JP2004102103A - Image forming apparatus and method for controlling scanning length thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming apparatus which can suppress deterioration in images caused by difference in scanning lengths between each of multiple beams without increasing cost. <P>SOLUTION: The image forming apparatus detects the difference (Xb-Xa) in the scanning lengths on a photosensitive drum 11 between each of laser beams based on the outputs of each of BD sensors 36 and 37 and changes the number of the high-frequency clocks forming one pixel at a specific point on a line scanned by the corresponding laser beam based on the result of the detection. As a result, the scanning lengths Xa and Xb on the surface of the photosensitive drum 11 are electrically corrected, making it possible to make the scanning lengths Xa and Xb by the two laser beams equal to each other. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image forming apparatus having a multi-beam scanning optical system that scans a corresponding line with a plurality of beams, and a scanning length control method thereof.
[0002]
[Prior art]
2. Description of the Related Art Generally, in an image forming apparatus such as a laser copying machine, a laser facsimile, and a laser printer, a scanning optical system that performs scanning by condensing laser light emitted from a laser light source as a light spot on a surface to be scanned such as a photoconductor. In recent years, in order to speed up writing, a multi-beam scanning optical system that simultaneously scans corresponding lines using a plurality of beams has been proposed as an alternative to the above scanning optical system. Have been.
[0003]
In the above multi-beam scanning optical system, a plurality of, for example, two laser light sources are arranged at intervals in the sub-scanning direction, and a scanning length (writing width) on a surface to be scanned by laser light from each laser light source. Are required to be equal, the optical path length from one laser light source to the photoconductor must be equal to the optical path length from the other laser light source to the photoconductor.
[0004]
[Problems to be solved by the invention]
However, usually, in addition to optical and mechanical errors, the scanning length (writing width) of each laser beam on the surface to be scanned is different due to the fluctuation of the optical system due to the temperature rise and the fluctuation of the laser wavelength. A difference occurs in the scanning length on the surface to be scanned by each laser beam. Due to the difference in the scanning lengths, there is a problem that, in particular, vertical line fluctuations occur, which significantly affects image deterioration.
[0005]
For this reason, Japanese Patent Application Laid-Open No. 10-268214 discloses a technique of shifting the scanning start timing of each laser beam so that pixels formed at the center of an image are aligned in order to reduce the pixel shift between the laser beams. ing. However, in the technique described in Japanese Patent Application Laid-Open No. H10-268214, although the pixel shift at the center of the main scanning is reduced, the pixel shift is most conspicuous when the writing width difference between the laser beams is large. In this state, the pixel shift between the scan start position and the end position remains large.
[0006]
Japanese Patent Application Laid-Open No. 2000-199868 discloses a technique of adjusting the scanning length between beams by finely adjusting the frequency of a beam writing clock. As a circuit for changing the frequency of the clock, a frequency synthesizer or the like is generally used. However, this is relatively expensive and causes an increase in the cost of the image forming apparatus.
[0007]
A first object of the present invention is to provide an image forming apparatus capable of suppressing deterioration of an image due to a difference in scanning length between each of a plurality of beams without increasing cost, and a scanning length control method thereof. It is in.
[0008]
Further, a second object of the present invention is to provide an image forming apparatus and a scanning length control method thereof capable of suppressing deterioration of an image due to a difference in scanning length between each of a plurality of beams and a displacement of pixels between lines. The purpose is to provide.
[0009]
[Means for Solving the Problems]
In order to achieve the first object, the present invention provides an image forming apparatus having a multi-beam scanning optical system for scanning a corresponding line with a plurality of beams, respectively, wherein a difference in scanning length between each of the plurality of beams is provided. A main clock composed of a plurality of high-frequency clocks having a predetermined frequency as a write clock for each of the plurality of beams, and writing each of the plurality of beams. A clock generating means for variably controlling the number of high-frequency clocks constituting the main clock according to a position; and forming a main clock of a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detecting means. By controlling the write position to change the number of high frequency clocks to be Characterized in that it comprises a correcting means for correcting the scanning length by.
[0010]
Further, the scanning length difference detecting means includes a scanning start position detecting means for detecting a scanning start position of each of the plurality of beams, and a scanning end position detecting means for detecting a scanning end position of each of the plurality of beams. The plurality of beams based on the respective scan start positions of the plurality of beams detected by the scan start position detection unit and the respective scan end positions of the plurality of beams detected by the scan end position detection unit. The method is characterized in that a difference in scanning length due to each of the beams is detected.
[0011]
The high-frequency clock generating means for generating the high-frequency clock from the basic clock is provided, and the high-frequency clock is a clock that is an integral multiple of the basic clock.
