JPH1070330A - Laser driving circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a laser driving circuit wherein excess current during driving of a semiconductor laser is reduced and deterioration and breakage of a semiconductor laser is prevented, and an error element of output power caused by overshoot and ringing is corrected and laser beam of a highly precise light amount is obtained. SOLUTION: While correction pulse having a pulse width according to image data DATA produced in a waveform correction pulse circuit 21 synchronizing with rise of each driving pulse of driving pulse signal produced in a pulse width modulation circuit 11 is asserted, a specified correction current from a waveform correction current source 22 is deducted from a synthetic current of a bias current of a bias current source 12 and a switch current of a switch current source 13 and an overcurrent element by overshoot and ringing generated during driving of the semiconductor laser 17 is restrained.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a laser printer,
The present invention relates to a laser drive circuit used for a copying machine or the like.

[0002]

2. Description of the Related Art In a laser driving circuit in an optical scanning device used for a device such as a laser printer, the reproducibility is controlled according to image data corresponding to binary density and image data corresponding to each density gradation level. To get good laser output,
Conventionally, various methods have been used. When a laser output with good reproducibility is obtained from image data corresponding to a binary density, a method of changing the laser power by modulating the laser light emission or non-light emission intensity (hereinafter, binary drive) is generally used. Method is described). On the other hand, when a laser output with good reproducibility is obtained from image data corresponding to the density gradation, for example, a method of changing the laser power in one pixel region in accordance with the density gradation is used. A pulse width modulation method in which the laser power is changed by controlling the pulse width of the laser drive signal corresponding to each density gradation level, and the laser power is controlled by controlling the amplitude of the laser drive signal corresponding to the density gradation. There is an intensity modulation method that changes the intensity, or a composite method that combines the pulse width modulation method and the intensity modulation method.

FIG. 7 is a block diagram of a conventional laser drive circuit using a pulse width modulation method. The pulse width modulation circuit 11 constituting the laser drive circuit 70 shown in FIG. 7 inputs image data (image data representing the pixel value of each pixel constituting the image) DATA corresponding to the gradation level, and A drive pulse signal including a drive pulse having a pulse width corresponding to the image data DATA is generated.

The bias current source 12 is provided with a semiconductor laser 17
To generate a predetermined bias current to supply the bias current. The switch current source 13 generates a current for causing the semiconductor laser 17 to emit light, superimposed on the bias current generated by the bias current source 12. The current switching circuit 14
While the drive pulse signal generated by the pulse width modulation circuit 11 is asserted, the switch current source 13 is connected to the semiconductor laser 17 via the resistor 71.

[0005] The PD current detection circuit 15 is a semiconductor laser 1
A current corresponding to the light emission intensity of the semiconductor laser 17 from the photodiode 18 that receives a part of the laser light emitted from 7 is detected. APC (Auto Power C)
The control circuit 16 controls the current value of the switch current source 13 based on the current detected by the PD current detection circuit 15.

[0006] The laser driving circuit 70 thus configured
When the semiconductor laser 17 emits light, the bias current from the bias current source 12 is constantly supplied to the semiconductor laser 17. The image data DATA is input to the pulse width modulation circuit 11. Then, a drive pulse signal including a drive pulse having a pulse width corresponding to the image data DATA of each pixel is generated, and the switch current source 13 is connected to the semiconductor laser 17 by the current switching circuit 14 while the drive pulse is asserted. Is done. Thus, the switching current from the switch current source 13 is supplied to the semiconductor laser 17 so as to be superimposed on the bias current from the bias current source 12. Then, the semiconductor laser 17 emits light. Here, the laser drive circuit 70 and the semiconductor laser 1 mounted on the printed circuit board have the driving current waveform when the semiconductor laser 17 is driven by the resistor 71.
The overshoot and ringing generated by the wiring inductance component 7 and the inductance component of each circuit element are reduced. Further, a current corresponding to the emission intensity of the semiconductor laser 17 is detected by the PD current detection circuit 15 via the photodiode 18. The current detected by the PD current detection circuit 15 is input to the APC circuit 16,
The current of the switch current source 13 is controlled by the C circuit 16, and the light amount of the semiconductor laser 17 is controlled to be constant.

