JP4827504B2 - Optical scanning device and image forming apparatus using the same - Google Patents

Description

  The present invention relates to an optical scanning device in an image forming apparatus such as a laser printer, a digital copying machine, and a facsimile machine.

  Image forming apparatuses such as laser printers, digital copiers, and facsimile machines scan light in the main scanning direction on a surface to be scanned such as a photosensitive member by scanning means such as a polygon mirror, and also scan the surface to be scanned in the sub-scanning direction. A configuration is used in which an optical scanning device is used to write an image for each line on the photosensitive member. In such an optical scanning device, in order to accurately control the main scanning position of the beam lighting on the surface to be scanned, it is necessary to manage the start timing and end timing of the main scanning writing and maintain the same magnification on the surface to be scanned. There is.

  Therefore, the light beam is detected by the light beam detection means at a plurality of locations on the main scanning line, and the time interval during which the light beam passes between these light beam detectors is measured by a predetermined clock count. It has been proposed to perform a magnification correction by calculating a correction amount from a preset reference count value (see, for example, Patent Document 1). This Patent Document 1 is provided with beam light detection means on the writing start side and the end side, and the passing time between two points is measured by the count number of a predetermined clock so that it matches the reference count number stored in advance. It has been proposed to maintain the same magnification by correcting the pixel clock frequency.

In addition, as a conventional technique for performing synchronization detection of a laser beam emitted from a laser light source with high accuracy, for example, as shown in Patent Document 2, it has been proposed to adjust the position of a synchronization detection sensor. According to this patent document 2, the low level time of the sensor detection signal output from the synchronization detection sensor is measured, and the position of the synchronization detection sensor is controlled by moving the movable stage in the sub-scanning direction based on the measurement result. It is disclosed that a detection signal is stably detected with high accuracy.
JP-A-7-131616 JP 2002-139686 A

  However, as disclosed in Patent Document 1, a photosensor IC or the like is used as the light beam detecting means, but these sensor means have characteristics in which output delay differs depending on the amount of incident light. For this reason, when there is variation in the amount of beam incident on each light beam detecting means, there arises a problem that even if correction is performed, a deviation from the target magnification occurs. Further, in Patent Document 2, the synchronization detection sensor is moved relative to the housing in the sub-scanning direction to adjust the position of the synchronization detection laser beam, and thus includes a mechanism element.

  The main object of the present invention is to control the light beam emission amount so that the amount of light where the light beam reaches each light beam detection means is constant, so that the output delay of the light beam detection means is not taken into consideration. An object of the present invention is to provide an optical scanning device capable of accurately performing magnification correction.

In order to solve the above problems, the present invention adopts the following configuration.
Light source means for generating a light beam, a light quantity setting signal generating circuit for generating a light quantity setting signal for setting a light quantity emitted from the light source means, deflection scanning means for deflecting and scanning the light beam from the light source means, and the deflection scanning A plurality of light beam detecting means for detecting the light beam deflected by the means at a plurality of locations on the same scanning line; and a measuring means for measuring a time interval during which the light beam passes between the plurality of light beam detecting means. An optical scanning device that performs magnification correction based on the measured value and a preset setting value, wherein the light beam detecting means includes a plurality of regions obtained by dividing the scanning width of the light beam into a plurality of regions. The write start side sensor means provided on the write start side and the write end side sensor means provided on the write end side, and the light emission amount of the light beam is changed in a plurality of regions in the scanning direction. Make Has a査光amount varying means, a storage means for storing a respective beam transmittance to the light receiving surface of the write end side sensor unit and the writing start side sensor means from the light beam emitting points of the light source means From the light source means to the write start side sensor means and the write end side sensor means so that the respective light amounts incident on the write start side sensor means and the write end side sensor means are constant. The amount of light at the light beam emission point of the light source means is controlled in accordance with the stored beam transmittance .