[0012]
Further, in order to achieve the second object, the present invention provides a multi-beam scanning optical system that scans a corresponding line with a plurality of beams, and a scanning start position detecting unit that detects a scanning start position of each of the plurality of beams. Means for starting image formation with each of the plurality of beams based on a detection result for each of the plurality of beams by the scanning start position detecting means, wherein scanning with each of the plurality of beams is performed. Scanning length difference detection means for detecting a difference between lengths, and first correction means for controlling timing of starting image formation of a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detection means And a second compensation for correcting a scanning length by a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detecting means. Characterized in that it comprises a means.
[0013]
Further, the first correction means controls to delay the timing of starting image formation by a corresponding beam among the plurality of beams.
[0014]
Further, the first correction unit controls to delay the corresponding detection result among the detection results of the plurality of beams by the scanning start position detection unit.
[0015]
Further, a main clock composed of a plurality of high frequency clocks having a predetermined frequency is generated as a write clock for each of the plurality of beams, and the main clock is generated according to a write position for each of the plurality of beams. Clock generating means for variably controlling the number of high frequency clocks to be constituted, wherein the second correcting means sets a main clock of a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detecting means. The scanning length by the corresponding beam is corrected by controlling a writing position for changing the number of high frequency clocks to be constituted.
[0016]
A scanning end position detecting unit that detects a scanning end position of each of the plurality of beams; wherein the scanning length difference detecting unit detects a scanning start position of each of the plurality of beams detected by the scanning start position detecting unit; A difference in scan length between each of the plurality of beams is detected based on a position and a scan end position of each of the plurality of beams detected by the scan end position detecting means.
[0017]
The high-frequency clock generating means for generating the high-frequency clock from the basic clock is provided, and the high-frequency clock is a clock that is an integral multiple of the basic clock.
[0018]
In order to achieve the first object, the present invention provides a multi-beam scanning optical system for scanning a corresponding line with a plurality of beams, and a main clock comprising a plurality of high-frequency clocks having a predetermined frequency. An image forming apparatus for generating a clock as a write clock for each of the plurality of beams, and varying the number of high-frequency clocks constituting the main clock in accordance with a write position for each of the plurality of beams. A scanning length difference detecting step of detecting a scanning length difference between each of the plurality of beams, based on a detection result of the scanning length difference detecting step, among the plurality of beams, The write position to change the number of high-frequency clocks that make up the main clock of the moving beam Accordingly, characterized in that it comprises a correction step of correcting the scanning length by the corresponding beam.
[0019]
Further, in order to achieve the second object, the present invention provides a multi-beam scanning optical system that scans a corresponding line with a plurality of beams, and a scanning start position detecting unit that detects a scanning start position of each of the plurality of beams. A scanning length control method for an image forming apparatus, comprising: means for starting image formation by each of the plurality of beams based on a detection result for each of the plurality of beams by the scanning start position detecting means. A scanning length difference detecting step of detecting a difference between the scanning lengths of the respective beams, and controlling a timing of starting image formation of a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detecting step. And correcting the scanning length by the corresponding beam among the plurality of beams based on the correction step of (1) and the detection result of the scanning length difference detecting means. Characterized in that it comprises a second correction step of.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0021]
(1st Embodiment)
FIG. 1 is a longitudinal sectional view schematically showing the configuration of the image forming apparatus according to the first embodiment of the present invention.
[0022]
As shown in FIG. 1, the image forming apparatus includes a document feeder 1 capable of stacking a plurality of documents, and a scanner unit 4 configured to be movable in the sub-scanning direction. The document feeder 1 conveys a plurality of loaded documents one by one from the top onto the platen glass 2. The scanner unit 4 has a lamp 3 for illuminating a document conveyed on the platen glass 2 and a reflection mirror 5 for guiding light reflected from the document on the platen glass 2 to a reflection mirror 6. . The reflecting mirror 6 guides the reflected light from the reflecting mirror 5 to the lens 8 in cooperation with the reflecting mirror 7, and the lens 8 forms an image of the reflected light on the image sensor unit 9. The image sensor unit 9 converts the formed light image into an electric signal, and after performing a predetermined process, the electric signal is input to the exposure control unit 10 as an image signal.
[0023]
The exposure controller 10 emits a laser beam based on the input image signal, and performs exposure scanning on the photosensitive drum 11 with the laser beam. The latent image corresponding to the laser beam is formed on the photosensitive drum 11 by the exposure scanning of the laser beam. The latent image formed on the photosensitive drum 11 is visualized as a toner image by the toner supplied from the developing device 13.
[0024]
Further, a sheet is fed from the cassette 14 or the cassette 15 at a timing synchronized with the start of the laser beam irradiation, and the sheet is conveyed to the transfer unit 16 via the conveyance path. The transfer unit 16 transfers the toner image on the photosensitive drum 11 onto the conveyed sheet. The sheet on which the toner image has been transferred is conveyed to the fixing unit 17.