FIG. 8 is a timing chart of the laser drive circuit based on the pulse width modulation method shown in FIG. The drive pulse signal Data shown in FIG.
Each of the drive pulses is output within one pixel period Tpx, which is one cycle of the pixel clock CKpx. 1 of the drive pulse signal Data
The position where the drive pulse is output within the pixel period Tpx is controlled with respect to the pixel position to be formed. Here, the center of the pixel period Tpx and the center of the drive pulse are represented in correspondence. The drive pulse signal Data is obtained by converting the image data DATA shown in FIG. 7 into a data voltage signal Vda by a pulse width modulation circuit 11, and further converting the voltage between the data voltage signal Vda and the triangular wave voltage signal TW in the pulse width modulation circuit 11. A comparison result is made and generated by the result. During the period in which the drive pulse signal Data is asserted, the drive current I is supplied to the semiconductor laser 17.
_{The LD} flows, and the semiconductor laser 17 is driven by the drive current I _LD , whereby the instantaneous output power Po of the laser light is obtained. Here, the steady drive current Idr shown in FIG. 8 is a current in which the maximum peak value of the drive current I _LD is suppressed to a predetermined level by the APC circuit 16, and this steady drive current Idr
As a result, a set stationary light power Pox is obtained. Here, the overshoot and ringing of the drive current I _LD alleviated by the resistor 71 are ignored.

The above-mentioned binary driving method is a case where there is one image data DATA and the pulse width of the image data DATA is a predetermined width, and is considered to be included in the pulse width modulation method. FIG. 9 is a block diagram of a conventional laser drive circuit using the intensity modulation method. The laser drive circuit 90 includes an intensity modulation circuit 91. When image data DATA is input to the intensity modulation circuit 91, the pulse width is constant and the amplitude is converted to the image data DATA for each pixel. A drive pulse signal composed of the corresponding drive pulse is generated, and the semiconductor laser 17 emits light with a current corresponding to the amplitude of the generated drive pulse signal. Here, the resistance 71 reduces overshoot and ringing of the drive current waveform when the semiconductor laser 17 is driven. Further, a current corresponding to the emission intensity of the semiconductor laser 17 is detected by the PD current detection circuit 15 via the photodiode 18. The current detected by the PD current detection circuit 15 is input to the APC circuit 16, and the APC circuit 16
Controls the amplitude of the drive pulse signal, and the light amount of the semiconductor laser 17 is controlled to be constant.

FIG. 10 is a timing chart of the laser drive circuit based on the intensity modulation method shown in FIG. The drive pulse signal Data shown in FIG. 10 is composed of drive pulses having a predetermined pulse width Tda, and each drive pulse is output within one pixel period Tpx which is one cycle of the pixel clock CKpx. This drive pulse signal Da
During the period in which ta is asserted, the semiconductor laser 17 is driven by the drive current I _{LD including} a drive pulse current having an amplitude corresponding to the image data DATA of each pixel, thereby obtaining the instantaneous laser light output power Po.

[0010]

In the above-mentioned conventional laser drive circuit based on the pulse width modulation method, in the case of the binary drive method, the modulation is performed by the light intensity of light emission and non-light emission of the semiconductor laser. In order to obtain a laser output, there is a problem that the maximum peak (maximum peak current) of the driving current at the time of driving the semiconductor laser becomes an excessive current to the semiconductor laser, which causes deterioration or destruction of the semiconductor laser. When a laser output with good reproducibility is obtained from image data corresponding to a density gradation, as the pulse width of the driving current becomes narrower, an error component of output power caused by overshoot or ringing reduced by resistance cannot be ignored. There is a problem. This problem will be described with reference to FIG. 11 together with the above-described laser drive circuit using the pulse width modulation method shown in FIG.

FIG. 11 is a diagram showing a half of the pulse width modulation method.
Driving current waveform for driving semiconductor laser and its semiconductor
The figure which shows the waveform of the instantaneous output power of the laser beam of the body laser.
is there. The instantaneous output power Po shown in FIG.
Current I_LDIs the boundary of whether or not the semiconductor laser 17 emits light.
Above the threshold current Ith
Therefore, the region showing this linear characteristic is used for modulation drive.
You. The semiconductor laser 17 is driven by a drive pulse signal D.
data pulse period Tda, but the semiconductor laser 17
Actually emits light by the bias current source 12.
The switch current from the current switching circuit 14
Drive current I superimposed with switching current Isw _LDBut the threshold
Period exceeding the value current Ith, that is, the laser emission period t
_LDAnd the laser emission period t_LDWithin the drive
Style I_LDInstantaneous output power Po is obtained. here
Therefore, the drive pulse signal Data is an ideal signal,
The rising and falling periods are zero and
If no shoot or undershoot occurs, break
Ideal drive current waveform a shown by the line₀ And its luminescence response
Answer waveform b₀ become. However, actually, the driving pulse signal
Data has a predetermined rise period and fall time due to transient characteristics.
With a rolling period and reduced by the aforementioned resistance.
-Waveform distortion due to overshoot and ringing
Therefore, taking these factors into account, for example, the ideal
Drive current waveform a deviated from₁ And its emission response waveform b
₁ become. However, the peak value of ringing gradually decreases.
Here, these components emit light
Period t_LDAre shown by the sum of the respective values. Luminous
Answer waveform b₁ Has a drive current waveform a₁ Waveform distortion
Over peak Idp and under peak Idn
To increase the over peak for the desired level Por.
Pop, reduced under for desired level Por
-Peak Pon appears, ideal laser light output
There is an error between the power and the actual laser output power.
You. The problem caused by this error will be described with reference to FIG.
explain.