A light source unit that generates a light beam; a light amount setting signal generation circuit that generates a light amount setting signal that sets an emitted light amount of the light source unit; a deflection scanning unit that deflects and scans the light beam from the light source unit; A plurality of light beam detecting means for detecting a light beam deflected by the deflection scanning means at a plurality of locations on the same scanning line, and a time interval at which the light beam passes between the plurality of light beam detecting means is a pixel clock count An optical scanning device that performs magnification correction by controlling the frequency of the pixel clock so that the measured count value of the pixel clock coincides with a preset reference count value a is, the light beam detecting means, said light beam writing start side sensor means provided to the write start side of the plurality of regions within the scanning width is divided into a plurality of the write Consists of a writing end side sensor means provided on the completion side, the scanning light amount changing means for changing the light emission amount of the light beam in a plurality of regions in the scanning direction, the write start from the light beam emitting points of the light source means a storage means for storing the respective beam transmittance of the side sensor means to the light receiving surface of the write end side sensor unit, and is incident on the writing end side sensor unit and the writing start side sensor means The light beam of the light source means according to the stored beam transmittances from the light source means to the write start side sensor means and the write end side sensor means so that the respective beam light amounts are constant. The light amount at the emission point is controlled .

A plurality of light source means for generating a light beam; a light quantity setting signal generating circuit for generating a light quantity setting signal for setting an emitted light quantity of each light source means; and a deflection scanning means for deflecting and scanning the light beam from each light source means. A plurality of light beam detecting means for detecting the light beam deflected by the deflection scanning means at a plurality of locations on the same scanning line, and a time interval at which the light beam passes between the plurality of light beam detecting means as a pixel clock. Measuring means for measuring the number of counts, and correcting the magnification by controlling the frequency of the pixel clock so that the measured count value of the pixel clock matches a preset reference count value. an optical scanning apparatus, the light beam detecting means, said plurality of light source means provided for each light beam, and the light beam of the plurality of regions formed by dividing the inside of the scanning width in a plurality of In consists of a writing end side sensor means provided on the writing start side sensor means and the write end side provided on the writing start side, wherein the light emission amount of the plurality of light beams at a plurality of regions in the scanning direction a scanning light amount changing means for changing for each light beam, each beam transmittance from each of the light beam emitting point to the light receiving surface of the writing start side sensor unit and the write end side sensor means of said plurality of light source means Storing means for each light beam, and the amount of light incident on each of the write start side sensor means and the write end side sensor means provided for each light beam is constant. Thus, for each light beam, at the light beam emission point of the light source means according to the respective stored beam transmittances from the light source means to the write start side sensor means and the write end side sensor means. of A configuration to control the amount.

  According to the present invention, ideal magnification correction can be performed without considering the output delay of the light beam detecting means. Furthermore, high-precision color matching is possible even in the configuration of a full-color image forming apparatus having a plurality of light sources or the configuration of a monochrome or multi-beam image forming apparatus.

  Further, since the amount of light is variable at each scanning position of the plurality of light beam detection means, magnification correction can be performed with a simple configuration without considering the output delay of the light beam detection means. Furthermore, it is possible to convert the light quantity setting data into a light quantity setting signal with a simple configuration or low cost configuration, and with a simple configuration, accurate magnification correction can be performed without considering the output delay of the light beam detection means. Can be implemented.

  An optical scanning device of an image forming apparatus according to an embodiment of the present invention will be described in detail below with reference to FIGS. FIG. 1 is a perspective view showing a basic configuration of an optical scanning device of an image forming apparatus and an optical path of a light beam according to an embodiment of the present invention. FIG. 2 is a timing chart for explaining the necessity of correcting the magnification of a single light source according to this embodiment. FIG. 3 is a diagram showing the relationship between the incident laser power and the sensor output timing in the light beam detection means according to this embodiment.

  FIG. 4 is a timing chart showing signal mode examples of each light beam detection signal when the light beam passes through the writing start side sensor and the writing end side sensor in the light beam detecting means according to the present embodiment. FIG. 5 is a timing chart showing a signal mode example of each light beam detection signal when the received light amount of the writing start side sensor and the writing end side sensor in the light beam detecting means according to the present embodiment is controlled to be constant.