[0025]
In the fixing unit 17, the toner image on the sheet is heated and fixed on the sheet. The sheet that has passed through the fixing unit 17 is discharged to the outside via a discharge roller pair 18.
[0026]
After the surface of the photosensitive drum 11 after the transfer of the toner image is cleaned by the cleaner 25, the charge is removed by the auxiliary charger 26. Then, after the residual charges on the surface of the photosensitive drum 11 are erased by the pre-exposure lamp 27 and a state is obtained in which the primary charger 28 obtains a good charge, the surface of the photosensitive drum 11 is charged by the primary charger 28. .
[0027]
By repeating the above series of steps, it is possible to form a plurality of images.
[0028]
Next, a detailed configuration of the exposure control unit 10 will be described with reference to FIGS. FIG. 2 is a plan view schematically illustrating the configuration of the exposure control unit 10 of FIG. 1, and FIG. 3 is a side view schematically illustrating the configuration of the exposure control unit 10 of FIG.
[0029]
The exposure control unit 10 includes a laser driving device 31 that drives the semiconductor laser 43, as shown in FIG. Although not shown, in the present embodiment, two semiconductor lasers are provided, and a laser driving device and a modulation unit described later are provided for each of them.
[0030]
A photodiode sensor (PD sensor; not shown) for detecting a part of the laser beam is provided inside the semiconductor laser 43, and the laser driving device 31 uses the detection signal of the PD sensor to control the APC of the semiconductor laser 43. (Auto Power Control) control is performed. The laser light emitted from the semiconductor laser 43 becomes almost parallel light by the collimator lens 35 and the stop 32, and enters the polygon mirror (rotating polygon mirror) 33 with a predetermined beam diameter. The polygon mirror 33 is rotated at a constant angular velocity in the direction indicated by the arrow in the drawing, and with this rotation, the laser light incident on the polygon mirror 33 is reflected as a deflection beam whose angle continuously changes. . The laser beam reflected as a deflected beam is condensed by the f-θ lens 34. At the same time, the f-θ lens 34 corrects the distortion so as to guarantee the temporal linearity of the scanning, so that the laser beam passing through the f-θ lens 34 At the same speed.
[0031]
In the vicinity of one end of the photosensitive drum 11, a beam detect (hereinafter, referred to as BD) sensor 36 for detecting a laser beam reflected from the polygon mirror 33 is provided, and near the other end, a BD sensor is provided. 37 are provided. The detection signal of the BD sensor 36 is a scanning start position signal, and is used as a synchronization signal for synchronizing the rotation of the polygon mirror 33 and the writing of data. The detection signal of the BD sensor 37 is a scan end position signal, and is used together with the scan start position signal of the BD sensor 36 to calculate the scan time by each laser beam.
[0032]
In the present embodiment, as described above, two semiconductor lasers 43 are provided. In this case, as shown in FIG. 3A, the two laser beams are deflected by the polygon mirror 33 rotating at a constant speed and are irradiated onto the photosensitive drum 11. That is, by scanning the photosensitive drum 11 in the main scanning direction with two laser beams, an electrostatic latent image is formed on the photosensitive drum 11. Here, the two laser beams are applied to the photosensitive drum 11 at a predetermined interval in the sub-scanning direction. With such a configuration, image formation can be performed with half the number of scans as compared with the case where the photosensitive drum 11 is scanned with one laser.
[0033]
Here, as shown in FIG. 3B, assuming that the optical path lengths of the respective laser beams from the polygon mirror 33 to the photosensitive drum 11 are La and Lb, the respective laser beams are spaced at a predetermined interval in the sub-scanning direction. Since the photosensitive drum 11 is irradiated in this state, the optical path lengths La and Lb are different. Here, it is assumed that the relational expression of La <Lb holds, and the difference is ΔL.
[0034]
The fact that the optical path lengths La and Lb of the respective laser beams from the polygon mirror 33 to the photosensitive drum 11 are different from each other means that the effective pixels of one scanning line in the main scanning direction on the photosensitive drum 11 as shown in FIG. The scanning length of the laser light for the range will be different for each laser light. Here, assuming that the scanning length of the laser beam in the case of the optical path length La is Xa and the scanning length of the laser beam in the case of the optical path length Lb is Xb, the relational expression of Xa <Xb is established.
[0035]
Such optical path length differences due to optical and mechanical errors include optical path length differences due to fluctuations in the optical system due to temperature rise and fluctuations in the wavelength of the laser, and the respective optical path length differences may be added. . Therefore, even if there is an optical path length difference due to an optical or mechanical error, if the optical path difference due to a change in the optical system due to a rise in temperature or a change in the wavelength of the laser occurs, the scanning lengths Xa and Xb are similarly determined. Will be different.
