DE69631248T2 - Image forming apparatus - Google Patents

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an imaging device such as a printer and in particular an image-forming device for image data processing Splitting the image data into color components or partial images.

2. Description of the stand of the technique

Recently, the transmission image data through a network or when storing image data the image data is encoded and compressed in a memory in order to Reduce data volume.

There are various static coding systems Pictures. Among them is a JPEG (Joint Photografic Coding Experts Group) system is an influential coding system that uses a DCT (discrete Cosine transformation) used on an interframe correlation rests ("International Standard of Multimedia Coding "released von Maruzen K.K. 1991, pp. 14 to 47; and "DCT Coding System Using Adaptive Quantization" written in Treatise of Image Electronics Society 1991, Volume 20, No. 5, pp. 467 to 475).

To in an imaging device such as a color copier or a color printer, images from image data to print or output, encoded image data is decoded and decompressed, and then color images are placed on a recording medium printed.

There are so-called color printers Tandem system color printer to make color inks with the components yellow (Y), magenta (M), cyan (C) and black (K) on top of each other on a recording medium to print.

In this tandem system color printer are exclusively Recording elements for Color components provided. These recording elements can be relative pipeline-like to a recording medium to be transported operated to achieve a color printing throughput that is close is a single color print. For example, in the case of a Laser beam printer using an electrophotographic process the recording elements for Color components only arranged so that a recording medium at a process speed is transported, and draws the corresponding recording element Images with the inks with the appropriate color components the recording medium while the speed of the process is adjusted. Because the throughput of the Image recording depends on the speed of the process, can Tandem system color printer four colors with the same throughput as in the case of recording, only be recorded with black.

Accordingly, if the process speed made big the throughput of the color printer can be improved. It actually is however, it is very difficult to change the process speed out Establish, the mentioned below are.

For example, design parameters of the Processes (development process, transfer process and fixation process) that form the electrophotographic process, based on a certain process speed become. To make the process speed variable, you should all parameters of the affected processes are made variable. So it is real very difficult, all changed Adjust parameters.

In these circumstances, the process speed set constantly. In this way, white recording sheets are ejected or images that are disturbed in the middle are printed on the recording sheets, unless the image data is constant at the recording element Speed according to the speed of the process supplied become. Must accordingly the image data to the recording element at a constant speed supplied become. However, in the case where the image data is supplied, while they are encoded, the decoding process with the printing process the recording elements are matched.

Especially in the case where that Coding system is a reversible coding system, the decoding speed depends generally from an original. Therefore it changes the decoding speed with the image data, thereby ensuring a constant supply of image data to the recording elements fails.

In the case where the coding system is a reversible coding system, z. B. a code quantity control carried out, so as to get a constant amount of code per page and a decoding speed can be made constant. The smaller the code amount, the more is bigger generally in the case where an image is not reversibly encoded is the quality disorder. On hard-to-encode image (e.g. an image made up of random noise) has the property that the deterioration in the case where encoding is performed with the same amount of code, greater than with a normal picture (e.g. a picture or a natural picture) Picture like a landscape). Therefore, in the case where the code quantity control grows carried out to encode different images with a constant amount of code, the deterioration in quality according to the pictures, sometimes maintaining the lasting quality for the practical Use fails.

Accordingly, in a case where the image data is supplied in an encoded form when a ver is made to ensure the quality, it becomes difficult to make the decoding speed constant, which makes it difficult to supply the image data to the recording elements at a constant speed.

In the case where it's difficult To make the decoding speed constant, the decoded ones Image data temporarily held in a buffer memory, so that the image data from the buffer memory to the recording elements supplied become. This allows a feeder from image data to the recording elements at constant speed, so that white paper is not ejected or pictures with disturbed Middle part can be printed out.

14 shows a construction of a color printer of a tandem system, which with a buffer memory 101 as described above. In this color printer coded image data are stored in a magnetic disk device 12 held, which is an external memory, by a decoder 103 decoded and image data are temporarily retained in the buffer memory per page, and image data with color components are saved from the buffer memory 1 to the recording elements 104Y . 104M . 104C and 104K for the color components yellow, magenta, cyan and black. A control device 105 to control the decoding process by the decoder 103 controls the feeding of the recording sheets from a sheet dispenser 106 , Recording sheets are fed through a sheet transport device 107 to a printing position by the recording elements in synchronism with the supply of image data to the recording elements 104Y . 104 . 104C and 104K transported to wrap the recording sheets so that they pass through the recording elements 104Y . 104M . 104C and 104K go through, recording the images with color inks on top of each other.

In the tandem system color printer as described, the recording sheets are pipelined to increase throughput. If the recording sheets are not continuously through the recording elements 104Y . 104M . 104C and 104 the throughput is reduced with the appropriate colors.

Therefore, in the case where a plurality of the same originals are continuously printed, the recording sheets can be piped continuously at the time when the image data for one page is ready. That means like in 15 shown that the control device 105 Decoding instructions to the decoder 103 gives (step S1) and receives a message that the image data for one page has been decoded and is retained in the buffer memory (step S2). Then the control device gives 5 Sheet feed instructions to the sheet dispenser 106 (Step S3) to the donor 106 to cause transport of the recording sheets to begin. When a predetermined number of recording sheets are transported and the same kind of originals are stored in the buffer memory 101 be held back by the transducers 104Y . 104M . 104C respectively. 104K processing is complete (step S4). In the case where a variety of different types of images are printed, e.g. B. buffer memory 101 in the number of types of images provided, and when all the image data is ready for the buffer 101 the recording sheets can be fed continuously into the pipeline.