  FIG. 6 shows a configuration in which the light quantity setting signal generating means according to the present embodiment is provided with scanning light quantity variable means for setting a light quantity setting signal for each divided area within the scanning width, and the incident light quantity to the light beam detecting means is controlled to be constant. FIG. FIG. 7 is a diagram showing a configuration for controlling the amount of light when the incident light amount on the sensor light receiving surface is constant when the light beam is detected by the writing start side sensor and the writing end side sensor according to the present embodiment. FIG. 8 is a diagram illustrating a configuration example in which a D / A converter is used in the light amount setting signal generation circuit according to the present embodiment. FIG. 9 is a diagram showing a configuration example in which a pulse width modulation circuit and a low-pass filter circuit are used in the light amount setting signal generation circuit according to the present embodiment.

  A basic configuration of the optical scanning device of the image forming apparatus according to the embodiment of the present invention shown in FIG. 1 will be described below. The optical scanning device of the image forming apparatus according to the present embodiment includes an image data writing control unit 1, a light source driving unit 2, a light source 3, optical systems 4, 5, 6, a polygon mirror 7, and an optical system 8. , 9, dust-proof glass 10, scanned surface 11, writing disclosure side light beam detection means 20, and writing end side light beam detection means 21. In FIG. 1, when a lighting control signal 26 and a light amount setting signal 27 are input from the writing control unit 1 to the light source driving means 2, a driving signal is supplied to a laser diode (LD) 3 or the like as the light source means. Control the lighting. The laser light emitted from the LD 3 is shaped through the collimator lens 4 and the aperture 5, passes through the cylinder lens 6, and then the incident laser light is deflected and scanned by the polygon mirror 7 for rotational deflection.

  The polygon mirror 7 is rotationally driven at a predetermined rotational speed by a polygon motor (not shown). The laser beam reflected by the polygon mirror passes through the fθ lens 8, is reflected by the folding mirror 9, passes through the dust-proof glass 10, and is condensed on the scanned surface 11. When a light beam is incident on the plurality of light beam detection means 20 and 21 arranged on the scanned surface 11, light beam detection signals 22 and 23 corresponding to the scanning timing are output.

  FIG. 1 shows a configuration example in which the light beam detecting means 20 and 21 are arranged on the write start side and the write end side. The write start side light beam detection signal 22 and the write end side light beam detection signal 23 are shown. Is output. The time interval between the plurality of light beam detection signals 22 and 23 is measured by counting the pixel clock, and the writing pixel frequency is changed so that the count value matches a preset reference count value. , Correct the magnification.

Next, the execution of magnification correction for a single light source will be described with reference to FIG. FIG. 2 is a timing chart for explaining execution of magnification correction of a single light source. The writing start side detection signal 22 becomes active when the beam passes through the light beam detecting means 20 attached to the writing start side, and writing ends when the beam passes through the writing end side light beam detecting means 21. The start side detection signal 23 becomes active. At this time, it is assumed that the magnification of the target light source is matched and the count value becomes N0 when counting between the light beam detection means 20 and 21 by the pixel clock of the frequency f0.
Next, when the magnification has changed due to the temperature rise of the optical element portion, particularly the temperature rise of the fθ lens 8 (see FIG. 1) while the light beam scanning is repeated, it is counted by the writing clock of the frequency f0. Suppose that the count value at that time becomes N ′. The frequency f ′ of the write clock for correcting the magnification at this time is
f ′ = (N0 / N ′) × f0
If f ′ is newly set as a write clock and an image is formed, an image with a suitable magnification can be obtained. As described above, in the optical scanning device, a plurality of light beam detecting means are arranged on the same surface to be scanned, the interval between the respective light beam detecting means is measured, and the pixel clock frequency is controlled to perform magnification correction. .

  Photosensor ICs and the like are generally used as the light beam detection means 20 and 21, but these photosensor means have characteristics that output timing differs depending on the amount of incident light. FIG. 3 shows an example of the relationship between incident laser power and sensor output timing. In the case of the sensor having the characteristics shown in the figure, when the amount of beam incident on the sensor is 0.4 mW, the sensor output is delayed by about 40 ns when the light amount is 0.3 mW (two black circles on the curve shown in FIG. 3). Refer to the timing of occurrence). As described above, the sensor output timing with respect to the incident light amount varies depending on the characteristics of the sensor. Therefore, when there is a variation in the light amount of light incident on a plurality of light beam detection units (for example, reference numerals 20 and 21 in the example of FIG. 1), the magnification Deviation occurs. In particular, in the case of a configuration having a plurality of light sources such as a full-color image forming apparatus or a multi-beam image forming apparatus, color misregistration and image misregistration occur.