[0036]
When an image is formed in such a state, an image having jagged edges at every other line is obtained. In today's situation where the demand for high resolution for images is increasing, the jagged edges do not meet the high resolution requirements.
[0037]
Therefore, in the present embodiment, means for correcting the scanning length so as to reduce the difference in the scanning length on the photosensitive drum 11 by each laser beam is provided. The basic principle of this scan length correction and the configuration for realizing it will be described.
[0038]
In the scanning length correction of the present embodiment, a difference (Xb-Xa) between the scanning lengths of the laser beams on the photosensitive drum 11 is detected based on the outputs of the BD sensors 36 and 37, and the corresponding laser beam is detected based on the detection result. To change the number of high frequency clocks forming one pixel at a specific location on the line scanned.
[0039]
First, a method of detecting the difference (Xb-Xa) in the scanning length on the photosensitive drum 11 by each laser beam will be described with reference to FIG. FIG. 4 is a timing chart showing the output of each of the BD sensors 36 and 37 with respect to each laser beam of FIG. Here, one of the two semiconductor lasers 43 is referred to as LD1 and the other is referred to as LD2, and the outputs of the BD sensors 36 and 37 when each is turned on are shown.
[0040]
When scanning with the LD1 turned on, as shown in FIG. 4A, the time T1 from the output of the BD sensor 36 to the output of the BD sensor 37 is the scanning time of the LD1. Similarly, when scanning with the LD2 turned on, as shown in FIG. 4B, the time T2 (<T1) from the output of the BD sensor 36 to the output of the BD sensor 37 is the scanning time of the LD2. Here, assuming that the distance between the BD sensors 36 and 37 is L, the difference (Xb-Xa) between the scanning length of LD1 and the scanning length of LD2 is
Xb-Xa {(T1-T2) / T2} × L (1)
It becomes. (T1-T2≪T1, T2)
In this manner, the difference (Xb-Xa) between the scanning length of LD1 and the scanning length of LD2 can be obtained from the outputs of the BD sensors 36 and 37.
[0041]
Next, a method for correcting the scanning length on the surface of the photosensitive drum 11 by the corresponding laser light will be described with reference to FIGS. FIG. 5 is a block diagram showing a configuration of the modulation section 48 of FIG. 2, FIG. 6 is a timing chart of input / output signals of the frequency divider 61 of FIG. 5, and FIG. 7 is a timing chart of input / output signals of the modulation circuit 62 of FIG. FIG. 8 is a timing chart of input / output signals of the counter circuit 64 and the output circuit 63 of FIG.
[0042]
In the present embodiment, as described above, it is assumed that there is a relationship of Xb> Xa between the scan lengths Xa and Xb, and the modulator 48 corresponding to the semiconductor laser that draws the scan length Xa makes the scan length Xa equal to Xb. The control for correction is performed as described above. As shown in FIG. 5, the controllable modulator 48 includes a PLL circuit 60, a frequency dividing circuit 61, a modulating circuit 62, an output circuit 63, and a counter circuit 64.
[0043]
The PLL circuit 60 receives a basic clock (basic CLK) as an input, and outputs a high-frequency clock that is n times the basic clock. This high frequency clock is input to the frequency dividing circuit 61 and the output circuit 63, respectively. The frequency dividing circuit 61 outputs a clock (main clock) obtained by dividing the input high frequency clock by 1 / x by counting the input high frequency clock once every x times (see FIG. 6). Here, x may be any positive number. Here, for convenience of explanation, it is assumed that a main clock having the same cycle as the basic clock input to PLL circuit 60 is divided by 1 / n. The clock output from the frequency dividing circuit 61 is input to the counter circuit 64.
[0044]
The modulation circuit 62 modulates input data in synchronization with a clock signal described later. Usually, in order to represent the gradation of the laser, the lighting time within a unit time is controlled by PWM modulation. Therefore, in the present embodiment, it is assumed that PWM modulation (particularly digital PWM modulation) is performed. explain. For example, to PWM modulation input data A bit, the input data is converted into pulse width data of 2 ^A. here,
2 ^A = n (2)
The constant is determined so that The modulation circuit 62 generates pulse width data from the input data, and outputs the pulse width data to the output circuit 63 (see FIG. 7).
[0045]
The output circuit 63 outputs a PWM signal synchronized with the high frequency clock output from the PLL circuit 60 and a clock signal synchronized with the high frequency clock according to the pulse width data output from the modulation circuit 62. The PWM signal is output to the laser driving device 31, and the clock signal is output to the image processing unit (not shown) and the modulation circuit 62 (see FIGS. 8A, 8D, and 8E).
