JP2010030052A - Image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming device which reduces uneven print density by correcting the quantity of the light of a light emitting element, and prevents the deterioration of image quality by adjusting uneven density, especially caused by process strokes, by correcting the quantity of the light of the light emitting element. <P>SOLUTION: The image forming device which forms an electrostatic latent image on a photo-sensitive body by light emitted from the light emitting element based on image formation data comprises a first storing means for storing the quantity of light correction data based on the uneven emission of a light emitting element such as an LED, a second storing means for storing correction data based on streaks which are generated by a SELFOC lens or the like, a correction data operating means for adjusting the quantity of light correction data by the correction data stored in the second storing means, and a correction processing means for correcting the quantity of the light of the image formation data based on the quantity of light correction data which is calculated by the correction data operating means. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an image forming apparatus that reduces print density unevenness by performing light amount correction of a light emitting element.

  When a light emitting element such as an LED (Light Emitting Diode) is used as a print head as an image forming apparatus, exposure according to print data from the light emitting element is performed on the photosensitive member, and an image is written, for example, in a line shape. In such an image forming apparatus, density unevenness often occurs due to variations in the light amount of the light emitting elements, and correction processing is performed.

For example, Patent Document 1 is an invention of a light amount correction method for a print head, lighting a plurality of light emitting elements, measuring a light emission intensity distribution of each light emitting element by a light amount sensor, measuring a feature point in the light emission intensity distribution, Based on this feature point, light amount correction for supplying energy to the light emitting element is performed to prevent occurrence of uneven printing density.
JP-A-11-227254

  As described above, in the conventional example, the light amount variation of the light emitting element is corrected by measuring the light amount energy and the light emission intensity distribution. However, there is a problem that density unevenness is conspicuous in the printing result due to the visual frequency characteristics and the frequency characteristics of the correction data. This density unevenness is caused by process strokes due to variations in charging of the photoconductor, etc., and causes a reduction in image quality.

  Therefore, the present invention provides an image forming apparatus in which density unevenness caused by process strokes is adjusted by correcting the light amount of a light emitting element to prevent deterioration in image quality.

  According to the first aspect of the present invention, there is provided an image forming apparatus for forming an electrostatic latent image on a photosensitive member by light emission from a light emitting element based on image formation data, and forming an image on a recording medium. The first storage means for storing light amount correction data based on unevenness, the second storage means for storing correction data based on streak, and the correction data stored in the second storage means This can be achieved by providing an image forming apparatus having correction data calculation means for performing adjustment and correction processing means for performing light quantity correction of the image formation data based on the light quantity correction data calculated by the correction data calculation means.

  According to the second invention, in the image forming apparatus that forms an electrostatic latent image on the photosensitive member by light emission from the light emitting element based on the image formation data and forms an image on a recording medium, the light emission unevenness of the light emitting element. Storage means for storing light amount correction data based on the image, print processing means for printing an image determination test pattern, and a print output sheet of the image determination test pattern placed on a document table and printed on the print output sheet An image reading unit that reads the read image determination test pattern, an adjustment value generation unit that compares the read image data with the original image determination test pattern and generates adjustment value data, and the adjustment value Correction data calculation means for adjusting the light quantity correction data by means of, and light quantity correction of the image formation data based on the light quantity correction data calculated by the correction data calculation means. It can be achieved by providing an image forming apparatus and a correcting means for performing.

  According to the third aspect of the present invention, the print processing means also prints an image position detection test pattern, and superimposes the position information of the light emitting element on the analysis result of the image determination test pattern according to the print result. This can be achieved by providing a combined image forming apparatus.

  According to a fourth aspect of the present invention, there is provided a program used in an image forming apparatus for forming an electrostatic latent image on a photosensitive member by light emission from a light emitting element based on image formation data and forming an image on a recording medium. A process for storing light amount correction data based on light emission unevenness of the light emitting element in a first storage unit, a process for storing correction data based on streak in a second storage unit, and the second storage unit. A program for performing correction data calculation processing for adjusting the light amount correction data based on the correction data stored in the image data, and correction processing for correcting the light amount of the image formation data based on the light amount correction data calculated by the processing is provided. Can be achieved.

