JPH11160636A - Horizontal synchronizing signal detecting circuit and optical scanning device using it, and image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stable horizontal synchronizing signal detecting circuit by adding control to a reference voltage control circuit from a CPU to eliminate malfunction of a horizontal synchronizing signal caused by changes in light quantity. SOLUTION: This horizontal synchronizing signal detecting circuit is provided with a laser driving circuit 1 for making a laser diode 2 emit a light flux based on a video signal 10 transmitted from an upper device, a light quantity detecting sensor 4 for detecting light quantity of the emitted light flux, and a light quantity control circuit 5 for controlling the laser driving circuit 1 based on the signal from the light quantity detecting sensor 4 and keeping the light quantity from the laser diode 2 constant. Moreover, it is provided with a synchronization sensor 3 for detecting a scanning start position for specifying a position for the emitted light flux to form an image, a comparator 6 outputting an optical signal of the emitted light flux detected by the synchronization sensor 3 as a horizontal synchronizing signal, and a reference voltage control circuit 8 outputting a reference voltage to the comparator 6 based on a signal from a CPU 9 managing the control of the whole circuit.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a horizontal synchronizing signal detecting circuit, a scanning optical device and an image forming apparatus using the same.

[0002]

2. Description of the Related Art In laser printers, facsimile machines, digital copiers, plate making machines and the like, image forming apparatuses for optically writing an image on an image surface by laser light, etc., generally use a laser scanning optical apparatus. According to this laser scanning optical device, the laser light emitted from the light emitting unit is modulated by the image information signal, and the laser light is repeatedly deflected to a certain angle, so that the image plane (photosensitive drum surface) is main-scanned. The image plane corresponding to the image information signal is written on the image plane by performing sub-scanning by moving the image plane at a constant speed in a direction perpendicular to the main scanning direction. As a conventional technique employing this kind of laser scanning optical device, there are an optical scanning device of an image forming apparatus described in JP-A-59-147319, a laser beam scanning device described in Japanese Utility Model Application Laid-Open No. 2-102515, and the like. Alternatively, JP-A-4-2912
No. 73, the image forming apparatus described in JP-A-5-3
No. 23221 and the like.

Referring to FIG. 6, which schematically shows a conventional laser scanning optical device of this type, a light beam emitted from a laser diode 2 as a light source is collimated by a collimator 12, and
After being incident on the cylindrical lens 14 and being elongated in the main scanning direction, the polygon mirror 1 serving as a deflecting unit is turned on.
5. Irradiate the surface to be scanned 17 sequentially through the fθ lens 16 which is an image forming optical system.

The polygon mirror 15 rotates about an axis perpendicular to the main scanning direction as shown by a driving means (not shown). By this rotation operation, the laser beam is reflected in the main scanning direction on the surface 17 to be scanned. Is done. Laser diode 2
Switches the output state in accordance with the rotation operation of the polygon mirror 15, whereby an image is formed in the main scanning direction of the surface 17 to be scanned. The laser light reflected by the rotating polygon mirror 15 forms an image in the form of a spot by the fθ lens 16 and scans the scanned surface 17 such as the photosensitive drum at a constant speed.

A measuring optical system for detecting a position where an image is formed is provided between the fθ lens 16 and the surface 17 to be scanned. This measuring optical system includes a slit 9 and a synchronous sensor 3 as a light receiving element. Among these members, the slit 9 and the synchronous sensor 3 are arranged so that the laser beam enters the synchronous sensor 3 through the slit 9.

Referring to FIG. 7 showing the configuration of a horizontal synchronizing signal detecting circuit used in this type of conventional laser scanning optical apparatus, together with FIG. 6, a video signal 10 transmitted from a host device (not shown) is a laser. The laser diode 2 is input to the drive circuit 1 and lights up. The light quantity control circuit 5 controls the laser drive circuit 1 based on the signal from the light quantity detection sensor 4 to keep the light quantity from the laser diode 2 constant. The horizontal synchronizing signal detection circuit used in this type of conventional laser scanning optical device is configured so that a signal detected by the synchronizing sensor 3 is output as a horizontal synchronizing signal 11 by the comparator 6. FIG. 3 shows a sensor output level which is an output waveform of the synchronization sensor 3 and a horizontal synchronization signal 1 which is an output of the comparator 6.
1 shows the waveform of FIG.