However, if all image data of different types are to be prepared, there is an enormous capacity of buffer memory 101 what is lacking in reality in terms of cost and performance. For example, if the buffer memory 101 is formed from relatively expensive semiconductor memory, a larger part of the printer costs is covered by the memory costs. Alternatively, if the buffer memory 101 formed by a relatively inexpensive magnetic disk, a plurality of magnetic disks should be operated in parallel, since the data transfer speed of the magnetic disk is much lower compared to the recording speed, and as a result, a larger part of the printer cost is covered by the cost of the magnetic disks are required.

To print a variety of images of different types, while the cost of the buffer memory 101 are required to be kept low, the operation of preparing the image data for one page for the buffer memory 101 and continuously feeding the recording sheets in the number required for recording the images are repeated for the kinds of the image data.

That means like in 16 it is shown that the control device 105 There are decoding instructions that are the first page for the decoder 103 (Step S11) concerns and receives a message that image data for one page has been decoded and in the buffer memory 101 retained (step S12). Then the control device gives 105 Sheet feed instructions to the sheet dispenser 106 (Step S13) to the donor 106 to cause transport of the recording sheets to begin. When a predetermined number of recording sheets are transported and the images stored in the buffer memory 101 retained by the recording elements 104Y . 104M . 104C respectively. 104K are recorded (step 14), the control unit returns 105 Decoding instructions, which is the next page for the decoder 103 concern (step S11), and the operations (steps S12 to S14) similar to the above are repeated.

However, in the case where, as described above, image data for one page for the buffer memory 101 be prepared where the recording is completed regarding the necessary page and where the next page is then decoded and stored in the buffer memory 101 is held back, the throughput drops sharply and the applicability becomes very low.

In view of the foregoing, a recording method was used in which there was enough buffer memory 101 in order to retain image data for all pages is not required and where the reduction in throughput is pushed to an allowed level. That is, the decoding process for each page is performed at different times, so that after image data for a previous page that is retained in the buffer memory is partially output, image data for the next page in the buffer memory 101 retained, thereby reducing the amount of data stored in the buffer memory 101 is retained, reduced, and data for a plurality of pages in the buffer memory 101 be held back to approximate the time lapse by being able to begin recording the next page relative to the previous page to avoid reducing throughput.

For example, the record elements decode 104Y . 104M . 104C and 104K Pages of different images required for recording at different times and the images are taken sheet by sheet. The processing is then as in 17 shown performed. In the figure, the abscissa shows the time. Under the timing chart, for each processed page of the recording sheet, a buffer memory capacity is shown which is required at the time in memory capacity (one level) for one page and one color.

First, when processing the first page, image data (for four levels) with four color components yellow (Y), magenta (M), cyan (C) and black (K) are decoded and stored in the buffer memory 101 retained. Then sheets are transported to the leading position of the row of recording elements, and thereafter the recording sheets are between the recording elements 104Y . 104M . 104C and 104K transported. Recordings are carried out successively on the basis of image data of the color components. As a result, after six time units, images for the first page are superimposed on the recording sheets with color inks, and a data retention capacity of the buffer memory 101 "0" is blank for the first page.

For this purpose, the second side is processed in parallel under a state delayed by a unit of time and the third side is processed in parallel under a state delayed by one unit of time. This way the buffer memory 101 The capacity required each time a level recording is completed is reduced by "1" and the corresponding pages are processed in parallel.

That is, in the example described above, if the pipeline is filled after six time units from the start of printing and if the buffer memory 101 storage capacity for a maximum of 18 levels, various images can be recorded on the recording sheets that are continuously loaded.

In the case of the tandem type color printer as described above, data for a plurality of pages is stored in the buffer memory 101 retained, thereby allowing recording sheets to be fed continuously to perform the recording operation while preventing the throughput from decreasing.

These situations are also for the single color Printer valid. In order to supply image data to the recording elements, so in time with the recording process to be, it is necessary that even in the case of the record a kind of images minimally image data for a page temporarily in the Buffer memory held back and the image data are transferred from the buffer memory to the recording elements fed.

In the case where images are different Species on the record sheets, the constantly be fed be recorded, it is necessary to keep image data for minimal Temporarily hold two pages in the buffer to continue feed the data from different image pages as described.

In the tandem type color printer as described above, in the case where the process speed is constant and where the feeding speed of the image data cannot be ensured, buffer memory is necessary 101 to provide, for which the reading speed is ensured. Particularly in the case where a plurality of images of different kinds are printed even when recording sheets are fed into the pipeline intermittently, a buffer memory for the depth of the pipeline is necessary. In the example of 17 a buffer memory for 18 levels is necessary.

If the buffer memory 101 consists of a semiconductor memory whose data access speed is high, in the case of image data with the resolution of the JIS A4 format 400 (dot / 25.4 mm) and a gradation accuracy of each pixel of 8, a data amount for a quantity of 60 (MByte). Therefore, a large storage capacity of approximately 288 (MByte) in total for 18 levels is necessary, which results in a considerable increase in printer costs.

Furthermore, even in a single color printer, a total storage capacity of approximately 32 "Mbytes" for two pages is minimally required in order to continuously print data for different types of image pages, which results in a considerable increase of printer costs caused by storage costs.

EP-A-0427466 relates to a control system for a Multi-color computer graphics plotter that turns the plot into a variety of bands divides and approximates calculated the time it takes to get each picture into each Draw the tape in the required color (see generic term of claim 1).