  The variation in the amount of light incident on the light beam detector means that even if the amount of light beam at the light source emission point is all kept constant, the synchronization detection means (configuration example of FIG. 1) from the beam emission point of the light source means (for example, LD3). Therefore, since the light beam transmittance to the light receiving surface of the light beam detecting means 20, 21) varies, the light amount on the sensor light receiving surface varies.

  FIG. 4 shows an example of a timing chart of each of the light beam detection signals 22 and 23 when passing through the writing start side sensor 20 and the writing end side sensor 21. The amount of light at the emission point of the light source is P1 (= P2). If the transmittance to the write start side sensor light receiving surface is A, the light amount on the write start side light receiving surface is P1 × A. On the other hand, the amount of light at the exit point on the writing end side is P2 (= P1). If the transmittance to the writing end side light receiving surface is B, the light amount on the writing end side light receiving surface is P2. XB.

  FIG. 4 shows an example in which the light intensity on the sensor light-receiving surface on the writing start side is different from that on the writing side (when (P1 × A) and (P2 × B) are not equal). Since the amount of beam incident on the light beam detecting means is different for each writing end side, if magnification correction is performed as it is, a deviation from the ideal magnification occurs. That is, if P1 × A and P2 × B are not equal, the sensor output timings t1 and t2 are shifted from the characteristics shown in FIG. 3, and if magnification correction is performed based on this timing shift, accurate magnification correction cannot be achieved. .

  FIG. 5 shows a timing chart of each light beam detection signal when the sensor received light amount on the writing start side and the writing end side is controlled to be constant. The amount of light at the emission point of the light source is P1 (> P2), and when the transmittance to the start-side sensor light-receiving surface is A, the light amount at the start-side light-receiving surface is P1 × A. On the other hand, the light amount at the exit point on the end side is P2 (<P1). If the transmittance to the sensor light receiving surface is B, the light amount on the light receiving surface is P2 × B. FIG. 5 shows an example of the case where the light amount on the sensor light-receiving surfaces on the start side and the end side is controlled to be constant (when P1 × A = P2 × B). In each case, the amount of light incident on the light beam detecting means is also constant, so that when magnification correction is performed in this state, it is possible to correct to an ideal magnification. That is, when P1 × A and P2 × B are equal, there is no deviation between the sensor output timings t1 and t2 from the sensor characteristics shown in FIG.

  4 and 5 show timing charts in the case of a single light source. However, when a magnification shift occurs in a configuration having a plurality of light sources such as a full-color image forming apparatus or a multi-beam image forming apparatus, color misregistration occurs. And image displacement will occur. For this reason, it is desirable to control the amount of incident light on each sensor light receiving surface to be constant regardless of the configuration of a single light source or a plurality of light sources.

  Next, FIG. 6 shows another configuration example of the light amount setting signal generating means in the writing control unit according to the present embodiment. Incidentally, in the configuration examples shown in FIGS. 4 and 5, the light amount setting signals corresponding to P1 and P2 are generated on the writing start side and the writing end side. The writing control unit 1 shown in FIG. 6 mainly includes a light amount setting signal generation unit 60, a pixel clock generation unit 61, and a lighting / extinguishing signal generation circuit 62. The light amount setting signal generation unit 60 includes: It comprises a scanning light quantity varying means 66, a light quantity setting signal generating circuit 68, and a zoom circuit 1 / α69. The pixel clock generator 61 generates a pixel clock by correcting the magnification 63 of the pixel clock 64 based on the write start side light beam detection signal 22 and the write end side light beam detection signal 23. Further, the amount of emitted light can be varied by controlling the zoom circuit 69 by the transmittance data 71 from the beam transmittance storage means 70 provided separately from the writing controller 1.