In recent years, this type of laser scanning optical device has been improved in resolution and speed, and a function of changing the image density by the amount of laser has been added. When the resolution and speed are increased, the rotation of the polygon mirror 15 must be increased, and the laser beam crossing the slit 9 increases, and the sensor output level in FIG. Go down. Then, the horizontal synchronization signal 11
Has a narrower waveform as shown in FIG. Further, when the sensor output level falls below the detection level, the horizontal synchronization signal 11 is not generated. A similar problem occurs when the amount of laser light is reduced to reduce the image density. There is a problem that it is necessary to adjust the detection level for each performance model in order to avoid a problem.

[0008]

The first problem of the conventional horizontal synchronizing signal detecting circuit is that when the resolution or the speed is increased, the waveform of the horizontal synchronizing signal narrows or the horizontal synchronizing signal is generated. It is gone. The reason is that when the resolution and the speed are increased, the rotation of the polygon mirror must be increased, and the laser beam crossing the slit becomes faster, and the sensor output level decreases. A similar problem occurs when the amount of laser light is reduced to reduce the image density. There is a problem that it is necessary to adjust the detection level for each performance model in order to avoid a problem.

A second problem is that when the laser light amount is increased to increase the image density, the sensor output level increases and the width of the horizontal synchronizing signal increases. Then, there arises a problem that the first print start position is shifted to the left.

An object of the present invention has been proposed to solve the above-mentioned problems of the prior art. The object of the present invention is to provide a high-resolution and high-speed horizontal synchronizing signal caused by a change in light quantity at the time of image density adjustment. A stable horizontal synchronizing signal detection circuit is provided by controlling the malfunction from a CPU or the like to a reference voltage control circuit or the like of the horizontal synchronizing signal detecting circuit.

[0011]

A horizontal synchronizing signal detecting circuit according to the present invention detects a driving circuit for emitting a light beam emitted from a light emitting means based on a video signal transmitted from a certain device, and detects a light amount of the emitted light beam. A light amount detection unit, a light amount control circuit that controls the drive circuit based on a signal from the light amount detection unit to keep the light amount from the light emission unit constant, and a scan for defining a position where the emitted light beam forms an image. A synchronous sensor that detects a start position, a comparator that compares the emitted light beam optical signal detected by the synchronous sensor with a certain reference voltage and outputs the same as a horizontal synchronization signal, and a reference voltage control circuit that outputs the reference voltage .

Further, the horizontal synchronizing signal detecting circuit of the present invention
A reference voltage control circuit that outputs the reference voltage to the comparator based on a signal from a CPU that controls the entire circuit.

Further, the horizontal synchronizing signal detecting circuit of the present invention comprises a driving circuit for emitting a light beam emitted from a light emitting means based on a video signal transmitted from a certain device, and a light amount detecting means for detecting a light amount of the emitted light beam. A light quantity control circuit for controlling the drive circuit based on a signal from the light quantity detection means to keep the light quantity from the light emission means constant, and detecting a scanning start position for defining a position where the emitted light flux forms an image. A synchronous sensor, a comparator that outputs the emitted light beam optical signal detected by the synchronous sensor as a horizontal synchronization signal, and a gain adjustment circuit that adjusts the gain of the comparator.

Further, the horizontal synchronizing signal detecting circuit of the present invention includes the gain adjusting circuit for adjusting the gain of the comparator based on a signal from a CPU which controls the entire circuit.

Further, in the horizontal synchronization signal detecting circuit according to the present invention, the light emitting means is a laser light emitting means.

Further, the scanning optical apparatus according to the present invention comprises: a light emitting means for emitting an emitted light beam based on a video signal transmitted from a certain device; a collimator for making the emitted light beam of the light emitting means a parallel light; , A cylindrical lens having an elongated shape in the main scanning direction, a deflecting unit for the emitted light beam, an imaging optical system for the emitted light beam, a driving circuit for emitting the emitted light beam, and a light amount for detecting the light amount of the emitted light beam Detecting means, a light quantity control circuit for controlling the drive circuit based on a signal from the light quantity detecting means to keep the light quantity from the light emitting means constant, and starting scanning for defining a position where the emitted light flux forms an image. A synchronous sensor that detects a position, a comparator that compares the emitted light beam optical signal detected by the synchronous sensor with a certain reference voltage, and outputs the signal as a horizontal synchronous signal. And a reference voltage control circuit for outputting the reference voltage.