FIG. 12 is a diagram showing a change in the integrated power P in the pulse of the laser beam when the pulse period Tda of the drive pulse signal Data changes in the pulse width modulation method. The ideal characteristic of the integrated power P of the laser beam with respect to the pulse period Tda is a linear characteristic as indicated by a broken line A in FIG. However, actually, as the pulse period Tda of the drive pulse signal Data becomes narrower,
Since the increasing component on the side of the over-peak Pop is larger than the decreasing component on the side of the under-peak Pon (see FIG. 11), the integrated power P of the laser beam increases as shown by the solid line in FIG. Here, the laser drive current I
_{If LD} is the steady drive current Idr, the error curve B follows the same locus. The reason why the integrated power P becomes zero when the pulse period Tda is close to zero is due to an error component in the rising and falling periods.

As described above, in the conventional laser drive circuit based on the pulse width modulation method, as the pulse width of the drive current becomes narrower, the error component of the output power due to overshoot and ringing increases, so that a highly accurate light quantity is obtained. Is difficult to obtain. FIG. 13 is a diagram showing a drive current waveform for driving a semiconductor laser and a waveform of an instantaneous output power of laser light of the semiconductor laser in the intensity modulation method. FIG. 14 is a diagram showing a drive pulse signal Data in the intensity modulation method. FIG. 7 is a diagram showing a change in the integrated power P in the pulse of the laser beam when the amplitude of the laser beam changes.

[0014] Figure 13 is a drive current waveform a ₁ deviated from the ideal, the drive current waveform large oscillating current waveform a ₂ amplitude than a _1, the drive current waveform a ₁ small drive current waveform a amplitude than ₃ and their drive current waveforms a ₁ and a
Light emission response waveforms b ₁ , b ₂ and b ₃ corresponding to ₂ and a ₃ are shown. Since the increasing components on the over-peak side of the light emission response waveforms b ₁ , b ₂ , and b ₃ are larger than the decreasing components on the under-peak side Pon, A ₁ , FIG.
Compared to the ideal characteristics shown by the broken line indicated by A _2, A _3, becomes the characteristic shown by the solid line indicated by B _1, B _2, B ₃ which is shifted from the ideal, actual integrated power P of the laser beam is an ideal It is larger than the integral power P. Also, the actual integrated power P
As shown in B ₁ , B ₂ , and B ₃ in FIG. 14, the larger the amplitude of the drive current waveform, the larger the ideal integrated power P.

As described above, in the laser drive circuit based on the conventional intensity modulation method, as the pulse width of the drive current becomes narrower and the amplitude of the drive current becomes larger, the error component of the output power caused by overshoot and ringing. Therefore, it is difficult to obtain a high-precision amount of laser light. In view of the above circumstances, the present invention reduces excessive current during driving of a semiconductor laser, prevents deterioration and breakage of the semiconductor laser, and corrects an error component of output power caused by overshoot or ringing. It is an object of the present invention to provide a laser drive circuit capable of obtaining a high-precision amount of laser light.

[0016]

According to a first aspect of the present invention, there is provided a laser driving circuit for driving a semiconductor laser based on image data representing a pixel value of each pixel constituting an image. (1-1) a drive pulse generation circuit for generating a drive pulse signal composed of a drive pulse having a pulse width corresponding to the image data of each pixel; (1-2) having a start point synchronized with the start point of each of the drive pulses A correction pulse generation circuit that generates a correction pulse signal composed of a correction pulse having a pulse width corresponding to the image data of each pixel. (1-3) A semiconductor laser that generates a predetermined drive current while the drive pulse is asserted. (1-4) A drive current source connected in series to the semiconductor laser, which generates a predetermined correction current while the correction pulse is asserted. A correction current source connected to the column and connected in series to the driving current source is provided.

