magnification detected by the magnification detection circuit 103 in order to match the resolutions of the image data and the printer engine, and the composition circuit 115.
Then, it is combined with the text data expanded by the expansion circuit 113 and output to the printer engine 116. On the other hand, when the resolution of the decompressed image data is equal to or higher than the resolution of the printer engine, the enlarging circuit 202 goes through and does nothing.

An object of the present invention is to provide an image output apparatus having the above-mentioned configuration, which is configured to effectively use the memory in which the number of pixels stored in the memory is minimum.
The present invention may be applied to a system including a plurality of devices or an apparatus including a single device.
Further, it goes without saying that the present invention is also applied to the case where it is achieved by supplying a program to a system or an apparatus.

As described above, according to each embodiment, when the resolution of the compressed input image data matches the resolution of the printer engine, the compression / decompression processing is not performed, but the data is directly stored in the memory. The processing time can be significantly reduced and the deterioration of the image quality of the image data can be suppressed, high quality image output can be obtained, and when the resolution of the image data exceeds the resolution of the printer engine, the image data is stored in the memory. Shrink before doing
When the resolution of the image data is smaller than the resolution of the printer engine, the image data is stored in the memory and then the enlargement process is performed to store the image data in the memory b112.
Since the number of pixels stored in is minimum, the memory can be effectively used.

[0023]

As described above, according to the present invention, it is possible to significantly reduce the processing time, suppress the deterioration of the image quality of image data, and obtain a high quality image output.
Furthermore, even when the resolution of the image data exceeds the resolution of the printer engine, a high-quality image output can be obtained with a small memory capacity.

[Brief description of drawings]

FIG. 1 is a block diagram showing an image output device of a first embodiment according to the present invention.

FIG. 2 is a block diagram showing an image output device of a second embodiment according to the present invention.

FIG. 3 is a block diagram showing a conventional image output device.

[Explanation of symbols]

 101 Input Terminal 102 Image Detection Circuit 103 Magnification Detection Circuit 104, 110 Signal Switching Switch 105, 113, 114 Expansion Circuit 106 Rasterizer 107 Resolution Conversion Circuit 108, 109 Compression Circuit 110 Mode Switching Switch 111, 112 Memory 115 Compositing Circuit 116 Printer Engine 201 Reduction circuit 202 Enlargement circuit

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Claims (4)

[Claims] 1. Decompression means for decompressing input compressed data, conversion means for converting the resolution of the decompression data in the decompression means, compression means for compressing the data whose resolution has been converted by the conversion means, and compression. When the resolution of the storage means for storing data and the resolution of the input compressed data matches the resolution of the connected image output means, the input compressed data is directly stored in the storage means, and the input compressed data is stored. And a storage control unit for storing the data compressed by the compression unit in the storage unit when the resolution does not match the resolution of the connected image output unit. 2. Decompression means for decompressing the compressed data, reduction means for reducing the resolution of the decompression data in the decompression means, compression means for compressing the data whose resolution has been converted by the reduction means, and compressed data. And a resolution of the input compressed data that is directly stored in the storage means when the resolution of the input compressed data is less than or equal to the resolution of the connected image output means. And a storage control unit that stores the data compressed by the compression unit in the storage unit when the resolution is not lower than the resolution of the image output unit connected to the image output apparatus. 3. When the resolution of the input compressed data exceeds the resolution of the image output means, the input compressed data is expanded by the expansion means and then reduced by the reduction means so as to match the resolution of the image output means. 3. The image output device according to claim 2, wherein the image output device compresses the image data later by the compression device and stores it in the storage device. 4. A second decompression means for decompressing the data stored in the storage means, and an enlarging means for enlarging the resolution of the decompressed data in the second decompression means. When the resolution is smaller than the resolution of the image output means, the data stored in the storage means is expanded by the second expansion means and expanded by the expansion means to match the resolution of the image output means. The image output device according to claim 2.