Further, the scanning optical device according to the present invention comprises: a light emitting means for emitting an emitted light beam based on a video signal transmitted from a certain device; a collimator for making the emitted light beam of the light emitting device a parallel light; , A cylindrical lens having an elongated shape in the main scanning direction, a deflecting unit for the emitted light beam, an imaging optical system for the emitted light beam, a driving circuit for emitting the emitted light beam, and a light amount for detecting the light amount of the emitted light beam Detecting means, a light quantity control circuit for controlling the drive circuit based on a signal from the light quantity detecting means to keep the light quantity from the light emitting means constant, and starting scanning for defining a position where the emitted light flux forms an image. A synchronous sensor that detects a position, a comparator that outputs the emitted light beam optical signal detected by the synchronous sensor as a horizontal synchronous signal, And a gain adjusting circuit for adjusting the resulting.

Further, the image forming apparatus according to the present invention has a light emitting means for emitting an emitted light beam based on a video signal transmitted from a certain device, a collimator for making the emitted light beam of the light emitting means parallel light, and an emitted light beam , A cylindrical lens having an elongated shape in the main scanning direction, a deflecting unit for the emitted light beam, an imaging optical system for the emitted light beam, a driving circuit for emitting the emitted light beam, and a light amount for detecting the light amount of the emitted light beam Detecting means, a light quantity control circuit for controlling the drive circuit based on a signal from the light quantity detecting means to keep the light quantity from the light emitting means constant, and starting scanning for defining a position where the emitted light flux forms an image. A synchronous sensor that detects a position, a comparator that compares the emitted light beam optical signal detected by the synchronous sensor with a certain reference voltage, and outputs the signal as a horizontal synchronous signal. Comprising a scanning optical means and a reference voltage control circuit for outputting the reference voltage, and an image forming unit by the electrophotographic method.

Further, the image forming apparatus of the present invention has a light emitting means for emitting an emitted light beam based on a video signal transmitted from a certain device, a collimator for making the emitted light beam of the light emitting means a parallel light, and an emitted light beam , A cylindrical lens having an elongated shape in the main scanning direction, a deflecting unit for the emitted light beam, an imaging optical system for the emitted light beam, a driving circuit for emitting the emitted light beam, and a light amount for detecting the light amount of the emitted light beam Detecting means, a light quantity control circuit for controlling the drive circuit based on a signal from the light quantity detecting means to keep the light quantity from the light emitting means constant, and starting scanning for defining a position where the emitted light flux forms an image. A synchronous sensor that detects a position, a comparator that outputs the emitted light beam optical signal detected by the synchronous sensor as a horizontal synchronous signal, Comprising a scanning optical means and a gain adjusting circuit for adjusting the resulting, and an image forming unit by the electrophotographic method.

[0020]

Next, embodiments of the present invention will be described in detail with reference to the drawings.

Referring to FIG. 1 showing the configuration of the horizontal synchronizing signal detection circuit used in the laser scanning optical apparatus according to the first embodiment of the present invention, in conjunction with FIG. The video signal 10 is input to the laser drive circuit 1 and turns on the laser diode 2 which is a light emitting unit.
A light amount control circuit 5 controls a laser drive circuit 1 based on a signal from a light amount detection sensor 4 serving as a light amount detection unit, and keeps the light amount from the laser diode 2 constant. Further, in this embodiment, the laser light signal detected by the synchronization sensor 3 is output by the comparator 6 as a horizontal synchronization signal 11. The reference voltage to the comparator 6 is output from the reference voltage control circuit 8 based on a signal from the CPU 9 that controls the entire circuit.

As shown in FIG. 5 (b), when the output of the synchronous sensor is lowered to increase the resolution and speed and to reduce the image density, the CPU 9 controls the reference voltage control circuit 8 to lower the reference voltage. Let it do. As shown in FIG. 4B, when increasing the amount of laser light to increase the image density, the CPU 9 controls the reference voltage control circuit 8 to increase the reference voltage.