The first laser driving circuit according to the present invention uses a predetermined driving current generated during a period in which a driving pulse having a pulse width corresponding to the image data of each pixel is asserted.
Since a predetermined correction current generated during a period in which a correction pulse having a start point synchronized with the start point of each drive pulse and having a pulse width corresponding to the image data of each pixel is asserted is subtracted, pulse width modulation is performed. An overpeak of the driving current generated when the semiconductor laser is driven in the system is suppressed, and an integrated emission power corresponding to the image data with high accuracy can be obtained.

The driving current source generates a driving current having a current value corresponding to a predetermined driving current control signal, and generates a driving current control signal corresponding to image data of each pixel. When a driving current control circuit for transmitting the driving current to the driving current source is provided, a driving current in consideration of the intensity modulation method can be obtained. Further, the correction current source generates a correction current having a current value corresponding to a predetermined correction current control signal, and generates a correction current control signal corresponding to image data of each pixel to generate the correction current source. With a correction current control circuit
A correction current considering the intensity modulation method is obtained.

A second laser driving circuit according to the present invention for achieving the above object is a laser driving circuit for driving a semiconductor laser based on image data representing a pixel value of each pixel constituting an image. A drive pulse generation circuit for generating a drive pulse signal composed of a drive pulse having a predetermined pulse width. (2-2) A predetermined pulse having a start point synchronized with the start point of each of the drive pulses and shorter than the pulse width of the drive pulse A correction pulse generation circuit that generates a correction pulse signal including a correction pulse having a width (2-3) a period in which the drive pulse is asserted;
A drive current source that generates a drive current having a current value according to a predetermined drive current control signal and is connected in series to the semiconductor laser; (2-4) a period in which the correction pulse is asserted;
A correction current source for generating a correction current having a current value corresponding to a predetermined correction current control signal, the correction current source being connected in parallel to the semiconductor laser and connected in series to the drive current source; (2-5) Image of each pixel A drive current control circuit that generates a drive current control signal corresponding to data and transmits the same to the drive current source (2-6) A correction current control signal that generates a correction current control signal corresponding to image data of each pixel and transmits the correction current control signal to the correction current source A current control circuit is provided.

A second laser driving circuit according to the present invention drives a current value corresponding to a driving current control signal corresponding to image data of each pixel generated during a period in which a driving pulse having a predetermined pulse width is asserted. From the current, a correction according to the image data of each pixel generated during a period in which a correction pulse having a start point synchronized with the start point of each of the drive pulses and having a predetermined pulse width shorter than the pulse width of the drive pulse is asserted Since the correction current of the current value according to the current control signal is subtracted, an overpeak of the drive current generated when driving the semiconductor laser in the intensity modulation method is suppressed.

Here, when the driving pulse generation circuit generates a driving pulse signal having a driving pulse having a pulse width corresponding to the image data of each pixel, the pulse width modulation method is added to the intensity modulation method. The obtained driving current is obtained. Further, when the correction pulse generation circuit generates a correction pulse signal including a correction pulse having a pulse width corresponding to the image data of each pixel, the correction in which the pulse width modulation method is added to the intensity modulation method. The drive current is corrected by the current.

Further, a third aspect of the present invention for achieving the above object.
A laser driving circuit for driving a semiconductor laser based on image data representing a pixel value of each pixel forming an image; (3-1) a driving circuit having a pulse width corresponding to the image data of each pixel; Driving pulse generation circuit for generating a driving pulse signal composed of a pulse (3-2) correction comprising a correction pulse having a starting point synchronized with the starting point of each of the driving pulses and having a predetermined pulse width shorter than the pulse width of the driving pulse A correction pulse generation circuit that generates a pulse signal. (3-3) A drive current source that is connected in series with a semiconductor laser and generates a predetermined drive current while the drive pulse is asserted. (3-4) The correction While the pulse is asserted,
A correction current source that generates a correction current having a current value corresponding to a predetermined correction current control signal and is connected in parallel to the semiconductor laser and connected in series to the drive current source; (3-5) an image of each pixel A correction current control circuit is provided that generates a correction current control signal corresponding to data and transmits the generated correction current control signal to a correction current source.

The third laser drive circuit of the present invention is a laser drive circuit that employs a pulse width modulation method for a drive pulse and an intensity modulation method for a correction current. A fourth laser driving circuit of the present invention for achieving the above object is a laser driving circuit for driving a semiconductor laser based on image data representing a pixel value of each pixel constituting an image. (4-2) Correction having a starting point synchronized with the starting point of each of the driving pulses and having a pulse width corresponding to the image data of each pixel A correction pulse generation circuit that generates a correction pulse signal composed of pulses (4-3) a period in which the drive pulse is asserted,
A drive current source that generates a drive current having a current value corresponding to a predetermined drive current control signal and is connected in series with a semiconductor laser. (4-4) Generates a predetermined correction current while the correction pulse is asserted A correction current source connected in parallel to the semiconductor laser and connected in series to the drive current source. (4-5) The drive current source generates a drive current control signal corresponding to image data of each pixel. And a drive current control circuit for transmitting the current to the control circuit.