[0046]
The counter circuit 64 counts the clock (clock obtained by dividing the high frequency clock by 1 / n) output from the frequency dividing circuit 61 (see FIG. 8B). When the count value reaches the set value, the counter circuit 64 outputs a predetermined signal to the output circuit 63 (see FIGS. 8B and 8C). Here, the value set in the counter circuit 64 is a value determined according to the value obtained by the above equation (1).
[0047]
When the counter circuit 64 outputs the predetermined signal to the output circuit 63, the output circuit 63 performs an operation different from a normal operation. In the normal operation, one cycle (of a PWM signal and a clock signal) is generated by n high-frequency clocks, but when the predetermined signal is input, a PWM signal having a cycle different from the above cycle is generated. , And outputs a clock signal (see FIG. 8).
[0048]
Next, a specific configuration of the output circuit 63 will be described with reference to FIG. FIG. 9 is a block diagram showing a configuration of the output circuit 63 of FIG.
[0049]
As shown in FIG. 9, the output circuit 63 includes a modulation control unit 80, nine D-type flip-flops 81a to 81i, nine two-input AND circuits 82a to 82i, and two two-input selector circuits 83 and 84. , A 9-input OR circuit 86, and a 2-input OR circuit 87.
[0050]
The modulation circuit 62 modulates the input image data into 8-bit pulse width data. Each bit of the pulse width data is input to one of the inputs of two-input AND circuits 82a to 82i. Here, the same data is input to two-input AND circuits 82h and 82i.
[0051]
The flip-flops 81a to 81i output the input of the D terminal to the Q terminal at the rise of the high frequency clock (CLK). The outputs of the flip-flops 81a to 81i are connected to the other of the inputs of the two-input AND circuits 82a to 82i. At the same time, the flip-flops 81a to 81i are cascaded such that the output of the flip-flop 81a is connected to the input of the flip-flop 81b, and the output of the flip-flop 81b is connected to the input of the flip-flop 81c. The output of the flip-flop 81h is also connected to a two-input selector circuit 83 and a two-input selector circuit 84. The output of the flip-flop 81i is also connected to the two-input selector circuit 83.
[0052]
The outputs of the two-input AND circuits 82a to 82i are respectively connected to a nine-input OR circuit 86, and the output of the nine-input OR circuit 86 is output as a PWM signal. The two-input selector circuit 83 selects the outputs of the flip-flops 81h to 81i according to the output of the modulation control unit 80, and is connected to one of the inputs of the two-input OR circuit 87. The other input of the two-input selector circuit 84 is connected to GND. The two-input selector circuit 84 controls whether the output of the flip-flop 81h is input to the flip-flop 81i based on the output of the modulation control unit 80.
[0053]
The modulation control unit 80 switches the selection operation of the two-input selector circuits 83 and 84 according to the output of the counter circuit 64.
[0054]
A timing signal is input to the other input of the two-input OR circuit 87, and an output of the two-input OR circuit 87 is input to the flip-flop 81a.
[0055]
Next, the operation of the output circuit 63 will be described with reference to FIG. FIG. 10 is a timing chart showing an operation example of the output circuit 63 of FIG.
[0056]
A timing signal is input to the two-input OR circuit 87 in synchronization with the high-frequency clock (CLK) input to the flip-flops 81a to 81i. This timing signal is a signal having a width of one clock of the high frequency clock. As a result, one of the outputs of the shift register of the ring constituted by the flip-flops 81a to 81i is always "1". The modulation control unit 80 receives the output of the counter circuit 64 and controls the two-input selector circuits 83 and 84 so as to control the size of the ring-shaped shift register (ie, the number of flip-flops forming the ring-shaped shift register). Switch the operation. When one pixel is composed of eight high-frequency clocks (CLK), the output of the flip-flop 81h is selected by the two-input selector circuit 83, and GND is selected by the two-input selector circuit 84. When one pixel is composed of nine high-frequency clocks (CLK), the output of the flip-flop 81i is selected by the two-input selector circuit 83, and the output of the flip-flop 81h is selected by the two-input selector circuit 84. By these switching, "1" is output once as the output of the flip-flops 81a to 81i for the high frequency clock (CLK) of 8/9.
[0057]
Pulse width data is set in the two-input AND circuits 82a to 82i, and the pulse width data changes for each pixel (= 8 / 9CLK). Then, in each of the two-input AND circuits 82 a to 82 i, an AND operation is performed on the set data and “1” once per 8/9 high-frequency clocks (CLK). The AND outputs of the two-input AND circuits 82a to 82i are ORed. As a result of this OR operation, a PWM signal composed of 8/9 high-frequency clocks (CLK) is output.