  As in the block configuration shown in FIG. 6, division area setting data 65 for dividing the light beam scanning width into a predetermined number is input to the light quantity setting signal generating means 60, and each division area (division shown in FIG. 7) is input. A scanning light amount varying means 66 for setting the light amount setting signal 27 for each area) is provided, and the light amount at the sensor scanning position is made variable (the scanning light amount varying means 66 receives the divided area setting data and outputs it). The light amount setting signal generation circuit 68 is controlled by the divided area setting signal 67, and the light amount setting signal for each divided area is output from the light amount setting signal generation circuit 68). By controlling the amount of emitted light according to the transmittance data 71, the amount of incident light on each light beam detecting means light receiving surface can be controlled to be constant.

  Here, the beam transmittance storage means 70 may be configured to store the transmittance for each light beam detection means. Further, the beam transmittance storage means 70 may be configured to store the transmittance for each light beam. Further, in the image forming apparatus having the storage means for storing the beam transmittance from the beam emission point of the plurality of light source means 3 to the light receiving surface of the light beam detection means, the storage means 70 is arranged in a writing unit including an optical element. Alternatively, it may be arranged on the writing control unit 1 or other main body side.

  Since the beam transmittance is greatly influenced by optical elements such as the polygon mirror 7, the fθ lens 8, the folding mirror 9, and the dust-proof glass 10 that are provided in the writing unit, the storage means 70 that stores the beam transmittance is also written. By arranging in the unit, when replacing the writing unit for maintenance or the like, it is only necessary to read out the transmittance data specific to the writing unit from the storage means 70, so that the maintenance becomes easy. On the other hand, when the storage means 70 for storing the beam transmittance is also arranged outside the writing unit, it is necessary to reset the writing unit-specific transmittance data in the storage means when replacing the writing unit for maintenance or the like. .

  FIG. 7 shows an example in which the incident light quantity on the light receiving surface of the sensor is constant for the case where the light beam is detected at two points on the writing start side and the writing end side. FIG. 7 is a chart when the scanning area is divided into 11 areas from area 0 to area 10. Of these divided areas, “area 0” corresponding to the timing of passing through the writing start side sensor means, The amount of light with “area 10” corresponding to the timing of passing through the writing end side sensor means is controlled. The light amount control is not limited to “area 0” and “area 10”, and may be configured such that the light amount control can be performed for all areas.

  At this time, if the light amount at the emission point of the light source in “area 0” is P1, and the transmittance to the sensor light receiving surface is A, the light amount on the light receiving surface is P1 × A. On the other hand, the light quantity at the emission point of the light source in “area 10” is P2, and when the transmittance to the sensor light receiving surface is B, the light quantity on the light receiving surface is P2 × B. Here, by storing the transmittances A and B in the beam transmittance storage means 70 shown in FIG. 6 in advance, P1 and P2 are determined so that P1 × A = P2 × B. At this time, the amount of light incident on the sensor means (corresponding to the light beam detection signals 20 and 21 in the example of FIG. 1) is equal for each of the writing start side and the writing end side. The interval can be accurately measured, and ideal magnification correction can be performed.

  As described above, the sensor means for detecting the light beam has a characteristic that the output timing differs depending on the amount of incident light. However, by making the amount of light incident on the light beam detecting means constant, the interval between the sensors is accurately measured. It becomes possible. With this configuration, ideal magnification correction can be performed, and with a configuration such as a full-color image forming apparatus having a plurality of light sources, high-precision color matching is possible. Even in monochrome, highly accurate alignment is possible in the configuration of the multi-beam image forming apparatus.

  In addition, by setting the light amount setting signal 27 shown in FIGS. 1 and 6 to a voltage value that is proportional to the laser light amount, the light amount control can be easily performed with a simple configuration with respect to the light amount control.

  FIG. 8 shows a configuration example in which a DA converter is used for the light quantity setting signal generation circuit 68 shown in FIG. When the light amount setting data 25 of the digital signal is input, a voltage value proportional to the laser light amount is output, so that the light amount setting data 25 is converted into a light amount setting signal with a simple structure for light amount control. It becomes possible to control the light quantity of the beam at the sensor passage timing.