The fourth laser driving circuit according to the present invention is a laser driving circuit employing an intensity modulation method for a driving pulse and a pulse width modulation method for a correction pulse.

[0025]

Embodiments of the present invention will be described below. FIG. 1 is a block diagram of a laser drive circuit using a pulse width modulation method according to an embodiment of the present invention, FIG. 2 is a circuit diagram of the laser drive circuit shown in FIG. 1, and FIG. 3 is a laser drive circuit shown in FIG. 6 is an operation timing chart of FIG.

The same components as those of the laser drive circuit shown in FIG. 7 are denoted by the same reference numerals. Pulse width modulation circuit 1 constituting laser drive circuit 10 shown in FIG.
Reference numeral 1 denotes a D / A converter 11a and a comparator 11b shown in FIG. The waveform correction pulse circuit 21 includes a nonlinear correction circuit 21a and a comparator 21b.
And an AND gate 21c. As shown in FIG. 2, the switch current source 13 and the waveform correction current source 22 are connected to the semiconductor laser 17 in series and in parallel, respectively. The waveform correction current source 22 generates a predetermined correction current Ibs. The current switching circuit 23
It is composed of two current switches 23a and 23b.

The D / A converter 11a constituting the pulse width modulation circuit 11 receives image data DATA representing the pixel value of each pixel constituting the image, and D / A converts the inputted image data DATA. The data voltage signal Vda corresponding to the gradation level of the image data DATA shown in FIG.
Is output. The comparator 11b compares the voltage level of the data voltage signal Vda from the D / A converter 11a with the voltage level of the triangular wave voltage signal TW shown in FIG. 3, and thereby the image data of each pixel for driving the semiconductor laser 17 is obtained. A drive pulse signal Data composed of a drive pulse having a pulse width of “H” level according to DATA is output. The current switch 23a of the current switching circuit 23 shown in FIG. 2 is turned on with the pulse width of the “H” level of the drive pulse signal Data. Further, the driving pulse signal D
The data is input to the AND gate 21c.

The nonlinear correction circuit 21a receives the data voltage signal Vda from the D / A converter 11a and generates a voltage signal Vbs corresponding to the data voltage signal Vda.
A voltage signal obtained by adding the voltage signal Vbs to the data voltage signal Vda is output. The comparator 21b compares the voltage signal from the non-linear correction circuit 21a with the triangular wave voltage signal TW, and inputs the comparison result (signal A shown in FIG. 3) to the AND gate 21c. The pixel clock CKpx is also input to the AND gate 21c. The AND gate 21c outputs a correction pulse B during a period Tbs in which the input drive pulse signal Data, the signal A from the comparator 21b, and the pixel clock CKpx are all at the "H" level. That is, the correction pulse B has a starting point synchronized with the starting point of each driving pulse constituting the driving pulse signal Data, and has a pulse width Tbs corresponding to the image data DATA of each pixel. The current switch 23b of the current switching circuit 23 is controlled by the correction pulse B.

In the laser drive circuit 10 of the present embodiment, when the semiconductor laser 17 is driven, the bias current Ib from the bias current source 12 is constantly supplied to the semiconductor laser 17. Further, the image data DATA is input to the pulse width modulation circuit 11. Then, the image data DATA of each pixel generated by the pulse width modulation circuit 11 is obtained.
The current switch 23a of the current switching circuit 23 is turned on by a drive pulse signal Data including a drive pulse having a pulse width of the “H” level corresponding to. At the same time, a correction pulse B having an “H” level pulse width is also output from the AND gate 21c. As a result, the current switch 23b is also turned on. Then, the bias current source 1
The drive pulse signal D of the combined current of the bias current Ib from the switch current source 2 and the current Isw from the switch current source 13
The current in the rising period of data is subtracted by the correction current Ibs from the waveform correction current source 22. The driving current I _LD generated in this way flows through the semiconductor laser 17, and the semiconductor laser 17 emits light. Light corresponding to the emission intensity is detected by the PD current detection circuit 15 via the photodiode 18. The current detected by the PD current detection circuit 15 is input to the APC circuit 16, whereby the switch current source 13 is controlled, and the maximum light amount of the semiconductor racer 17 within a predetermined period is determined. As described above, in the laser drive circuit 10 of the present embodiment, when the semiconductor laser 17 is driven, the correction having the pulse width corresponding to the data DATA of each pixel is synchronized with the rise of each drive pulse of the drive pulse signal Data. A predetermined correction current Ibs during a period in which the pulse B is asserted is subtracted from a combined current of the bias current Ib and the current Isw, and an excess current of the combined current due to overshoot or ringing generated when the semiconductor laser 17 is driven. Since the component is suppressed, an increase component of the laser beam instantaneous output power Po due to overshoot or ringing is reduced,
Highly accurate laser light can be obtained.