SUMMARY THE INVENTION

The present invention has been made in view of this the facts above regarding the state of the art mentioned has been. It is an object of the present invention to provide an imaging Provide device to further a storage capacity to reduce the necessary for temporary caching of image data is.

The task is accomplished through a An imaging device as defined in claim 1. preferred embodiments are in the dependent claims Are defined.

According to the present invention will be image data for an image into a variety of elements such as color components or Fields are divided and these data elements become temporary in a memory such as a buffer memory with respect to the recording medium retained. The timing is adjusted to the time at which the data element in the Memory held back to the recording medium such as recording sheets the recording medium and to transport the images that based on the data element to record on the recording medium.

According to an imaging device Data processes like a decoding process by a data processing means, Data supply process, Reception process, color correction process and intensification process carried out, in the image data for an image can be divided into a variety of elements and the Data of these elements in a buffer with respect to the recording medium retained become. A control means initiates upon completion of the data process the means of transport the transport of the recording medium to start and causes the recording medium to start recording of the data element that is retained in the cache will carry out wherein images are recorded on the recording medium in the state in which the transport of the recording medium and the supply of the data to match the recording medium.

Furthermore, according to the present invention the imaging device is a so-called tandem type color printer, that with a variety of recording media to overlap Printing picture elements of each color component on a recording medium Is provided. The decoding process is done by a decoding means by dividing the image data for performed an image of each color component and the data of those color components are retained in the buffer. The device also includes estimation tools for Estimate the completion time for all color component data by the decoder. On the base the estimate the control means the means of transport causes the transport of the recording medium starts and causes the recording medium the recording process of the color component data stored in the buffer retained are going to perform. This means, in the case where recording sheets fed into the pipeline by the controller with an interruption based on the above estimate in the tandem type color printer, become the recording sheets fed into the pipeline only when an estimate has been made so that the image data in the buffer are prepared at the time if the recording sheets arrive at the recording medium, and if the estimate so fails, that the preparation of the image data is not synchronized, the Not recording sheets fed and the feed the data on the recording medium and the recording process is synchronized by the recording medium.

This is the recording process not started by the recording medium after the image data for a Image held in the clipboard were, but when the color component data in the buffer be held back the recording process becomes based on the color component data quickly started by the appropriate recording medium. Corresponding is the amount of data that is in the cache until the recording process completed is held back should be reduced in a short time and the buffering capacity required for the supply of the Data required for the recording medium is reduced compared to the prior art.

The estimate for the completion time of the Decoding process by the estimation means is performed based on the processing speed if Data is encoded, or is based on the amount of code Color component data, the number of encoded symbols or the time, the required for the color component data is decoded.

Furthermore, in the image forming apparatus according to the present invention, image data for an image is divided by an image dividing means in parallel to a main scanning line, and the obtained data of the partial picture elements are stored in the image memory. On the basis of the control, the feeding means causes the intermediate storage with respect to the recording means the partial image data stored in the image storage are to be withheld and the printing process is carried out by the recording medium.

By mapping the image data for an image The sub-picture data, as described above, becomes the capacity required for the buffer is required, reduced, and the cost of the cache are reduced.

If a variety of recording media for the Printing for all color component data can be provided, the Images are subjected to the recording process in the state in which the partial image data is further divided into color component data were.

SHORT DESCRIPTION THE DRAWINGS

1 Fig. 11 is a schematic view showing the construction of an image forming apparatus according to an embodiment of the present invention;

2 Fig. 11 is a schematic view showing the construction of a tandem type color printer which is the image forming apparatus according to an embodiment of the present invention;

3 Fig. 12 is a schematic view showing an example of the construction of the decoding speed estimation means;

4 Fig. 12 is a graph showing an example of a relationship between the encoding time and the decoding time;

5 Fig. 12 is a graph showing an example of a relationship between the code amount and the decoding time;

6 Fig. 12 is a graph showing an example of a relationship between the number of symbols encoded and the decoding time;

7 FIG. 4 shows the operational timing of an image forming device according to an embodiment of the present invention;

8th FIG. 4 shows the operational timing of an image forming device according to an embodiment of the present invention;

9 Fig. 11 is a schematic view showing the construction of an image forming apparatus according to another embodiment of the present invention;

10 Fig. 11 is a schematic view showing the construction of an image forming apparatus according to another embodiment of the present invention;

11 is a conceptual diagram for explaining the division of the image data;

12 FIG. 4 shows the operational timing of an image forming device according to another embodiment of the present invention;

13 Fig. 11 is a schematic view showing the construction of an image forming apparatus according to still another embodiment of the present invention;

14 Fig. 11 is a schematic view showing the construction of a conventional image forming apparatus;

15 Fig. 14 is a flowchart showing the process flow in the conventional image forming apparatus;

16 Fig. 14 is a flowchart showing the process flow in the conventional image forming apparatus; and

17 shows the timing of operation of a conventional imaging device.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The image forming apparatus according to the present invention is hereinafter exemplified by a tandem type color printer with reference to FIG 1 to 8th described.

As in 1 shown, the tandem type color printer according to the present invention comprises coding means 1 , Memory for encoded data 2 , Decoding means 3 , Decoding speed estimation means 4 , Cache 5 , Control 6 , four recording media 7Y . 7M . 7C and 7K , and sheet transport 8th ,

The coding medium 1 encodes image data according to the encoding instructions from the controller 6 and stores the encoded data in the encoded data memory 2 , In addition there is the coding means 1 encoded information regarding decoding of image data into the decoding speed estimation means 4 to estimate the completion time of the decoding process as described later.