  According to a fifth aspect of the present invention, there is provided a program used in an image forming apparatus for forming an electrostatic latent image on a photosensitive member by light emission from a light emitting element based on image formation data and forming an image on a recording medium. A process for storing light amount correction data based on light emission unevenness of the light emitting element in a storage unit, a printing process for printing an image determination test pattern, and a print output sheet for the image determination test pattern on a document table. The image reading process for reading the image determination test pattern printed on the printed output paper is compared with the read image data and the original image determination test pattern, and the adjustment value data is obtained. Based on the adjustment value generation process to be generated, the correction data calculation process for adjusting the light quantity correction data based on the adjustment value, and the light quantity correction data calculated by the process. It can be achieved by providing a program for performing a correction process for performing light intensity correction of the form data.

  According to the present invention, a light amount correction data conversion table including process streak correction is used, the correction data of the conversion table is calculated for the head information of the print head, and light amount correction data including streak adjustment is generated. An image forming apparatus that reduces print density unevenness and improves print quality is provided.

(Embodiment 1)
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 2 is a system configuration diagram of a printing apparatus for explaining the present embodiment. In FIG. 1, a printing apparatus 1 includes an interface controller (hereinafter referred to as an I / F controller) 2 and an engine control unit 3. The I / F controller 2 includes a reception control unit 4, a ROM 5, a font ROM 6, and a display control unit 7. , A video I / F control unit 8, a memory 9 (standard RAM 9a, expansion RAM 9b), a DMA control unit 10, and an MPU 11. In addition, an operation panel 7a is connected to the display controller 7, and a streak determination instruction to be described later is performed.

  On the other hand, the engine control unit 3 includes a print head control unit (hereinafter simply referred to as a head control unit) 12, a motor control unit 13, an MPU 14, a fixing control unit 15, a high voltage control unit 16, a print head 17, a main motor 18, and various loads. 19, various sensors 20, a fixing thermistor 21, a fixing heater 22, and a high voltage unit 23.

  The printing apparatus 1 having the above configuration is supplied with print data from a host device 25 such as a personal computer (PC) or a printer server via a Centronics interface and a LAN (local area network). The print data supplied from the host device 25 is transferred to the reception control unit 4, and when a predetermined amount of print data is transferred to the reception control unit 4, the print data is transferred to the memory 9 (standard RAM 9a). The print data transferred to the memory 9 is subsequently analyzed according to the control of the MPU 11, compressed and decompressed by the DMA controller 10, and then sent from the video I / F controller 8 to the engine controller 3 (head). Is output to the controller 12).

The video data output to the head control unit 12 is subjected to processing described later and output to the print head 17. The motor control unit 13 controls the driving of the main motor 18, and the MPU 14 controls the head control unit 12 and the motor control unit 13 and also controls the fixing control unit 15 and the high voltage control unit 16.
FIG. 1 is a diagram for specifically explaining the configuration of the head control unit 12 and the configuration of the video I / F control unit 8. In the figure, the video I / F control unit 8 is included in the head control unit 12 for explanation.

  The head control unit 12 includes a head I / F control unit 30, a head correction data control unit 31, a basic timing generation unit 32, and a CPU I / F unit 33. The video I / F control unit 8 is connected to a video RAM 8 a that stores video data generated by the I / F controller 2.

  The head I / F control unit 30 includes a dot pattern generation unit 34, a head data transmission unit 35, a head control signal generation unit 36, and a strobe signal generation unit 37, and the dot pattern generation unit 34 starts from the video I / F control unit 8. Based on each gradation value, data in which one pixel of the supplied video data is developed into N fine pixels is generated with reference to a pattern registration register (not shown).

  The head data transmission unit 35 transfers the data generated by the dot pattern generation unit 34 to the print head 17 in synchronization with the dot clock (DCLK) output from the head control signal generation unit 36. The head control signal generator 36 also outputs a horizontal synchronization signal (HSYNC) in addition to the dot clock (DCLK).

  Further, the strobe signal generation unit 37 divides the sub-scanning direction into n according to the gradation information set by the CPU I / F unit 33 and transmits a corresponding strobe signal to the print head 17. For example, when the sub-scanning direction is divided into three, three types of strobe signals (1/3), (2/3), and (3/3) are output. When the sub-scanning direction is divided into four, the sub-line ( Four types of strobe signals (1/4), (2/4), (3/4), and (4/4) are output.