Referring to FIG. 2 showing the configuration of a horizontal synchronizing signal detecting circuit used in the laser scanning optical device according to the second embodiment of the present invention in conjunction with FIG. 6, a gain adjusting circuit 7 is added in FIG. The CPU 9 controls the gain adjustment circuit 7 in the same manner as in the first embodiment, and adjusts the gain of the comparator 6 to obtain the same effect.

In both the first embodiment and the second embodiment, the same effect can be obtained by controlling the light amount control circuit 5 in accordance with the amount of light currently being operated, instead of the control from the CPU 9. .

A laser scanning optical apparatus using the above-described horizontal synchronizing signal detecting circuit is used in an image forming apparatus such as a laser printer, a facsimile, a digital copying machine, and a plate making apparatus, which optically writes an image on an image surface with a laser beam. be able to.

[0026]

As described above, the first effect is that the horizontal synchronizing signal is normally output even if the output of the synchronizing sensor is lowered in order to increase the resolution and speed and to reduce the image density. That is. The reason is that the CPU controls the reference voltage control circuit to lower the reference voltage or causes the gain adjustment circuit to adjust the gain of the comparator.

The second effect is that even if the output of the synchronization sensor is increased to increase the image density, the horizontal synchronization signal is normally output. The reason is that the CPU controls the reference voltage control circuit to increase the reference voltage or causes the gain adjustment circuit to adjust the gain of the comparator.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a first exemplary embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a second exemplary embodiment of the present invention.

FIG. 3 is a waveform diagram of a sync sensor output, a reference voltage, and a horizontal sync signal.

FIG. 4 is a waveform diagram of a sync sensor output, a reference voltage, and a horizontal sync signal when the amount of laser light increases.

FIG. 5 is a waveform diagram of a sync sensor output, a reference voltage, and a horizontal sync signal when the laser light amount decreases.

FIG. 6 is a perspective view illustrating a configuration of a laser scanning optical device.

FIG. 7 is a circuit diagram showing a configuration of a conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Laser drive circuit 2 Laser diode 3 Synchronization sensor 4 Light quantity detection sensor 5 Light quantity control circuit 6 Comparator 7 Gain adjustment circuit 8 Reference voltage control circuit 9 CPU 10 Video signal 11 Horizontal synchronization signal 12 Collimator 14 Cylindrical lens 15 Polygon mirror 16 fθ lens 17 Scanned surface

Claims (15)