The memory for encoded data 2 includes a storage device such as a magnetic disk device that stores encoded data in a readable and writable manner.

The decoder 3 reads and decodes the encoded data from the encoded data memory according to the decoding instructions from the control means 6 and the obtained image data is stored in the buffer 5 retained.

The decoding speed estimator 4 estimates the decoding speed of the decoding means 3 based on the coded information, the estimated result being preserved therein, and the estimated result being in the control means 6 entered according to the estimation request. The details of the process by the decoding speed estimation means 4 will later refer to the 3 to 6 described.

The cache 5 comprises a buffer memory, which is formed from a semiconductor memory, the image data in the recording means 7Y . 7M . 7C and 7K caches.

The means of control 6 conveys the coding instructions to the coding means 1 to start encoding the image data passes an estimation request to the decoding speed estimating means 4 to get the estimated result regarding the Obtain decoding speed, and conveys the decoding instructions to the decoding means 3 to start decoding the encoded data. The means of control 6 determines whether or not the decoding process is complete until the recording sheets are at the printing start position of the recording means 7Y . 7M . 7C and 7K arrive based on the estimated result received. If the determination was made in time, the control means indicates 6 the leaf transport 8th to transport the leaves.

The recording elements 7Y . 7M . 7C and 7K correspond to the color component data yellow (Y), magenta (M), cyan (C) and black (K), respectively, and perform an overlapping recording process on the recording sheets which are transported with the color inks. That is, the recording media 7Y . 7M . 7C and 7K read image data with the color components stored in the buffer 5 be held back and if the sheets by the sheet transport 8th are transported, the recording medium 7Y . 7M . 7C and 7K pass through, images are recorded on the sheets with color inks superimposed based on the image data.

The leaf transport 8th starts the transport of the recording sheets based on the sheet feeding instructions from the control means 6 to move the sheets to the recorders one after the other 7Y . 7M . 7C and 7K to transport and eject the sheets on which the images are recorded with color inks superimposed.

According to the tandem type color printer, constructed as described above becomes a color image on a Recording sheet printed using the following procedure.

First, if the control means 6 Coding instructions to the coding means 1 mediates, encodes the coding means 1 Image data according to the encoding instructions stores the encoded data in the encoded data memory 2 and puts the encoded information into the decoding speed estimation means 4 on. Then the decoding speed estimation means estimates 4 the decoding speed of the decoding means 3 from the coded information, preserves the estimated result therein and puts the estimated result in the control means 6 according to the estimation requirement of the control means 6 on.

Upon receipt of the estimated result from the decoding speed estimation means 4 conveys the means of control 6 the decoding instructions to the decoder 3 and determines whether or not the decoding process is complete until the recording sheets on the recording means 7Y . 7M . 7C and 7K arrive based on the estimated result received. If it is determined that the operations are in time, the control means points 6 the leaf transport 8th to feed leaves. If not, the control means waits until the right time based on the estimated result and then passes on the sheet feeding instructions.

In parallel with the method described above, the decoding means reads and decodes 3 the encoded data 14 from the encoded data memory 2 according to the decoding instructions to the decoded image data in the buffer 5 withhold so that the data immediately from the recording media 7Y . 7M . 7C and 7K can be printed.

If the corresponding image data of the color components in the buffer 5 are retained, the recording medium reads 7Y . 7M . 7C and 7K the data and the sheet transport 8th starts transporting the recording sheets according to the sheet feeding instructions. When the recording sheets being transported through the recording medium 7Y . 7M . 7C and 7K passing through, the images are recorded on the recording sheets with color inks based on the image data of each color component one above the other. Then the sheet transport device drives 8th continues to transport the recording sheets and outputs the recording sheets on which the color images are recorded.

More specifically, the tandem type color printer constructed as described above can be in the form of a so-called tandem type color laser printer as shown in 2 shown, realized.

In this device, toner images of each color component are produced by four recording means 7Y . 7M . 7C and 7K corresponding to yellow (Y), magenta (M), cyan (C) and black (K), respectively, and the toner images thus formed are sequentially transferred to the recording sheets which are conveyed by the transfer belt type sheet conveying device to form color images.

The recording media 7Y . 7M . 7C and 7K each include a loading device 11 , a laser scanning unit 12 , a developer device 13 and a cleaning device 14 that around a photosensitive drum 10 are arranged. The toner images for each color component are on the photosensitive drum 10 through the steps of charging, exposing and developing, wherein the toner images are electrostatically transferred to the recording sheets that are on the sheet transport device 8th be worn.

The sheet transport device 8th is designed to span a transfer conveyor belt over a variety of rollers including a drive roller. In the vicinity of the transfer conveyor belt are a loading device 15 to electrostatically adsorb a recording sheet carried by a supply tray (not shown) on the surface of the tape, a transfer corotron 16 for electrostatically transferring a toner image from each of the recording media 7Y . 7M . 7C and 7K a discharge is generated on the recording sheet corotron 17 to discharge the recording sheet electrostatically adsorbed on the tape and a discharge corotron 18 to unload the tape after stripping the recording sheet.