  FIG. 9 is a diagram showing another configuration example of the light quantity setting signal generation circuit 68 shown in FIG. 6 including a pulse width modulation circuit 90 and a low-pass filter 91. When the digital signal light quantity setting data 25 is input to the pulse width modulation circuit 90, a PWM signal having a duty corresponding to the laser light quantity is generated. The PWM signal is smoothed by the low-pass filter 91 and outputs a voltage value proportional to the laser light quantity. As shown in FIG. 9, the light quantity setting signal generation circuit 68 is configured by the pulse width modulation circuit 90 and the low-pass filter 91, thereby converting the light quantity setting data 25 into the light quantity setting signal with a simple and low-cost configuration for the light quantity control. This makes it possible to control the amount of beam light at the sensor passage timing. In this configuration example, the light amount setting signal is a voltage value, but may be a current value.

  As described above, the optical scanning device according to the embodiment of the present invention has the following configuration, and further has a function or an action. That is, a light source unit that generates a light beam, a generation circuit that generates a light amount setting signal for setting the light amount of the light source unit, a deflection scanning unit that deflects and scans the light beam from the light source unit, and a light source unit that is turned on and off A generation circuit for generating an on / off control signal, a plurality of light beam detection means for detecting a light beam deflected by the deflection scanning means at a plurality of locations on the same main scanning line, and a light beam between these light beam detection means An optical scanning device that calculates a correction amount from a count result and a preset reference count value, and executes magnification correction. Scanning light quantity variable means for changing the light emission amount of the light beam in the scanning direction, and memory for storing the beam transmittance from the beam emitting point of the light source means to the light receiving surface of the light beam detecting means And a means for controlling the light quantity setting signal in accordance with the beam transmittance stored in advance, and the light beam emission amount is set so that the light quantity at which the light beam reaches each light beam detecting means is constant. By controlling, magnification correction can be performed accurately without considering the output delay of the light beam detection means.

  Further, in the configuration having a plurality of light source means, if there is a variation in the amount of light incident on the light beam detection means from each light source means, a deviation in magnification occurs for each light source. In particular, in the configuration of a full-color image forming apparatus or the like, color misregistration occurs due to this magnification shift. Therefore, in the present embodiment, a light source unit that generates a plurality of light beams, a generation circuit that generates a light amount setting signal for setting the light amount of each light source unit, and a deflection scanning unit that deflects and scans the light beam from each light source unit And a generation circuit for generating an on / off control signal for controlling on / off of each light source means, and a plurality of light beam detecting means for detecting each light beam deflected by the deflection scanning means at a plurality of locations on the same main scanning line, A means for measuring a time interval at which the light beam passes between the light beam detecting means by a predetermined clock count, and calculating a correction amount from the count result and a preset reference count value, In an optical scanning device that performs magnification correction, a scanning light amount variable unit that changes the amount of light emitted from a plurality of light beams in the scanning direction, and each light beam detection unit from a beam emission point of each light source unit Storage means for storing the beam transmittance up to the light receiving surface, and means for controlling the light quantity setting signal in accordance with the previously stored beam transmittance, where each light beam reaches each light beam detection means. By controlling the amount of light beam emission so that the amount of light is constant, the output delay of the light beam detection means is taken into account even in configurations such as a full-color image forming apparatus having a light source means for each color and a multi-beam monochrome image forming apparatus. Even without this, it is possible to accurately carry out magnification correction on the surface to be scanned, and to eliminate magnification deviation for each light source.

  The scanning light amount varying means is configured by control means for dividing the beam scanning width into a predetermined number and controlling a light amount setting signal for each divided region, and the light amount setting signal for each divided region. By switching, the amount of light is variable at each scanning position of the plurality of light beam detection means, so that magnification correction can be accurately performed with a simple configuration without considering the output delay of the light beam detection means. Is.

  Also, by making the light quantity setting signal a current value proportional to the laser light quantity, the light quantity control can be controlled with a simple configuration for the light quantity control, and the output of the light beam detection means with a simple configuration. The magnification can be accurately corrected without considering the delay. Furthermore, by making the light quantity setting signal a voltage value proportional to the laser light quantity, it is possible to control the light quantity with a simple configuration for the light quantity control, and the output of the light beam detecting means with a simple configuration. The magnification can be accurately corrected without considering the delay.