In the laser drive circuit of the present embodiment using the pulse width modulation method, a correction pulse having a pulse width corresponding to the image data of each pixel is generated, and an excess current generated when the semiconductor laser is driven is reduced. Instead of this, instead of this correction pulse, a correction voltage signal to be transmitted to the waveform correction current source according to the image data of each pixel is generated to suppress the excess current generated when the semiconductor laser is driven. Alternatively, while controlling the pulse width of the correction pulse to be constant, a correction voltage signal to be transmitted to the waveform correction current source according to the image data of each pixel is generated, and an excess current generated when driving the semiconductor laser is calculated. It may be suppressed.

FIG. 4 is a block diagram of a laser drive circuit using an intensity modulation method according to an embodiment of the present invention, and FIG.
3 is a circuit diagram of the laser drive circuit shown in FIG. 3, and FIG. 3 is an operation timing chart of the laser drive circuit shown in FIG. Note that the same components as those of the laser drive circuit shown in FIGS. 1 and 2 are denoted by the same reference numerals.

The intensity modulation circuit 41 constituting the laser drive circuit 40 shown in FIG. 4 is a D / A converter 41 shown in FIG.
a and a comparator 41b. The waveform correction pulse circuit 42 includes a polygonal line approximation circuit 42a, a comparator 42b, and an AND gate 42c. The switch current source 43 and the waveform correction current source 2
2 are semiconductor lasers 17 as shown in FIG.
Are connected in series and in parallel. Switch current source 43
Is provided with a plurality of current sources.

The D / A converter 41a inputs image data DATA representing the pixel value of each pixel constituting the image, and D / A converts the input image data DATA.
A data voltage signal Vda corresponding to the gradation level of the image data DATA is output. The data source provided in the switch current source 43 is controlled by the data voltage signal Vda, and a desired switch current I _SW is obtained. Comparator 41
b compares a voltage level between a predetermined set voltage signal Vdp and a triangular wave voltage signal TW shown in FIG. 6, thereby driving the semiconductor laser 17 with a pulse having a constant pulse width Tda. Pulse signal Data
Is output. With this “H” level pulse width Tda,
The current switch 2 of the current switching circuit 23 shown in FIG.
3a is turned on. The drive pulse signal Data is input to the AND gate 42c.

The polygonal line approximation circuit 42a receives the data voltage signal Vda from the D / A converter 41a, and outputs two correction voltage signals Vb corresponding to the data voltage signal Vda.
s1 and Vbs2 are output. The comparator 42b compares the voltage signal obtained by adding the set voltage signal Vdp to the voltage signal Vbs1 from the polygonal line approximation circuit 42a with the triangular wave voltage signal TW, and inputs the comparison result (signal A shown in FIG. 3) to the AND gate 42c. . The pixel clock CKpx is also input to the AND gate 42c. This AND gate 42c
Then, the correction pulse B is output during the period Tbs in which the input drive pulse signal Data, the signal A from the comparator 42b, and the pixel clock CKpx are all at the “H” level. That is, the correction pulse B has a starting point synchronized with the starting point of each driving pulse constituting the driving pulse signal Data, and has a pulse width Tbs corresponding to the image data DATA of each pixel. The current switch 23b of the current switching circuit 23 is controlled by the correction pulse B.

The value of the correction current Ibs flowing through the waveform correction current source 22 is controlled by a correction voltage signal Vbs2 (correction current control signal according to the present invention) from the polygonal line approximation circuit 42a according to the data voltage signal Vda. You. In the laser drive circuit 40 of the present embodiment, when driving the semiconductor laser 17, the bias current Ib from the bias current source 12 is constantly supplied to the semiconductor laser 17.
Further, the image data DATA is input to the intensity modulation circuit 41. Then, the current switch 23 is driven by a drive pulse having a predetermined pulse width Tda from the comparator 41b.
a is turned on, whereby the switch current source 43 receives D /
Switch current I _sw flows corresponding to the data voltage signal Vda from A converter 41a. On the other hand, AND gate 21
c, the current switch 23b is turned on by the correction pulse having the pulse width Tbs.
2, the correction current Ibs flows. Then, of the combined current of the bias current Ib from the bias current source 12 and the current Isw from the switch current source 43, the current during the rising period of the drive pulse signal Data is determined by the correction current Ibs from the waveform correction current source 22. Will be deducted. The driving current I _LD thus generated flows through the semiconductor laser 17, and the semiconductor laser 17 emits light. Light corresponding to the emission intensity is transmitted through the photodiode 18 to the PD 18.
The current is detected by the current detection circuit 15. The current detected by the PD current detection circuit is input to the APC circuit 16, whereby the switching current source 43 is controlled, and the maximum light amount of the semiconductor laser 17 within a predetermined period is determined. Here, in the APC circuit 16, the operation maximum value of the switch current I _SW is set for each valid period.
The modulation operation of the switch current I _SW with the operation maximum current value of the C circuit 16 as a full scale can be performed.