  The basic timing generation unit 32 generates a corresponding timing signal when the sub-scanning direction is divided into n according to the gradation information set by the CPU I / F unit 33, and outputs it to each unit. The CPU I / F unit 33 outputs the above gradation information, and performs address decoding processing, registration processing of each module, and the like.

  On the other hand, the head correction data control unit 31 includes a correction data calculation unit 40 and a correction RAM 41, and receives light amount correction data from the head information ROM 42 in the print head 17. The light amount correction data stored in the head information ROM 42 is obtained by measuring in advance the light amount variation of each light emitting element constituting the print head, and this correction data is stored as the light amount correction data.

  The correction data calculation unit 40 performs calculation processing of the light amount correction data supplied from the head information ROM 42 and correction data stored in a light amount correction data conversion table described later, and stores the calculation result.

In the above configuration, the processing operation of this example will be described below.
FIG. 3 is a diagram showing the correction data stored in the light quantity correction data conversion table as a characteristic diagram. In the figure, a correction value is set corresponding to the value of the light quantity γ. The original data has the same output value D with respect to the input value E.

This correction data is correction data caused by, for example, a SELFOC lens, for example, when the input value E, the output value D, and the correction range P are set,
When E ≦ 0, output value D = −P × (| E−P | / P) ^{(1 / r)}
When E ≧ 0, the output value D = P × (| E−P | / P) ^{(1 / r)}
The characteristics of γ corrections a to d are stored by γ values (for example, γ = 0.67), and each has a conversion table. For example, in the case of γ correction a having the largest correction amount, from the above characteristics, when the input value E is “−10”, the output value D is “−5”, and when the input value E is “10”, the output value is In D, a correction value “5” is stored. In the case of γ correction b, when the input value E is “−10”, the output value D is “−7”, and when the input value E is “10”, the output value D is “7”. The correction value is stored. The same applies to the other γ corrections c and d, and a conversion table corresponding to the characteristics shown in the figure is provided.

  Therefore, according to the flowchart shown in FIG. 4, first, the head correction data control unit 31 reads the light amount correction data from the head information ROM 42 in the print head 17 (step (hereinafter referred to as S) 1). Next, the correction data calculation unit 40 acquires light amount correction data from the light amount correction data conversion table of the correction RAM 41, and performs calculation processing of the light amount correction data (S2). That is, the correction data including the process streaks registered in the correction RAM 41 and the correction data of the light emitting element are calculated, and the light amount correction data in the correction RAM 41 is rewritten (S3).

  Therefore, this light amount correction data is data including correction of streaks caused by a SELFOC lens or the like, and is transferred to the print head 17 in synchronism with the dot clock (DCLK) described above (S4). Used for correction.

As described above, according to this example, new light amount correction data including process streaks is generated, and not only the light amount variation of light emitting elements but also corrections caused by process streaks are corrected by the light amount correction data, and the print density An image forming apparatus that eliminates unevenness can be provided.
(Embodiment 2)

Next, Embodiment 2 of the present invention will be described.
FIG. 5 is a schematic cross-sectional view of a printing apparatus illustrating an embodiment of the present invention. The printing apparatus 1 used in this example is provided with an image reading device 52.

  In the figure, a printing device 51 is composed of an image reading device 52, an image forming unit 53, an intermediate transfer medium 54, a paper feeding unit 55, and a fixing unit 56, and the image reading device 52 is disposed at the top. . The image forming unit 53 has a configuration in which four image forming units are arranged in parallel. The image forming unit 53M (magenta image forming unit), 53C (cyan image forming unit), 53Y (yellow image forming unit) and 53K (black image forming unit) are arranged in this order. The magenta (M), cyan (C), and yellow (Y) image forming units 53M to 53Y are used for color printing by subtractive color mixing, and the black (K) image forming unit 53K is used for monochrome printing.