  In addition, the light quantity setting signal is converted into a light quantity setting signal with a simple structure by using a D / A converter as a means for generating a voltage value corresponding to the light quantity setting signal, with the light quantity setting signal as a voltage value. The magnification correction can be accurately performed with a simple configuration without considering the output delay of the light beam detection means, and the light amount setting signal is a voltage value. As a configuration, the means for generating a voltage value corresponding to the light quantity setting signal is constituted by a pulse width modulation means and a low-pass filter (LPF) for smoothing the output from the pulse width modulation means, thereby reducing the cost. It is possible to convert the light quantity setting data into the light quantity setting signal with the configuration, and with a simple configuration, the magnification correction can be performed accurately without considering the output delay of the light beam detection means. Those that can be performed.

1 is a perspective view showing a basic configuration of an optical scanning device of an image forming apparatus and an optical path of a light beam according to an embodiment of the present invention. It is a timing chart for demonstrating the implementation necessity of the magnification correction of the single light source regarding this embodiment. It is a figure which shows the relationship between the incident laser power and sensor output timing in the light beam detection means regarding this embodiment. It is a timing chart which shows the signal mode example of each light beam detection signal when a light beam passes the writing start side sensor and writing end side sensor in the light beam detection means regarding this embodiment. It is a timing chart which shows the example of a signal mode of each light beam detection signal in case the sensor light-receiving amount of the writing start side sensor and the writing end side sensor in the light beam detection means regarding this embodiment is controlled constant. It is a figure which shows the structure which provides the light quantity setting signal generation means regarding this embodiment with the scanning light quantity variable means which sets a light quantity setting signal for every divided area within a scanning width, and controls the incident light quantity to a light beam detection means uniformly. . It is a figure which shows the structure which controls the light quantity when the incident light quantity in a sensor light-receiving surface is made constant when detecting a light beam with the writing start side sensor and writing end side sensor regarding this embodiment. It is a figure which shows the structural example which uses a D / A converter for the light quantity setting signal generation circuit regarding this embodiment. It is a figure which shows the structural example which uses a pulse width modulation circuit and a low-pass filter circuit for the light quantity setting signal generation circuit regarding this embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Write control part, 2 ... Light source drive means, 3 ... Laser diode (light source means), 4 ... Collimating lens, 5 ... Aperture, 6 ... Cylinder lens, 7 ... Polygon mirror, 8 ... f (theta) lens, 9 ... Folding mirror DESCRIPTION OF SYMBOLS 10 ... Dust-proof glass, 11 ... Scanned surface, 20 ... Write start side light beam detection means, 21 ... Write end side light beam detection means, 22 ... Write start side light beam detection signal, 23 ... Write end Side light beam detection signal, 24 ... image data, 25 ... light quantity setting data, 26 ... light on / off control signal, 27 ... light quantity setting signal, 60 ... light quantity setting signal generating means, 61 ... pixel clock generator, 62 ... light on / off signal Generation circuit 63... Magnification correction unit 64. Pixel clock 65. Divided area setting data 66. Scanning light quantity variable means 67. Divided area setting signal 68. ... zoom circuit, 70 ... beam transmission rate storage unit, 71 ... transmission data, 80 ... D / A converter, 90 ... pulse width modulation circuit, 91 ... LPF circuit

Claims (9)