The period Tbs of the correction pulse B may be a fixed period if the period that changes in proportion to the intensity level is small. In that case, the correction voltage signal Vbs1 is set to a constant value. As described above, in the laser drive circuit 40 of the present embodiment, when the semiconductor laser 17 is driven,
While the correction pulse B having a pulse width corresponding to the image data DATA of each pixel is asserted in synchronization with the rise of each pulse of the drive pulse signal Data, the correction current Ibs corresponding to the amplitude of the correction pulse B is It subtracts from the combined current of the bias current Ib and the current I _SW to suppress the excess current component of the combined current due to overshoot and ringing generated when the semiconductor laser 17 is driven. of P _o, reduced increase component due to the overshoot or ringing, the laser light with high accuracy the amount of light is obtained.

In the laser drive circuit of the present embodiment using the intensity modulation method, a correction pulse having a pulse width corresponding to the pixel data of each pixel and a correction voltage signal corresponding to the pixel data of each pixel are generated. Although the excess current generated when the semiconductor laser is driven is suppressed, the present invention is not limited to this, and a correction pulse having a pulse width corresponding to the image data of each pixel and a predetermined correction current are generated to generate a semiconductor laser. The excess current generated during driving may be suppressed, or the correction current having a predetermined pulse width and the correction current corresponding to the image data of each pixel may be generated to reduce the excess current generated when driving the semiconductor laser. It may be suppressed.

The current sources 13 provided in the laser driving circuit shown in FIG. 1 and the laser driving circuit shown in FIG. 3 respectively generate a predetermined current value and a current value corresponding to the pixel data of each pixel. Although the excess current generated when the semiconductor laser is driven was suppressed, the laser drive circuit shown in FIG. 1 and the current source 13 provided in the laser drive circuit shown in FIG. 3 respectively correspond to the pixel data of each pixel. A current value and a predetermined current value may be generated to suppress an excess current generated when the semiconductor laser is driven.

[0039]

As described above, the laser drive circuit of the present invention suppresses the maximum peak drive current value due to waveform distortion due to overshoot or ringing,
Excessive current can be prevented, and deterioration or destruction of the laser element can be prevented, and a highly reliable drive circuit can be achieved. Also,
An error component in the drive waveform distortion due to overshoot or ringing can be corrected according to the gradation modulation in the pulse width modulation method or the intensity modulation method, so that modulation characteristics with high precision and high gradation can be obtained.

[Brief description of the drawings]

FIG. 1 is a block diagram of a laser drive circuit using a pulse width modulation method according to an embodiment of the present invention.

FIG. 2 is a circuit diagram of the laser drive circuit shown in FIG.

FIG. 3 is an operation timing chart of the laser drive circuit shown in FIG. 1;

FIG. 4 is a block diagram of a laser drive circuit using an intensity modulation method according to an embodiment of the present invention.

FIG. 5 is a circuit diagram of the laser drive circuit shown in FIG.

6 is an operation timing chart of the laser drive circuit shown in FIG.

FIG. 7 is a block diagram of a conventional laser drive circuit using a pulse width modulation method.

8 is a diagram showing a timing chart of the laser drive circuit based on the pulse width modulation method shown in FIG.

FIG. 9 is a block diagram of a conventional laser drive circuit using an intensity modulation method.

10 is a diagram showing a timing chart of the laser drive circuit based on the intensity modulation method shown in FIG.

FIG. 11 is a diagram showing a drive current waveform for driving a semiconductor laser and a waveform of an instantaneous output power of laser light of the semiconductor laser in the pulse width modulation method.

FIG. 12 is a diagram showing a change in the integrated power P of the laser light in the pulse when the pulse period Tda of the drive pulse signal Data changes in the pulse width modulation method.

FIG. 13 is a diagram showing a drive current waveform for driving a semiconductor laser and a waveform of an instantaneous output power of laser light of the semiconductor laser in the intensity modulation method.