  Here, each of the image forming units 53M to 53K has the same configuration except for the toner (color) stored in the developing container, and is disposed in the vicinity of the photosensitive drum 58 and the peripheral surface of the photosensitive drum 58. The charger 59, the print head 17, and the developing roll 61 are sequentially arranged, the photosensitive drum 58 is rotated in the direction of the arrow, the charge is applied from the charger 59, and optical writing based on the print information from the print head 17 is performed. As a result, an electrostatic latent image is formed on the peripheral surface of the photosensitive drum 58, and a toner image is formed by development processing by the developing roll 61.

  The intermediate transfer medium 54 includes a transfer belt 62, a drive roll 63 that rotates the transfer belt 62, a driven roll 64, and the like. The toner image formed on the photosensitive drum 58 is transferred to the transfer belt 62, and the drive roll 63. Is sent to the transfer section 65. The transfer unit 65 is supplied with a sheet transported from a sheet feeding unit (sheet feeding cassette) 55 by a conveyance roller 66, and the toner image on the transfer belt 62 is transferred to the sheet and is fixed to the sheet by a fixing unit 56. .

  On the other hand, the image reading device 52 is provided with a document reading unit 70 and an ADF (auto document feeder) 71. The document reading unit 70 is provided with a light source 72, a mirror 73, a document table motor 74, and a CCD unit 75, and a document image placed on a document table glass 77 is read by driving the document table motor 74.

  FIG. 6 is a diagram for explaining the system configuration of the printing apparatus 51 of this example, in which the image reading apparatus 52 is connected to the I / F controller 2 of FIG. The image reading device 52 includes a document table motor 74, a motor 80 for driving the ADF 71, a CCD sensor 81, an A / D (analog / digital converter) 82, and an MCU 83 provided in the CCD unit 75 described above. After a document to be described later is placed on the document table glass 77, the document image is read by the CCD sensor 81 by driving the document table motor 74, and the document image is converted into digital data by the A / D converter 82. Thereafter, the data is transferred to the I / F controller 2 under the control of the MCU 83.

  The configuration of the I / F controller 2 is the same as that of FIG. 2 described above, and print data supplied from the host device 25 is converted into video data and transferred to the head controller 12 via the video I / F controller 8. . Therefore, the description of the circuit described in FIG. 2 is omitted in FIG.

FIG. 7 is a diagram showing a system configuration of the head control unit 12 of this example, and the same circuits as those in FIG.
As described above, the head control unit 12 includes a head I / F control unit 30, a head correction data control unit 31, a basic timing generation unit 32, and a CPU I / F unit 33. The video I / F control unit 8 includes an I / F. A video RAM 8a for storing video data generated by the F controller 2 is connected.

  The head I / F control unit 30 includes a dot pattern generation unit 34, a head data transmission unit 35, a head control signal generation unit 36, and a strobe signal generation unit 37, and the dot pattern generation unit 34 starts from the video I / F control unit 8. Based on each gradation value, dot pattern data in which one pixel of the supplied video data is developed into N fine pixels is generated.

  The head data transmission unit 35 transfers the dot pattern data generated by the dot pattern generation unit 34 to the print head 17 in synchronization with the dot clock (DCLK) output from the head control signal generation unit 36. Further, the strobe signal generation unit 37 divides the sub-scanning direction into n according to the gradation information set by the CPU I / F unit 33 and transmits a corresponding strobe signal to the print head 17.

  The basic timing generation unit 32 generates a corresponding timing signal when the sub-scanning direction is divided into n according to the gradation information set by the CPU I / F unit 33, and the CPU I / F unit 33 outputs the above gradation information. Are output, and address decoding processing, registration processing of each module, and the like are performed.

On the other hand, the head correction data control unit 31 includes a correction data calculation unit 40 and a correction RAM 41, and stores light amount correction data for correcting the light amount variation of each element constituting the print head stored in the head information ROM 42 of the print head 17. input.
The correction RAM 85 includes light amount correction data, streak data, and position detection data, which will be described later.

In the above configuration, the processing operation of this example will be described below.
FIG. 8 shows an example of a test chart for inspection output from the host device 25, for example. Note that the example in the figure shows where each test chart is printed on the paper. The test chart for inspection includes an image determination test pattern and an image position detection test pattern. The image determination test pattern is printed in the area A, and the image position detection test pattern is printed in the area B.

  For example, the image determination test pattern printed in the area A is data of a dot image of 100 to 200 LPI. The image position detection test pattern printed in the region B is a chip position determination image, which will be described in detail later.