[0058]
Although not shown, the same configuration is used, an image clock pattern is input to a portion corresponding to image data, and outputs of specific portions (for example, 81a and 81e) of flip-flops 81a to 81i are JK flip-flops. By inputting to the circuit, a clock signal composed of 8/9 high frequency clocks (CLK) can be output similarly to the PWM signal.
[0059]
As described above, as shown in FIG. 10, the number of components of one pixel is set to nine high-frequency clocks (CLK) at a specific position (writing position) within one cycle (image effective area), and at other times, eight high-frequency clocks (CLK) are used. By controlling so as to be the clock (CLK), the scanning lengths Xa and Xb on the surface of the photosensitive drum 11 are electrically corrected, and the scanning lengths Xa and Xb by the two laser beams can be made equal to each other. .
[0060]
In the present embodiment, the specific portion where the width of one pixel is changed is determined by the counter circuit 64, but may be determined by another timer means, for example.
[0061]
(2nd Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. FIG. 11 is a block diagram showing a configuration of an exposure control unit of the image forming apparatus according to the second embodiment of the present invention, FIG. 12 is a block diagram showing a configuration of the image signal timing control unit of FIG. 11, and FIG. It is a figure which shows typically the image before the scan length is corrected in 2nd Embodiment, and the image after the correction.
[0062]
In the first embodiment, the difference Xb-Xa in the scanning length on the surface of the photosensitive drum 11 is detected, and the number of high-frequency clocks that form one pixel at one specific location in one main scanning direction is increased. The correction is performed so as to eliminate the difference in the scanning length. However, the larger the value of the scanning length difference Xb-Xa is, the larger the increase number with respect to the number of high frequency clocks for correction is. This is because the proportion of dots formed by one laser beam that is periodically large is large, that is, the proportion of dots that are different in size from the dots formed by the other laser beam is large. This will lead to deterioration.
[0063]
Therefore, in the present embodiment, in order to reduce the pixel shift between the laser beams, the number of high-frequency clocks that are increased to correct the scanning length of one laser beam is limited, and the writing timing of the other laser beam is restricted. Use a shifting method. In order to realize this method, in the present embodiment, as shown in FIG. 11, the exposure control unit 10 is provided with a main scanning length difference detection circuit 101 and an image signal timing control unit 102. Here, the same blocks or members as those in the first embodiment are denoted by the same reference numerals, and description thereof will be simplified.
[0064]
The main scanning length difference detection circuit 101 detects a scanning length difference between the laser beams based on the detection signals of the BD sensors 36 and 37, and sends a correction amount corresponding to the detected value of the scanning length difference to the modulation unit 48. Send out. This correction amount is a set value for the counter circuit 64. When the scanning length difference exceeds a preset threshold value, the maximum value that does not cause image deterioration is sent as the correction amount.
[0065]
Further, the main scanning length difference detection circuit 101 determines a BD delay amount for delaying the capture of the output of the BD sensor 36 based on the detected scanning length difference and the correction amount, and sends the signal to the image signal timing control unit 102. Send out.
[0066]
As shown in FIG. 12, the image signal timing control unit 102 includes a selector 103, FIFOs (First In First Out memory) 105 and 106, and a BD delay circuit 104. An image signal is input to the selector 103, and the selector 103 switches the input image signal line by line and inputs the image signal to FIFOs (First In First Out memory) 105 and 106. The BD delay circuit 104 delays the capture of the output of the BD sensor 36 according to the BD delay amount sent from the main scanning length difference detection circuit 101. However, the output of the BD sensor 36 whose capture is delayed corresponds to the semiconductor laser whose scanning length is short, and the capture of the output of the BD sensor 36 to the other semiconductor laser is not delayed. The detection signal of the BD sensor 36 which is delayed or not delayed is input to the FIFOs 105 and 106, and is used for reading timing of an image signal. Then, an image signal is output from the FIFOs 105 and 106 based on the timing signal (the detection signal of the BD sensor 36 which is delayed or not delayed). The image signal from the FIFO 105 is input to a modulator for one semiconductor laser, and the image signal from the FIFO 106 is input to a modulator for the other semiconductor laser.
[0067]
Here, one of the semiconductor lasers 43 is referred to as LD1, and the other is referred to as LD2. In order to eliminate the difference in the scanning length of each laser beam on the photosensitive drum 11, the laser beam of LD2 shorter than the scanning length of the laser beam of LD1 is used. Consider a case where the scanning length is corrected while limiting the number of high-frequency clocks, and the capture of the output of the BD sensor 36 is delayed during scanning of the LD 2.