FIG. 14 shows a drive pulse signal Da in the intensity modulation method.
FIG. 7 is a diagram illustrating a change in the integrated power P in the pulse of the laser beam when the amplitude of ta changes.

[Explanation of symbols]

 10, 40 Laser drive circuit 11 Pulse width modulation circuit 11a, 41a D / A converter 11b, 21b, 42b Comparator 12 Bias current source 13, 43 Switch current source 15 PD current detection circuit 16 APC circuit 17 Semiconductor laser 18 Photodiode 21, Reference Signs List 42 Waveform correction pulse circuit 21a Nonlinear correction circuit 21c, 42c AND gate 22 Waveform correction current source 23 Current switching circuit 23a, 23b Current switch 41 Intensity modulation circuit 42a Broken line approximation circuit

Claims (6)

[Claims] 1. A laser driving circuit for driving a semiconductor laser based on image data representing a pixel value of each pixel constituting an image, comprising: a driving pulse signal comprising a driving pulse having a pulse width corresponding to the image data of each pixel. And a correction pulse generation circuit that generates a correction pulse signal including a correction pulse having a start point synchronized with the start point of each of the drive pulses and having a pulse width corresponding to image data of each pixel. A drive current source connected in series to a semiconductor laser for generating a predetermined drive current during a period in which the drive pulse is asserted; and a semiconductor generating a predetermined correction current during a period in which the correction pulse is asserted. A correction current source connected in parallel to the laser and connected in series to the drive current source. The drive circuit. 2. The method according to claim 1, wherein the correction current source generates a correction current having a current value corresponding to a predetermined correction current control signal, and generates a correction current control signal corresponding to image data of each pixel. 2. The laser driving circuit according to claim 1, further comprising a correction current control circuit for transmitting the correction current to a correction current source. 3. A laser driving circuit for driving a semiconductor laser based on image data representing a pixel value of each pixel constituting an image, wherein a driving pulse generation for generating a driving pulse signal comprising a driving pulse having a predetermined pulse width is performed. A correction pulse generation circuit that generates a correction pulse signal including a correction pulse having a start point synchronized with a start point of each of the drive pulses and having a predetermined pulse width shorter than the pulse width of the drive pulse; A driving current source that is connected in series with the semiconductor laser and generates a driving current having a current value corresponding to a predetermined driving current control signal during the asserted period, and a predetermined period during which the correction pulse is asserted. Generating a correction current having a current value according to a correction current control signal, the driving current being connected to the semiconductor laser in parallel; A driving current control circuit that generates a driving current control signal corresponding to image data of each pixel and transmits the generated driving current control signal to the driving current source; and a correction current control corresponding to image data of each pixel. A correction current control circuit for generating a signal and transmitting the signal to the correction current source. 4. The laser drive circuit according to claim 3, wherein said correction pulse generation circuit generates a correction pulse signal including a correction pulse having a pulse width corresponding to image data of each pixel. . 5. A laser driving circuit for driving a semiconductor laser based on image data representing a pixel value of each pixel constituting an image, wherein a driving pulse signal comprising a driving pulse having a pulse width corresponding to the image data of each pixel. And a correction pulse generation circuit that generates a correction pulse signal including a correction pulse having a start point synchronized with the start point of each of the drive pulses and having a predetermined pulse width shorter than the pulse width of the drive pulse. A drive current source connected in series with the semiconductor laser to generate a predetermined drive current during the period in which the drive pulse is asserted, and a predetermined correction current control signal during the period in which the correction pulse is asserted. A correction current having a corresponding current value is generated, connected in parallel to the semiconductor laser and connected in series to the drive current source. A correction current source, a laser drive circuit, characterized in that a correction current control circuit for transmitting to said correction current source generates the correction current control signal corresponding to the image data of each pixel. 6. A laser driving circuit for driving a semiconductor laser based on image data representing a pixel value of each pixel constituting an image, wherein a driving pulse generating a driving pulse signal comprising a driving pulse having a predetermined pulse width. A correction pulse generation circuit that generates a correction pulse signal including a correction pulse having a start point synchronized with a start point of each of the drive pulses and having a pulse width corresponding to image data of each pixel; and wherein the drive pulse is asserted. A driving current source that is connected in series with the semiconductor laser to generate a driving current having a current value corresponding to a predetermined driving current control signal, and a predetermined correction current during a period in which the correction pulse is asserted. Generating a correction current source connected in parallel with the semiconductor laser and connected in series with the drive current source; Laser drive circuit, characterized in that to generate a drive current control signal corresponding to data and a drive current control circuit for transmitting the drive current source.