[Claims] 1. A drive circuit for emitting a light beam emitted from a light emitting means based on a video signal transmitted from a certain device, a light amount detecting means for detecting a light amount of the emitted light beam, and a light amount detecting means based on a signal from the light amount detecting means. A light amount control circuit for controlling the drive circuit to keep the light amount from the light emitting unit constant, a synchronous sensor for detecting a scanning start position for defining a position where the emitted light beam forms an image, and a synchronous sensor for detecting the scanning start position. A horizontal synchronizing signal detecting circuit, comprising: a comparator that compares the obtained emitted light beam optical signal with a certain reference voltage and outputs the same as a horizontal synchronizing signal; and a reference voltage control circuit that outputs the reference voltage. 2. The horizontal synchronizing signal detection according to claim 1, further comprising the reference voltage control circuit that outputs the reference voltage to the comparator based on a signal from a CPU that controls the entire circuit. circuit. 3. A drive circuit for emitting a light beam emitted from a light emitting means based on a video signal transmitted from a certain device, a light amount detecting means for detecting a light amount of the emitted light beam, and a light amount detecting means based on a signal from the light amount detecting means. A light amount control circuit for controlling the drive circuit to keep the light amount from the light emitting unit constant, a synchronous sensor for detecting a scanning start position for defining a position where the emitted light beam forms an image, and a synchronous sensor for detecting the scanning start position. A horizontal synchronizing signal detection circuit, comprising: a comparator that outputs the output light beam light signal as a horizontal synchronizing signal; and a gain adjustment circuit that adjusts the gain of the comparator. 4. The horizontal synchronizing signal detection circuit according to claim 3, further comprising: the gain adjustment circuit that adjusts the gain of the comparator based on a signal from a CPU that controls the entire circuit. 5. The horizontal synchronizing signal detecting circuit according to claim 1, wherein said light emitting means is a laser light emitting means. 6. A light emitting means for emitting an emitted light beam based on a video signal transmitted from a certain device, a collimator for making the emitted light beam of the light emitting means a parallel light, and a shape of the emitted light beam being elongated in the main scanning direction. A cylindrical lens, a deflecting device for the emitted light beam, an imaging optical system for the emitted light beam, a driving circuit for emitting the emitted light beam, a light amount detecting device for detecting the light amount of the emitted light beam, and the light amount detecting device A light amount control circuit that controls the drive circuit based on a signal from the light source and keeps the light amount from the light emitting unit constant, a synchronous sensor that detects a scanning start position for defining a position where the emitted light flux performs image formation, A comparator for comparing the emitted light beam light signal detected by the synchronization sensor with a certain reference voltage and outputting it as a horizontal synchronization signal; and a reference voltage for outputting the reference voltage. A scanning optical device, comprising: a control circuit. 7. The scanning optical device according to claim 6, further comprising: the reference voltage control circuit that outputs the reference voltage to the comparator based on a signal from a CPU that controls the entire circuit. 8. A light emitting means for emitting a light beam based on a video signal transmitted from a certain device, a collimator for collimating the light beam emitted from the light emitting means, and a collimator having a shape elongated in the main scanning direction. A cylindrical lens, a deflecting unit for the emitted light beam, an imaging optical system for the emitted light beam, a driving circuit for emitting the emitted light beam, a light amount detecting unit for detecting the light amount of the emitted light beam, and the light amount detecting unit A light amount control circuit that controls the drive circuit based on a signal from the light source and keeps the light amount from the light emitting unit constant, a synchronous sensor that detects a scanning start position for defining a position where the emitted light flux performs image formation, A comparator that outputs the emitted light beam optical signal detected by the synchronization sensor as a horizontal synchronization signal; and a gain adjustment circuit that adjusts the gain of the comparator. A scanning optical device characterized by the following. 9. The scanning optical apparatus according to claim 8, further comprising the gain adjustment circuit that adjusts the gain of the comparator based on a signal from a CPU that controls the entire circuit. 10. The scanning optical device according to claim 6, wherein said light emitting means is a laser light emitting means. 11. A light emitting means for emitting an emitted light beam based on a video signal transmitted from a certain device, a collimator for making the emitted light beam of the light emitting means a parallel light, and a shape of the emitted light beam being elongated in the main scanning direction. A cylindrical lens, a deflecting unit for the emitted light beam, an imaging optical system for the emitted light beam, a driving circuit for emitting the emitted light beam, a light amount detecting unit for detecting the light amount of the emitted light beam, and the light amount detecting unit A light amount control circuit that controls the drive circuit based on a signal from the light source and keeps the light amount from the light emitting unit constant, a synchronous sensor that detects a scanning start position for defining a position where the emitted light flux performs image formation, A comparator that compares the emitted light beam optical signal detected by the synchronization sensor with a reference voltage and outputs the same as a horizontal synchronization signal; and a reference voltage that outputs the reference voltage. An image forming apparatus comprising: a scanning optical unit having a pressure control circuit; and an image forming unit by electrophotography. 12. The image forming apparatus according to claim 11, further comprising: the reference voltage control circuit that outputs the reference voltage to the comparator based on a signal from a CPU that controls the entire circuit. 13. A light emitting means for emitting an emitted light beam based on a video signal transmitted from a certain device, a collimator for making the emitted light beam of the light emitting means a parallel light, and a shape of the emitted light beam being elongated in the main scanning direction. A cylindrical lens, a deflecting unit for the emitted light beam, an imaging optical system for the emitted light beam, a driving circuit for emitting the emitted light beam, a light amount detecting unit for detecting the light amount of the emitted light beam, and the light amount detecting unit A light amount control circuit that controls the drive circuit based on a signal from the light source and keeps the light amount from the light emitting unit constant, a synchronous sensor that detects a scanning start position for defining a position where the emitted light flux performs image formation, A comparator that outputs the emitted light beam optical signal detected by the synchronization sensor as a horizontal synchronization signal, and a gain adjustment circuit that adjusts the gain of the comparator. An image forming apparatus, comprising: a scanning optical unit provided; and an image forming unit by electrophotography. 14. The image forming apparatus according to claim 13, further comprising the gain adjustment circuit that adjusts the gain of the comparator based on a signal from a CPU that controls the entire circuit. 15. An image forming apparatus according to claim 11, wherein said light emitting means is a laser light emitting means.