FIG. 9 is a flowchart for explaining the printing process of the image determination test pattern (streaks determination test pattern) and the image position detection test pattern.
First, when a “test pattern printing” operation key (not shown) disposed on the operation panel 7a is pressed, an image determination test pattern (streaks determination test pattern) is first transferred from the host device 25 to the printing apparatus 1. Transferred (step (hereinafter referred to as ST) 1). This pattern data is input to the I / F controller 2 and stored in the memory unit 9.

  Next, image position detection head correction data switching processing is performed (ST2), and an image position detection test pattern is transferred from the host device 25 (ST3). This image determination test pattern is also temporarily stored in the I / F controller 2. Stored in the memory unit 9.

  When the MPU 11 determines the input of the test pattern, the MPU 11 performs command analysis and performs printing processing on the sheet by the print head 17 via the video I / F control unit 8 and the head I / F control unit 30. By the above processing, the image determination test pattern (streaks determination test pattern) and the image position detection test pattern shown in FIG. 8 are output.

  Next, a sheet on which both test patterns are printed by the above processing is placed on the above-described original platen glass 77, and when an “image determination” operation key (not shown) provided on the operation panel 7a is pressed, the image reading device 52 is driven. That is, the document table motor 74 is driven to emit light from the light source 72 to the sheet via the mirror 73, and the reflected light is detected by the CCD sensor 81.

  FIG. 10 is a flowchart for explaining processing of the document image detected by the CCD sensor 81. Data of the document image detected by the CCD sensor 81 is transferred to the I / F controller 2 under the control of the MCU 83 (step ( Hereinafter, indicated by STP) 1). Thereafter, it is temporarily stored in the memory unit 9.

  Next, inspection processing of the image stored in the memory unit 9 is started (STP2). First, an image determination test pattern (streaks determination test pattern) is inspected (STP2). In this process, streak is determined based on the image data of the streak determination test pattern printed in the area A shown in FIG.

  This streak is a phenomenon in which streak-like or band-like blurring is generated on a printed image due to lens unevenness or an arrangement error of the photosensitive drum 58 or the like. FIG. 11 is a diagram for explaining the streak determination method, and shows an example of a halftone dot with a screen angle of 150 degrees of 150 DPI. In the process of this example, streak determination is performed by extracting density steps of peripheral pixels adjacent to the target pixel.

  For example, the example shown in FIG. 5A is a configuration in which streak determination is performed on a 600 DPI pixel with a halftone dot of 25%. The streak determination is performed with the target pixel being four pixels and the surrounding pixels being, for example, 32 pixels. It is an example to do. In this case, the pixel of interest is shifted by one dot in the main scanning direction (arrow direction), and the moving average difference of the peripheral pixels with respect to the pixel of interest is calculated according to the calculation formula shown in FIG.

  In the above formula, Xi represents pixel data of the target pixel, n represents the number of data of the target pixel, Yi represents pixel data of the peripheral pixel, and m represents the number of data of the peripheral pixel. In the above example, an example of halftone dots of 25% has been described, but halftone dots of 12%, 33%, 48%, etc. can be calculated in the same manner.

  FIG. 6C is a diagram showing an example of white or black band determination. In order to determine white or black streaks, a relatively large 8 pixels are used as the number of pixels of interest, and 192 pixels are used as peripheral pixels. In this case, if there is a large density step, the amplitude of the scan data increases as shown in FIG. 5C, and streak is determined depending on whether or not the threshold is exceeded.

  FIG. 4D is a diagram showing an example of white or black streak determination. In order to determine white or black streak streaks, for example, a relatively small four pixels are used as the number of pixels of interest. 32 pixels are used as peripheral pixels. Also in this case, if there is a large density step, the amplitude of the scan data increases as shown in FIG. 4D, and streaks are similarly determined by whether or not a predetermined threshold is exceeded.

  FIG. 12 is a diagram illustrating an analysis example in which a white or black band is extracted from image data for an image having streak. FIG. 6B shows the calculation result. For example, the threshold value of streak is set to ± 5, and the position of the density difference larger than that is set to NG. FIG. 4A shows the result of white or black band determination according to the threshold value. The white band shown in FIG. 5A is a case where the threshold value of − (minus) 5 or less is exceeded, and the black band is a case where the threshold value of + (plus) 5 or more is exceeded.