Accordingly, when the recording sheet is transported while it is on the transfer conveyor 8th is adsorbed, image data for each color component from the buffer 5 to a laser scanning unit 12 of any recording medium 7Y . 7M . 7C and 7K is supplied and a toner image for each color component is placed on the photosensitive drum 10 in each of the recording media 7Y . 7M . 7C and 7K generated. These toner images are successively transferred to the recording sheets being transported, and a color image on which the toner images for each color component are superimposed is formed on the recording sheet. After that, the recording sheet that is transferred from the transfer belt 8th was stripped into a delivery tray (not shown) via a fuser 19 output.

3 shows the detailed construction of the decoding speed estimating means 4 which is a coding unit 1 a JPEG system used as a coding means. In the estimator 4 becomes a decoding speed from a coding speed by the coding unit 1 estimated.

The JPEG coding unit 1 captures image data, the image data for each color component (ie, each level) is encoded for one page, and the encoded data becomes the memory 2 output for encoded data. When the coding for one level is complete, the JPEG coding unit returns 1 as encoded information, the encoding time required for the encoding process of the image data for one level to the decoding speed estimation means.

The decoding speed estimator 4 includes a mapping table 21 between the encoding time and the decoding time and a table 22 for temporarily storing the estimated result of the decoding time. The mapping table 21 describes the assignment information between the coding time and the decoding time as in 4 is shown. When the coding time is input, the decoding time corresponding to it is retained in the table 22.

Table 22 outputs the decoding time as an estimated result 18 according to the estimation requirements from the control means 6 is withheld, and the control agent 6 then gives the sheet feed instructions to the sheet transport 8th based on the estimated result. From the relationship that is in 4 it is shown that the longer the coding time, the more the decoding time is delayed, and the start timing for the sheet transport by the sheet transport means 8th is delayed.

For example, in the JPEG system of the ITU-T standard, the coding process consists of a number of processes such as blocking, discrete cosine transformation, quantization and Hafman coding. Conversely, the decoding process is composed of a number of processes such as Hafman coding, inverse quantization, inverse discrete cosine transformation and reverse blocking, the coding process and the decoding process being opposed to one another. In the case where the decoding process is determined when the coding process is determined, the decoding speed can be detected in advance from the coding speed. The relationship between them is shown in advance in the assignment table 21 is set so that the predicted time (speed) is estimated when the decoding process is completed from the time (speed) required for the current coding.

Even in the case of the general Encoding system that is not a JPEG system, e.g. B. the system in which the coding process is in contrast to the decoding process, how in predicted coding, reforming coding, block approximation coding and arithmetic coding, the decoding speed can be estimated from the coding speed in a similar manner as before.

5 shows another example to estimate the decoding time. The decoding time is estimated based on the amount of code in the coding process.

Accordingly, in the case of this example, the relationship between the code amount and the decoding speed is detected in advance and in the assignment table 21 described, and the coding unit 1 gives the amount of code as encoded information to the decoding speed estimation means 4 out. If the code amount from the coding unit 1 is entered, the decoding time will be according to the code amount based on the assignment table 21 retained in table 22, and the decoding time retained in table 22 is taken as the estimated result 18 to the control means 6 issued according to the estimation request. That is, from the relationship that is in 5 it is shown that the larger the code amount, the more the decoding time is delayed and the timing for starting the transport of the sheets by the sheet transport means 8th is delayed.

In particular in the Hafman decoding process from the decoding system of the JPEG system, the arithmetic part of the process changes depending on the image data content. The more objects to be processed (ie the larger the code set), the larger the arithmetic part. Accordingly, the processing speed of the Hafman decoding process can be estimated from the code set. In the case where the Arithmetic part of the decoding process is determined, if the code amount is determined, the decoding speed can be estimated from the code amount.

Even in the case of the general Encoding system that is not a JPEG system, e.g. B. the system in which the arithmetic part of the decoding process depending is determined by the amount of code, such as predicted coding, transform coding, Vector quantization, subband coding, block approximation coding and arithmetic Coding, the decoding speed can be from the coding speed on similar Way as previously estimated become.

6 shows another example to estimate the decoding time. The decoding time is estimated based on the number of symbols encoded in the encoding process.

Accordingly, in the case of this example, the relationship between the number of encoded symbols and the decoding speed is detected in advance and described in the corresponding table 21. The coding unit 1 gives the number of encoded symbols as encoded information to the decoding speed estimating means 4 out. If the number of encoded symbols from the coding unit 1 is entered, the decoding time corresponding to the number of encoded symbols is held in the table 22 based on the corresponding table 21, and the decoding time held in the table 22 is taken as the estimated result 18 to the control means 6 according to the estimation request from the control means 6 output. That is, the larger the number of the coded symbols, the more the decoding time is delayed and the timing for the start of the transport of the sheets by the sheet transport means 8th is delayed.

Especially in the Hafman decoding process from the decoding system of the JPEG system z. B. a code word is successively removed from the encoded data, and an encoded symbol corresponding to the code word is output. Therefore, the arithmetic amount is larger the more objects (i.e. coded symbols) of the process. Accordingly, the process speed of the Hafmann decoding can be estimated from the number of encoded symbols. That is, in the Case where the arithmetic amount of the decoding process is determined if the number of encoded symbols is determined, the decoding speed can can be estimated from the number of encoded symbols.

Even in the case of the general Encoding system that is not a JPEG system, e.g. B. the system in which the arithmetic amount of the decoding process depending the number of symbols encoded, such as predicted encoding, Transform coding, vector quantization, subband coding and block approximation coding is determined, the decoding speed can be determined from the number of encoded symbols on similar Way as previously estimated become.