Light source means for generating a light beam, a light quantity setting signal generation circuit for generating a light quantity setting signal for setting a light quantity emitted from the light source means, deflection scanning means for deflecting and scanning the light beam from the light source means, and the deflection scanning A plurality of light beam detecting means for detecting the light beam deflected by the means at a plurality of locations on the same scanning line; and a measuring means for measuring a time interval during which the light beam passes between the plurality of light beam detecting means. An optical scanning device that performs magnification correction based on the measured value and a preset setting value,
The light beam detecting means includes a write start side sensor means provided on the write start side and a write end provided on the write end side in a plurality of areas obtained by dividing the scanning width of the light beam into a plurality of areas. Side sensor means,
A scanning light amount variable means for changing the light emission amount of the light beam in a plurality of regions in the scanning direction, and from a light beam emission point of the light source means to a light receiving surface of the writing start side sensor means and the writing end side sensor means. Storage means for storing each beam transmittance,
From the light source means to the write start side sensor means and the write end side sensor means so that the respective beam amounts incident on the write start side sensor means and the write end side sensor means are constant. An optical scanning device characterized in that the amount of light at the light beam emission point of the light source means is controlled in accordance with each stored beam transmittance . Light source means for generating a light beam, a light quantity setting signal generation circuit for generating a light quantity setting signal for setting a light quantity emitted from the light source means, deflection scanning means for deflecting and scanning the light beam from the light source means, and the deflection scanning A plurality of light beam detecting means for detecting a light beam deflected by the means at a plurality of locations on the same scanning line, and a time interval during which the light beam passes between the plurality of light beam detecting means by a count number of pixel clocks An optical scanning device that performs magnification correction by controlling the frequency of the pixel clock so that the measured count value of the pixel clock coincides with a preset reference count value. And
The light beam detecting means includes a write start side sensor means provided on the write start side and a write end provided on the write end side in a plurality of areas obtained by dividing the scanning width of the light beam into a plurality of areas. Side sensor means,
A scanning light amount variable means for changing the light emission amount of the light beam in a plurality of regions in the scanning direction, and from a light beam emission point of the light source means to a light receiving surface of the writing start side sensor means and the writing end side sensor means. Storage means for storing each beam transmittance,
From the light source means to the write start side sensor means and the write end side sensor means so that the respective beam amounts incident on the write start side sensor means and the write end side sensor means are constant. An optical scanning device characterized in that the amount of light at the light beam emission point of the light source means is controlled in accordance with each stored beam transmittance . A plurality of light source means for generating a light beam, a light amount setting signal generating circuit for generating a light amount setting signal for setting the amount of light emitted from each light source means, a deflection scanning means for deflecting and scanning the light beam from each of the light source means, A plurality of light beam detecting means for detecting a light beam deflected by the deflection scanning means at a plurality of locations on the same scanning line, and a time interval at which the light beam passes between the plurality of light beam detecting means is counted by a pixel clock. An optical scanning unit that performs magnification correction by controlling the frequency of the pixel clock so that the measured count value of the pixel clock coincides with a preset reference count value. A device,
The light beam detecting means is provided for each light beam of the plurality of light source means, and a writing start side provided on a writing start side in a plurality of areas obtained by dividing the scanning width of the light beam into a plurality of areas. The sensor means and the writing end side sensor means provided on the writing end side,
A scanning light amount variable means for changing the light emission amounts of the plurality of light beams for each of the light beams in a plurality of regions in a scanning direction, the writing start side sensor means from the light beam emission points of the plurality of light source means, and the each beam transmittance to the light receiving surface of the write end side sensor means has a memory means for storing for each of the light beam,
Start writing from the light source means for each light beam so that the amount of light incident on the writing start side sensor means and the writing end side sensor means provided for each light beam is constant. An optical scanning device characterized in that the light quantity at the light beam emission point of the light source means is controlled in accordance with the stored beam transmittances from the side sensor means to the writing end side sensor means . In claim 1, 2 or 3,
The scanning light amount variable means is configured to change the light amount setting signal from the light amount setting signal generation circuit for each of the divided regions based on an input for dividing the scanning width of the light beam into predetermined regions. An optical scanning device that controls the light quantity setting signal generation circuit. In claim 1, 2 or 3,
The optical scanning device according to claim 1, wherein the light amount setting signal is a voltage value proportional to a laser light amount of a laser as the light source means. In claim 1, 2 or 3,
An optical scanning device characterized in that the light quantity setting signal is a current value. In claim 5,
An optical scanning device characterized in that the light amount setting signal generation circuit for outputting the light amount setting signal as a voltage value uses a D / A converter that receives the light amount setting data of a digital signal and outputs the voltage value. In claim 5,
The light amount setting signal generation circuit that outputs the light amount setting signal as a voltage value receives a light amount setting data of a digital signal and outputs a pulse width modulation circuit that outputs a pulse of a duty corresponding to the laser light amount, and smoothes the output pulse An optical scanning device using a low-pass filter circuit.   An image forming apparatus comprising the optical scanning device according to any one of claims 1 to 8.

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