  On the other hand, FIG. 13 is a diagram showing an analysis example in which white or black streaks are extracted from image data for an image in which streaks exist, and FIG. 13B is a diagram showing the above calculation results. Is set to ± 5, and the density difference position larger than that is set to NG. Also in this case, FIG. 9A shows the determination result of white or black stripes according to the threshold value. The white streaks shown in FIG. 5A are cases where the threshold value of − (minus) 5 or less is exceeded, and the black streaks are cases where the threshold value of + (plus) 5 or more is exceeded.

  As described above, by analyzing the image data of the halftone dot image, white or black stripes, white or black streaks are digitized, and whether or not streaks are within an allowable range is determined. Results can be obtained (STP3). Therefore, an adjustment value for the head correction value data is generated based on the result of the streak determination (STP4).

  Next, the correction data calculation unit 40 of the head correction data control unit 31 rewrites the head correction data RAM according to the adjustment value (STP5). In this processing, LEi is the original light amount correction data (light amount correction data from the head information ROM 42), STi is the data adjusted by the streak determination, and the light amount correction value data after the streak adjustment is LDi. It is possible to calculate based on the formula of LDi = LEi-STi * k. Note that k is a coefficient, and i = 0 to 7679 when the light emitting element of the print head is, for example, 7680.

Thereafter, the light quantity correction value data is transferred to the print head 17 according to the dot clock (DCLK) (STP6), and the print density unevenness is adjusted.
On the other hand, the reading result of the image position detection test pattern is used as follows. FIG. 14 shows an example of the above test pattern. In this example, a print head having a configuration in which 192 (dot) light emitting elements are arranged as one chip and 40 chips are arranged in a row is used, and 7680 as a whole. A dot light emitting element is used. The maximum value “63” is set for the light intensity correction data of the first dot of each of the 40 chips, and the center value “31” is set for the other dots, and this data is used for image position detection. Realized in test pattern. Therefore, when the same gradation data is given to each dot, the first dot of each chip is printed with a higher density than the other dots.

  FIG. 15A shows the result of density analysis after reading the image position detection test pattern. It can be seen that the first dot of each chip is shown at a high density for every 192 dots. On the other hand, FIG. 4B is a diagram showing the above-mentioned streak analysis results, and both results correspond to the printing positions on the horizontal axis.

  Therefore, by superimposing the first dot positions of each chip, it is possible to know the positional relationship between the streak information and each light emitting element of the print head. That is, when performing the streak determination, it is possible to accurately know the occurrence position of white or black stripes or white or black bands by accurately knowing the position of the light emitting element obtained from the image position detection test pattern.