[0068]
For example, as shown in FIG. 13, when no correction is performed, it is assumed that an image 121 is formed on the photosensitive drum 11 by the LD 1 and an image 122 is formed on the photosensitive drum 11 by the LD 2. On the other hand, if the LD 2 having a short scanning length is corrected to increase the number of high frequency clocks forming one pixel at a predetermined position in the main scanning direction, an image 123 is obtained as a corrected image. Here, when the scanning length difference between LD2 and LD1 is large, this correction amount (set value for the counter circuit 64) is set to the maximum value, and the pixel shift is reduced by this correction, but it is still at the end of the image. Pixel shift remains. Therefore, if the capture of the detection signal of the BD sensor 36 is delayed in addition to the correction for increasing the number of high frequency clocks, the image 124 in which the pixel shift amount is dispersed can be obtained.
[0069]
As described above, in the present embodiment, the scanning length is corrected by changing the width of one pixel at a predetermined portion of one line, and the capture of the output of the BD sensor is delayed, thereby reducing the scanning length of each beam light. Differences and pixel shift amounts can be reduced, and image quality degradation can be reduced as much as possible.
[0070]
In each of the above embodiments, the configuration using two beams has been described, but it goes without saying that the same effect can be obtained with three or more beams.
[0071]
【The invention's effect】
As described above, according to the present invention, a difference in scan length between each of a plurality of beams is detected, and based on the detection result, a high-frequency clock constituting a main clock of a corresponding beam among the plurality of beams is detected. By controlling the writing position for changing the number, the scanning length by the corresponding beam is corrected, so that it is possible to suppress the deterioration of the image due to the difference in the scanning length by each of the plurality of beams without increasing the cost. it can.
[0072]
Further, according to the present invention, based on a result of detecting a difference between scan lengths of each of the plurality of beams, a timing of starting image formation of a corresponding beam among the plurality of beams is controlled, and each of the plurality of beams is controlled. Of the plurality of beams, the scanning length of the corresponding beam is corrected based on the result of detection of the difference between the scanning lengths. Image deterioration can be suppressed.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view schematically showing a configuration of an image forming apparatus according to a first embodiment of the present invention.
FIG. 2 is a plan view schematically showing a configuration of an exposure control unit 10 of FIG.
FIG. 3 is a side view schematically showing a configuration of an exposure control unit 10 of FIG.
FIG. 4 is a timing chart showing the output of each of the BD sensors 36 and 37 with respect to each laser beam of FIG.
FIG. 5 is a block diagram illustrating a configuration of a modulation unit 48 in FIG. 2;
6 is a timing chart of input / output signals of the frequency dividing circuit 61 in FIG.
FIG. 7 is a timing chart of input / output signals of the modulation circuit 62 of FIG. 5;
8 is a timing chart of input / output signals of the counter circuit 64 and the output circuit 63 of FIG.
FIG. 9 is a block diagram illustrating a configuration of an output circuit 63 of FIG. 5;
10 is a timing chart showing an operation example of the output circuit 63 of FIG.
FIG. 11 is a block diagram illustrating a configuration of an exposure control unit of an image forming apparatus according to a second embodiment of the present invention.
FIG. 12 is a block diagram illustrating a configuration of an image signal timing control unit in FIG. 11;
FIG. 13 is a diagram schematically illustrating an image before and after a scan length is corrected in a second embodiment of the present invention.
[Explanation of symbols]
10 Exposure Control Unit 11 Photosensitive Drum 31 Laser Drive Device 33 Polygon Mirror 43 Semiconductor Laser 48 Modulation Unit 60 PLL
61 frequency dividing circuit 62 modulation circuit 63 output circuit 64 counter circuit 80 modulation control units 81a to 81i flip-flops 82a to 82i two-input AND circuits 83 and 84 two-input selector circuit 869 nine-input OR circuit 87 two-input OR circuit 101 main scanning length Difference detection circuit 102 Image signal timing control section 103 Selector 104 BD delay circuits 105 and 106 FIFO

Claims (14)

An image forming apparatus having a multi-beam scanning optical system that scans a corresponding line with a plurality of beams,
Scanning length difference detecting means for detecting a difference in scanning length due to each of the plurality of beams,
A main clock including a plurality of high-frequency clocks having a predetermined frequency is generated as a write clock for each of the plurality of beams, and the main clock is configured according to a write position for each of the plurality of beams. Clock generation means for variably controlling the number of high-frequency clocks;
Based on the detection result of the scanning length difference detection means, by controlling the writing position for changing the number of high-frequency clocks constituting the main clock of the corresponding beam among the plurality of beams, the scanning length by the corresponding beam can be reduced. An image forming apparatus comprising: a correction unit configured to perform correction. The scanning length difference detecting unit includes a scanning start position detecting unit that detects a scanning start position of each of the plurality of beams, and a scanning end position detecting unit that detects a scanning end position of each of the plurality of beams. The scanning start position of each of the plurality of beams detected by the scanning start position detection unit and the scanning end position of each of the plurality of beams detected by the scanning end position detection unit. 2. The image forming apparatus according to claim 1, wherein a difference between the scanning lengths is detected. 3. The image forming apparatus according to claim 1, further comprising a high-frequency clock generating unit that generates the high-frequency clock from a basic clock, wherein the high-frequency clock is a clock that is an integral multiple of the basic clock. A multi-beam scanning optical system that scans a corresponding line with a plurality of beams, and a scanning start position detecting unit that detects a scanning start position of each of the plurality of beams, wherein the plurality of beams are detected by the scanning start position detecting unit. An image forming apparatus that starts image formation by each of the plurality of beams based on a detection result for each of