As described above, the time when image data of each color component in the buffer 5 by the decoding speed estimation means 4 be prepared, predicted, and the timing of feeding the image data to the feeding means 7Y . 7M . 7C and 7K is adapted to the transport timing of the recording sheets. Then, various types of images on the recording sheets that are fed continuously without interference from the timing as shown in FIG 7 shown, recorded.

The example that in 7 is shown is the case where the recording medium 7Y . 7M . 7C and 7K decode each page of different images at different intervals required for the recording process to record the images sheet by sheet, similar to the example shown in FIG 17 is shown. In 7 the abscissa denotes the time axis. The required buffer memory 5 Capacity is shown with the storage capacity (one level) for one page and a color below the timeline for the recording sheets for one page.

In the process for the first page, the means of control mediates 6 the sheet feed instructions to the sheet transport 8th to move the recording sheet to a printing start position of the leading recording medium 7Y to transport and convey the decoding instructions to the decoding means 3 to decode yellow (Y) image data (for one level) and the yellow (Y) image data in the buffer memory 5 withhold. The recording medium 7Y records a yellow ink image on the recording sheet based on the yellow (Y) image data and the control agent 6 conveys the decoding instructions to the decoding means 3 to decode image data (for one level) for the next color magenta (M). This image data of the next color magenta (M) is stored in the buffer 5 retained.

Next draw the recording medium 7M Magenta ink images on top of the recording sheet based on the image data for magenta (M) and the control agent 6 passes the decoding instructions to the decoding means 3 to decode the image data (for one level) of the next color cyan (C). This image data for cyan (C) is stored in the buffer memory 5 retained.

Next draw the recording medium 7C Cyan ink images on top of the recording sheet based on the image data for cyan (C) and the control agent 6 passes the decoding instructions to the decoding means 3 to decode image data (for one level) for the next color black (K). This black (K) image data is stored in the buffer memory 5 retained. Next draw the recording medium 7K Black ink images on the recording sheet above based on the image data for black (K).

As a result, after five time units a color image, one on top of the other recorded with the colors yellow (Y), magenta (M), cyan (C) and black (B) was printed on a recording sheet and by the device output.

The sheet transport is of the conveyor belt type. Since subsequent recording sheets are transported to the second page, the recording sheet for the first page passes through the recording means in succession 7Y . 7M . 7C and 7K to undergo the recording process described above.

For the second page and subsequent pages, a procedure similar to that of the first page is performed with a timing delayed by one unit of time to the previous page. The required capacity of the buffer memory 5 is reduced by "1" each time the recording process for one level is completed and pages are printed one after the other.

As a result, the pipeline is filled after four time units from the start of printing. However, the data for each color component is decoded and stored in the buffer memory 5 retained and the data of each color component stored in the buffer 5 withheld, are issued immediately. Therefore, if the buffer memory 5 has a maximum storage capacity for five levels, various images can be recorded on each of the recording sheets that are continuously fed. Accordingly, the required buffer memory capacity for 18 levels can be compared to the conventional device shown in eight levels 17 is shown to be reduced.

Even in the case where a situation arises in the above-described method in which more than one time unit is required for the decoding process of color data because the quality of the codes is higher than that of others, the time for completing the Coding can be estimated since the data for each color component is decoded and recorded. In the case where such an estimated result is obtained, the control means can 6 the timing for the sheet feeding instructions is delayed to delay the sheet feeding process until after the process related to the color data, the feeding of the data to the recording means being adapted to the transportation timing of the recording sheets to print a color image with no difficulty.

8th shows the case where in the decoding process for the fifth page two time units are required for decoding yellow (Y) and cyan (C). The transport timing of the recording sheets after the fifth page is delayed by a unit of time in order to synchronize it with the feeding timing of the data to the recording means.

9 Figure 11 shows another example in which the imaging device of the present invention embodies a tandem type color printer.

The present example differs themselves in the estimate the decoding time from the previous example. The following explanation will be the parts that are the same as the previous example, by the same Reference numerals and a duplicate description is omitted.

That is, the decoding speed is decoded information from the decoding means 3 into the decoding speed estimation means 24 entered in the present embodiment. The decoding speed estimator 24 holds the decoding information in the internal table and gives the decoding information to the control means 6 according to the estimation request from the control means.

That is, in the present invention, encoded data is decoded in advance in the form of an example before actually recording on a recording sheet, and the decoding speed (decoding information) at that time is in the decoding speed estimation means 24 retained. The control means determines the actual recording process 6 from the decoding speed whether or not the decoding is complete until the recording sheets are at the recording means 7Y . 7M . 7C and 7K arrive. If the determination is made in time, the control means directs 6 the sheet feed instructions to the sheet transport 8th , That is why the control medium fulfills 6 in the present invention also the function of the control for inputting the decoding instructions to the decoding means 3 to obtain the decoding information in advance.

Accordingly, according to the tandem type color printer constructed as described above, the decoding process is performed in advance so that the decoding information in the decoding speed estimation means 24 is retained, after which, similar to the explanation in connection with the embodiment shown in 1 the timing between the feeding of the data to the recording medium is shown 7Y . 7M . 7C and 7K is adjusted on the basis of the decoding information, after which images with different colors are superimposed by the recording means 7Y . 7M . 7C and 7K on the recording sheets by the sheet transport 8th are transported, recorded, and then the recording sheets on which a color image is recorded are output.

10 shows an example of an image forming apparatus for processing image data for an image by dividing it into a plurality of sub-picture elements.