It is a figure explaining the structure of a head control part, and the structure of a video I / F control part concretely. 1 is a system configuration diagram of a printing apparatus for explaining Embodiment 1. FIG. It is a figure which shows the correction data memorize | stored in the light quantity correction data conversion table as a characteristic view. 3 is a flowchart for explaining a processing operation of the first embodiment. FIG. 6 is a schematic cross-sectional view of a printing apparatus for explaining a second embodiment. 1 is a diagram illustrating a system configuration of a printing apparatus. It is a figure which shows the system configuration | structure of a head control part. It is a figure which shows the example of the test chart for a test | inspection. It is a figure which shows the structural example of the test pattern for image determination (test pattern for streak determination). 6 is a flowchart for explaining processing of a document image detected by a CCD sensor. It is a figure explaining a streak judgment method, (a) is a structure which performs streak judgment with respect to a pixel of 600 DPI with a halftone dot of 25%, (b) is a figure showing a calculation formula, (c) is a figure which shows the example of determination of a white or black belt | band | zone, (d) is a figure which shows the example of determination of a white or black stripe. It is a figure showing an analysis example in which a white or black belt for an image having a stream is extracted from image data, (a) is a figure showing a determination result of a white or black belt according to a threshold, (b) An analysis result is shown. It is a figure showing an analysis example in which white or black streaks for an image in which streaks are extracted from image data, (a) is a figure showing a determination result of white or black streaks according to a threshold, (b) An analysis result is shown. It is a figure which shows the structure of the test pattern for image position detection. (A) is a figure which shows the result of having analyzed the density after reading the test pattern for image position detection, (b) is a figure which shows the analysis result of streak, and the printing position of a horizontal axis corresponds. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Printing apparatus 2 ... I / F controller 3 ... Engine control part 4 ... Reception control part 5 ... ROM
6 ... Font ROM
7... Display control unit 7 a ..Operation panel 8... Video I / F control unit 9... Memory 10... DMA control unit 11.
12. ・ Head controller 13 ・ ・ Motor controller 14 ・ ・ MPU
15. .. Fixing control unit 16 .. High pressure control unit 17... Print head 18. Main motor 19. Load 20. Various sensors 21. Fixing thermistor 22 Fixing heater 23 High pressure unit 25 Host Device 30 .. Head I / F control unit 31... Head correction data control unit 32... Basic timing generation unit 33... CPU I / F unit 34... Dot pattern generation unit 35. Control signal generation unit 37 .. Strobe signal generation unit 40 .. Correction data calculation unit 41 .. Correction RAM
42 .. Head information ROM
51..Printing device 52..Image reading device 53..Image forming unit 54..Intermediate transfer medium 55..Paper feeding unit 56..Fixing unit 58..Photosensitive drum 59. 62. Transfer belt 63 Drive roller 64 Transfer roller 66 Transfer roller 70 Document reading unit 71 ADF
72..Light source 73..Mirror 74..Document table motor 75..CCD unit 77..Document table glass 80..Motor 81..CCD sensor 82..A / D converter 83..MCU
85 .. Correction RAM

Claims (5)

In an image forming apparatus that forms an electrostatic latent image on a photoreceptor by light emission from a light emitting element based on image formation data, and forms an image on a recording medium.
First storage means for storing light amount correction data based on light emission unevenness of the light emitting element;
Second storage means for storing correction data based on the streaks;
Correction data calculation means for adjusting the light quantity correction data according to the correction data stored in the second storage means;
Correction processing means for performing light quantity correction of the image formation data based on the light quantity correction data calculated by the correction data calculation means;
An image forming apparatus comprising: In an image forming apparatus that forms an electrostatic latent image on a photoreceptor by light emission from a light emitting element based on image formation data, and forms an image on a recording medium.
Storage means for storing light amount correction data based on light emission unevenness of the light emitting element;
Print processing means for printing a test pattern for image determination;
Image reading means for placing the print output paper of the image determination test pattern on a document table and reading the image determination test pattern printed on the print output paper;
An adjustment value creating means for comparing the read image data with the original image determination test pattern and generating adjustment value data;
Correction data calculation means for adjusting the light amount correction data according to the adjustment value;
Correction processing means for performing light quantity correction of the image formation data based on the light quantity correction data calculated by the correction data calculation means;
An image forming apparatus comprising:   2. The image formation according to claim 1, wherein the print processing unit also prints an image position detection test pattern, and superimposes the position information of the light emitting element on the analysis result of the image determination test pattern according to the print result. apparatus. A program used for an image forming apparatus that forms an electrostatic latent image on a photosensitive member by light emission from a light emitting element based on image formation data and forms an image on a recording medium,
A process of storing light amount correction data based on light emission unevenness of the light emitting element in the first storage means;
Storing correction data based on the streak in the second storage means;
Correction data calculation processing for adjusting the light amount correction data by the correction data stored in the second storage means;
Correction processing for performing light amount correction of the image formation data based on the light amount correction data calculated by the processing;
The program characterized by performing. A program used in an image forming apparatus that forms an electrostatic latent image on a photoreceptor by light emission from a light emitting element based on image formation data, and forms an image on a recording medium,
A process for storing light amount correction data based on light emission unevenness of the light emitting element in a storage unit;
A printing process for printing a test pattern for image determination;
An image reading process of placing the print output paper of the image determination test pattern on a document table and reading the image determination test pattern printed on the print output paper;
An adjustment value creating process for comparing the read image data with the original image determination test pattern and generating adjustment value data;
Correction data calculation processing for adjusting the light amount correction data according to the adjustment value;
Correction processing for performing light amount correction of the image formation data based on the light amount correction data calculated by the processing;
The program characterized by performing.