Scanning length difference detecting means for detecting a difference between scanning lengths due to each of the plurality of beams,
A first correction unit that controls a timing of starting image formation of a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detection unit;
An image forming apparatus comprising: a second correction unit configured to correct a scanning length of a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detection unit. 5. The image forming apparatus according to claim 4, wherein the first correction unit controls to delay a timing of starting image formation by a corresponding beam among the plurality of beams. 6. The image forming apparatus according to claim 4, wherein the first correction unit controls to delay a corresponding detection result among detection results of the plurality of beams by the scanning start position detection unit. . A main clock including a plurality of high-frequency clocks having a predetermined frequency is generated as a write clock for each of the plurality of beams, and the main clock is configured according to a write position for each of the plurality of beams. Clock generating means for variably controlling the number of high-frequency clocks,
The second correction unit, based on the detection result of the scanning length difference detection unit, by controlling the writing position to change the number of high-frequency clocks constituting the main clock of the corresponding beam among the plurality of beams, The image forming apparatus according to claim 4, wherein a scanning length by the corresponding beam is corrected. Scan end position detection means for detecting the scan end position of each of the plurality of beams,
The scanning length difference detection means, the scanning start position of each of the plurality of beams detected by the scanning start position detection means and the scanning end position of each of the plurality of beams detected by the scanning end position detection means, The image forming apparatus according to claim 4, wherein a difference in scanning length between each of the plurality of beams is detected based on the difference. 5. The image forming apparatus according to claim 4, further comprising a high-frequency clock generating unit configured to generate the high-frequency clock from a basic clock, wherein the high-frequency clock is a clock that is an integral multiple of the basic clock. A multi-beam scanning optical system that scans a corresponding line with a plurality of beams, and a main clock composed of a plurality of high-frequency clocks having a predetermined frequency is generated as a write clock for each of the plurality of beams, A scanning length control method for an image forming apparatus, comprising: a high-frequency clock generating unit configured to vary the number of high-frequency clocks included in the main clock according to a writing position for each of the plurality of beams.
A scanning length difference detecting step of detecting a difference in scanning length due to each of the plurality of beams,
Based on the detection result of the scanning length difference detection step, of the plurality of beams, by controlling a writing position for changing the number of high-frequency clocks constituting the main clock of the corresponding beam, the scanning length of the corresponding beam is controlled. A scan length control method for an image forming apparatus. A multi-beam scanning optical system that scans a corresponding line with a plurality of beams, and a scanning start position detecting unit that detects a scanning start position of each of the plurality of beams, wherein the plurality of beams are detected by the scanning start position detecting unit. A scanning length control method of an image forming apparatus that starts image formation by each of the plurality of beams based on a detection result for each of the plurality of beams,
A scanning length difference detecting step of detecting a difference between scanning lengths by each of the plurality of beams,
A first correction step of controlling a timing of starting image formation of a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detection step;
A second correcting step of correcting a scanning length of a corresponding beam among the plurality of beams based on a detection result of the scanning length difference detecting means. 12. The scanning length control method for an image forming apparatus according to claim 11, wherein in the first correction step, control is performed such that a timing of starting image formation by a corresponding beam among the plurality of beams is delayed. 12. The image forming apparatus according to claim 11, wherein, in the first correction step, of the detection results of the plurality of beams by the scanning start position detection unit, a corresponding detection result is controlled to be delayed. Scan length control method. The image forming apparatus generates a main clock composed of a plurality of high-frequency clocks having a predetermined frequency as a write clock for each of the plurality of beams, and generates a main clock in accordance with a write position for each of the plurality of beams. Clock generating means for variably controlling the number of high-frequency clocks constituting the main clock,
In the second correction step, based on the detection result of the scanning length difference detection step, by controlling the writing position to change the number of high-frequency clocks constituting the main clock of the corresponding beam among the plurality of beams, The method according to claim 11, wherein the scanning length is corrected by the corresponding beam.

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