This image forming device comprises image dividing means 31 to divide input image data into a plurality of sub-picture elements, image storage means 32 to store data of the divided partial picture elements, image data supply means 33 to extract the sub-pixel data from the image file chermittel 32 feed or remove image data buffer 34 to temporarily save the partial image data items generated by the image data supply means 33 feed, withhold, feed time prediction means 35 to predict the time required when sub-picture data items from the image storage means 32 by the image data supply means 33 feed time storage means 36 to the by the feed time prediction means 35 to save predicted time, image data feed control means 37 to control the feeding by the image data feeding means and printing means 38 to record images on recording sheets according to the sub-picture data items stored in the image data buffer 34 be held back from printing.

The image dividing means 31 divides image data for an image that is continuously mainly in a main scanning direction as in FIG 11 (A) is shown in a main scan line as in 11 (B) is shown and stores data of the subpictures thus divided into the image memory 32 from.

As image storage 32 a magnetic disk or the like is used to store partial image data elements in writable and readable form.

The image data feeder 33 serves as a reading and writing medium between the image memory 32 and the image data buffer 34 to the sub-picture data items from the picture memory 32 read to the same in the image data buffer 34 under the control of the image data supply control means 32 withhold.

The image data buffer 34 is a buffer storage with regard to the pressure medium 38 , which is formed by a semiconductor memory, which is expensive, but has high access speed. This image data cache 34 is a memory having a smaller capacity than an image area, which in the present invention has a capacity capable of retaining two field data items.

The feed time prediction means 35 predicts the time up to which the sub-picture data item comes out of the frame buffer 32 was read out in the image data buffer 34 based on the amount of data of the partial picture elements and the feeding speed by the image data feeding means 33 is retained and stores the predicted time in the feed time memory 36 between.

The image data feed control agent 37 controls the feeding by the image data feeding means 35 based on the predicted time stored in the feed time memory 36 is temporarily stored, and at the time of printing start by the pressure medium 38 the sub-picture data item as an object to be printed, which is stored in the image data buffer 34 is withheld.

The pressure medium 38 performs printing with single color ink. Fields are sequentially transferred onto the recording sheets which are transported by the sheet transport means (not shown) based on the field data items stored in the image data buffer 34 be withheld, printed. The processing by the above image forming apparatus will be described with an example in which image data for one image is divided into four fields 1 to 4 is divided.

The sub-picture data items by the image dividing means 31 have been divided into the image data memory 32 saved. With this division, the time required to transfer the field data items to the buffer 34 by the feed time prediction means 35 is predicted and the predicted time is at the instigation of the feed time prediction means 35 in the feed time memory 36 retained.

The image data feed control agent 37 controls the feeding by the image data feeding means 33 based on the predicted time stored in the feed time memory 36 is retained and the sub-images based on the sub-image data items are on the recording sheet by the printing means 38 printed.

So that the leading drawing file 1 from the pressure medium 38 the corresponding sub-picture data elements should be printed in the image data buffer 34 be held back before the drawing file 1 is printed. Therefore, the image data supply control means determines 37 how long before printing begins with the feeding of the drawing file 1 to the cache 34 should start and cause the image data feed control means 33 , the feeding of the data of the drawing file 1 retrospectively at the predicted time intervals or more, as in 13 shown to start.

Such a feed control also applies to the following drawing files 2 to 4 , The feeding of the partial image data elements is started retrospectively at the time intervals based on the predicted time, so that when the printing medium starts printing 38 Data elements of the drawing files 1 to 4 in the image data buffer 34 be held back.

As a result, the data feed can be controlled with the most adequate timing based on the predicted time. Even if the cache 34 the partial images can not provide sufficient capacity for an image 1 to 4 continuously through the pressure medium 38 can be printed and the cost of the imaging device can be reduced.

13 shows another example in which the above-described image forming apparatus is embodied as a tandem type color printer.

This image forming device comprises image dividing means 41 to divide input image data into a plurality of sub-pixels, an image memory 42 to get data of the split part to store picture elements, an image data supply means 43 to extract field data items from the image memory 42 to remove or feed an image data buffer 44 to temporarily save the partial image data items generated by the image data supply means 43 to be fed, withheld, a feed time prediction means 45 to predict the time required when field data items from the frame buffer 42 by the image data supply means 43 are fed, feed time memory 46 to the by the feed time prediction means 45 to save predicted time, image data feed control means 47 to control the feeding by the image data feeding means and printing means 48Y . 48M . 48C and 48K to save images on the recording medium in accordance with the partial image data items stored in the image data buffer 44 be held back from printing.

The image dividing means 41 divides the input color image data into data of each color component yellow (Y), magenta (M), cyan (C) and black (K), divides this data in a direction of the main scanning line as in FIG 11 shown and stores the data of the thus divided sub-picture elements of each color in the image memory 42 from.

The image storage 42 is formed by a magnetic disk or the like in order to store the partial image data elements of each color in writable and readable form.

The image data feeder 43 is a reading and writing medium between the image memory 42 and the image data buffer 44 to the sub-picture data items from the picture memory 42 read to the same in the image data buffer 44 under the control of the image data supply control means 47 withhold. The image data buffer 44 is a buffer storage with regard to the pressure medium 48Y . 48M . 48C and 48K , which is formed by a semiconductor memory, which is expensive, but has a high access speed. This image data cache 44 is a memory that has a smaller capacity than an image portion of the color image data, which in the present invention is a capacity capable of holding two field data items.

The feed time prediction means 45 predicts the time up to which the field data item of each color component emerges from the image memory 42 is read out in the image data buffer 44 based on the amount of data for each color of the partial pixels and the feeding speed by the image data feeding means 43 is held back and holds the predicted time in the feed time memory 46 back.

The image data feed control agent 47 controls the feeding by the image data feeding means 45 based on the predicted time stored in the feed time memory 46 is retained and continues at the beginning of printing by the pressure medium 48Y . 48M . 48C and 48K the sub-picture data items as an object to be printed to be stored in the image data buffer 44 to be held back.

The pressure medium 48Y . 48M . 48C and 48K perform printing with yellow (Y), magenta (M), cyan (C) and black (B) color inks. The partial images are sequentially printed on the recording sheets by the sheet transport means (not shown) based on the partial image data items of the color components stored in the image data buffer 44 be held back, transported, overprinted.

In the above image forming apparatus, the partial image data items for each color component by the image dividing means 41 were divided in the image data memory 42 saved. In this section the feed time prediction means says 45 the time ahead required to cache the field data items for each color component 44 feed and causes the feed time memory 46 to withhold the predicted time.

The image data feed control agent 47 controls the feeding by the image data feeding means 43 based on the predicted time stored in the feed time memory 46 is retained, and the sub-images based on each color component of the sub-image data items are on the recording sheet by the printing means 48Y . 48M . 48C and 48K printed.

This example should also be similar to the previous example so that the drawing files are separated from the printing media 48Y . 48M . 48C and 48K are printed, the corresponding sub-picture data items of each color in the image data buffer 44 retained before starting to print the drawing files. Therefore, the image data supply control means determines 47 how long to start before printing begins, the data to the buffer 44 and causes the image data feed control means 43 , the feeding of the data of the drawing file 1 to start retrospectively at the predicted time intervals or more.

As a result, the data supply can be controlled at the most appropriate time based on the predicted time. Even if the cache 44 does not have the capacity for an image of the color image data, the partial images of each color component can be continuously fed through the printing medium 48Y . 48M . 48C and 48K can be printed on top of each other. The cost of the imaging device can be reduced.

As described above, according to the image forming apparatus in the present invention, processes such as decoding and data feeding are carried out, and the divided data items are cached in the buffer which serves as a buffer for recording each data item. Therefore, the amount of data stored in the cache until completion of printing is held back.

For this reason, the capacity of the cache, which is necessary to ensure the data supply, considerable be reduced, and the cost of the expensive cache, which consists of semiconductor memory, are required can be reduced to significantly reduce the cost of the device.

Furthermore, the recording process with the estimate the completion time of processes such as decoding and data feed performed because the recording process for performed every data item will while the recording media are transported. In connection with the corresponding data element, a sharp image on the recording medium without interference of quality how to record an image deviation.

Claims (9)

An image forming apparatus comprising: decoding means ( 3 ) to separate encoded image data for an image into color component data to decode it; Buffer ( 5 ) to cache the decoded data of each color component; Mode of Transport ( 8th ) to transport a recording medium; Receiving means ( 7Y . 7M . 7C . 7K ) by image elements of the color components on the recording medium on the basis of the in the buffer ( 5 ) to print stored data on top of each other; Estimation means ( 4 ) the process completion time for decoding all color component data by the decoding means ( 3 ) predict; characterized by control means ( 6 ) around the recording medium to an initial printing position of the recording medium ( 7Y . 7M . 7C . 7K ), which is arranged at the head of a transport route, on the basis of the estimated result by the estimating means ( 4 ), and around the receiving means ( 7Y . 7M . 7C . 7K ) to print the color component data. An image forming apparatus according to claim 1, further comprising: coding means ( 1 ) to encode news source image data, wherein image data generated by the encoding means ( 1 ) are encoded, decoded. An image forming apparatus according to claim 2, wherein the estimating means ( 4 Decoding completion time based on a coding speed of color component data by the coding means ( 4 ) predicts. An image forming apparatus according to claim 1, wherein the estimating means ( 4 ) predicts decode completion time based on a set of color component data codes. An image forming apparatus according to claim 1, wherein the estimating means ( 4 ) predicts the decoding completion time based on the number of encoded symbols of the color component data. An image forming apparatus according to claim 1, wherein individual color component data are processed to be decoded by a decoding means ( 3 ) to be decoded, and in which the estimation means ( 4 ) estimates the time required for the decoding process as the decoding completion time with respect to the remaining color component data. An image forming apparatus according to claim 1, wherein the recording means ( 7Y . 7M . 7C . 7K ) an image on a recording medium based on data stored in the buffer ( 5 ) are temporarily stored, prints, the device further comprising: image dividing means for dividing image data for an image into a plurality of partial picture elements which are divided parallel to a main scanning line; Image storage ( 2 ) to store the divided field data; Supply means for the partial image data from the image memory ( 2 ) to the buffer ( 5 ) feed; Recording medium ( 7Y . 7M . 7C . 7K ) to the field on a recording medium based on the field data stored in the buffer ( 5 ) are cached to record; and control means ( 6 ) to synchronize the feeding processing of the partial image data by the feeding means and the printing process by the recording means. The imaging device of claim 7, further full: a variety of recording means for image data for each color component to print in which the sub-images of each color component are based on the field data by the recording means one above the other to be printed. The imaging device of claim 1, further full: Data processing means for image data for an image divided into a variety of elements to process them.