JPH0469832B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an optical output control circuit that performs switching control on a laser diode.

(Prior Art) A light output control circuit in a beam scanning device such as an optical printer is configured such that, for example, when a light beam is scanned by a rotating polygon mirror, the rotating polygon finishes scanning one line of printing and then starts scanning the next line. The light output level of the laser diode in the subsequent printing scan is set in synchronization with the beam detection signal for each period that does not correspond to the image during the transition to line printing scanning.

Methods for setting the light output level include a method in which the light output level signal detected by the photodetector is compared and controlled in an analog manner with a reference level during a period of non-correspondence with the image, and a sample and hold is carried out. In the digital method, depending on the positive or negative sign of the comparison signal, pulses of a predetermined period are counted or the counting is stopped, and the counted value is D/A converted to output the optical output of the laser diode. The one I set was used.

(Problems to be Solved by the Invention) However, as the speed of optical printers increases, the control time for light output has become increasingly shorter.
In the devices described above, especially in analog systems, the response of comparison control is slow, making it impossible to control each line and having to control each page. There was a problem that it was not possible to adequately respond to changes in characteristics due to rise in temperature, etc.

In addition to the above-mentioned response speed, in the digital system, there is insufficient compensation for variations in the optical output of the laser diode and variations in the photodetector element that detects the optical output within the chip of the laser diode. Furthermore, if the amount of control light for one step of the counter is set small in order to improve control accuracy, there is also the problem that the number of bits of the D/A converter increases.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a control circuit that solves the above-mentioned problems of response speed and control accuracy during control, and allows optical output to be stabilized quickly at the start of control.

(Means for Solving the Problem) In order to solve the above problem, the present invention detects the optical output of a laser diode that emits light in response to a video signal, and converts the optical output level signal to a predetermined reference level value. a comparator that outputs a mutual difference signal between the reference level and the reference level; an integrating circuit that integrates the mutual difference signal; and setting the current of the laser diode to be increased or decreased in accordance with the integral value of the integrating circuit. a constant current circuit; a counter for counting the number of times the mutual difference signal mutually reverses positive and negative signs over a predetermined number of times; and at the beginning of control and at the beginning of each pause period of the video signal. Driving the laser diode by the constant current circuit and enabling the integrating function of the integrating circuit, and when the counter has counted the predetermined number, disabling the integrating function of the integrating circuit and holding the integrated value. This configuration is provided with a switching circuit for controlling the power supply.

(Function) According to the present invention, since the optical output level signal is delayed in phase from the optical output signal of the laser diode, the optical output level signal input to the comparator during the pause period of the video signal is set to the reference level value. After slightly exceeding the reference level value without stabilizing, it returns to below the reference level value, and this process is repeated. Then, the counter counts the number of times this exceeds the limit, and when it reaches a predetermined number, the current setting value of the constant current circuit at that time is held during the next printing period, and the laser diode light is turned on. The output becomes a set value at a predetermined duty time after stabilization.

In addition, at the beginning of control, the counter does not count until the optical output level signal input to the comparator reaches the reference level value, and the laser diode and integration circuit operate continuously during that time. to start up the optical output of the laser diode.

(Embodiment) FIG. 1 is a light output control circuit diagram showing an embodiment of the present invention, and FIG. 2 is a timing chart showing each operation thereof.

1 is a laser diode assembly in which a laser diode 2 and a photodiode 3 are assembled in the same package. 4 is a constant current circuit which makes the current of the laser diode 2 a constant current. The transistor 5 controls the laser diode 2 to blink in response to a light emission control signal sent through the NOR gate 6. signal a
is the control start signal, which changes from H level to L level at the start of control.
level, and is held at L level throughout the control. Signal b is a line start pulse signal, 1
The line printing repetition period T ₀ is set.
7 is a timer for setting the printing period, and its output signal c
is the printing period T ₁ starting from the pulse of signal b
is set. 8 is a flip-flop for setting the sampling period as a switching circuit;
It receives signals a and c via the NAND gate 9, and is set when the signal a or c goes to L level, and its output signal d starts at the beginning of the control start or the start point of the printing pause period _T2. , start the integration described below. Signal e is a video signal,
In FIG. 2, H level corresponds to white, and L level corresponds to black. The signal d is at L level during the printing period _T1 , and the video signal e is made valid for the transistor 5 at this time. and signal d
When the signal becomes H level, the transistor 5 is activated to control the laser diode 2 to emit light, regardless of the video signal e. The signal f is an optical output level signal,
Laser diode 2 by photo diode 3
The photodiode 3 is reverse-biased by the negative power supply _E1 , and its level is proportional to and follows the optical output of the laser diode 2 with a delay. Change. 10 is a comparator, which has a positive potential with respect to the power supply E ₁
Vr is the comparison reference level value, and the mutual difference between the optical output level signal f and the potential Vr, that is, the optical output level signal f
It outputs a signal (hereinafter simply referred to as a mutual difference signal) indicating whether Vr is above (+) or below (-) the potential Vr, and when it is above, an H level signal is output. 11 is a counter, comparator 1
0 becomes H level, and when a predetermined number is reached, flip-flop 8 is reset and its output signal d is set to L level. Reference numeral 12 denotes an integrating circuit, which includes an operational amplifier 13, resistors R ₁ , R ₂ , capacitor C ₁ , etc. When receiving the output signal of the comparator 10, it integrates the output signal according to its positive or negative level. do. 14 is an analog switch,
When the output signal d of the flip-flop 8 is at the L level, the contact _S1 is open and the contact _S2 is closed, holding the output of the integrating circuit 12. When the output signal d is at the H level, the contact S1 is closed. ₁ is closed, contact S ₂ is open,
Integrating circuit 12 receives the output signal of comparator 10 and integrates the output signal. The constant current circuit 4 has a high impedance at the base of the first stage transistor 15, receives the output signal of the integrating circuit 12,
The output signal is kept substantially unchanged over the printing period of the line. transistor 1
5 receives a positive voltage E ₂ and a negative voltage E ₁ at each end, and is set to a constant current according to the output signal of the integrating circuit 12. The second stage transistor 16 receives a voltage corresponding to the current of the transistor 15 at its base, and a laser diode 2 is connected to its load. is set to In addition, resistance
Integrating circuit 12 determined by R ₁ , R ₂ , capacitor C _1, etc.
The time constant is set to be relatively small in order to cope with minute changes in the vicinity of the reference level Vr for the signal f in order to improve the precision of optical control.

The operation of the above configuration will be explained below.

During steady control, control start signal a is at L level. During the printing period _T1 , the output signal d of the flip-flop 8 is at L level, and the contact _S1 of the analog switch 14 is open as shown in FIG.
Contact S ₂ is closed and the integrating circuit 12 is held in its previous state. The NOR gate 6 enables the video signal e, and the laser diode 2 is controlled to blink by the video signal e. The photodiode 3 detects the optical output signal of the laser diode 2, and the signal f changes, but at this time, the contact S ₁
is open and signal f is not used.

When one line of printing is completed and the signal c falls, the flip-flop 8 is set and the signal d becomes H level, the contact _S1 is closed and the contact _S2 is opened.
Integrating circuit 12 starts integrating the output signal of comparator 10. At the same time, the laser diode 2 is continuously driven by the set current of the constant current circuit 4, regardless of the video signal e. The photodiode 3 detects the optical output of the laser diode 2, and the optical output level signal f increases, for example. While the voltage is below the reference level Vr, the comparator 10 is at L level, the integral value of the integrating circuit 12 increases, and the optical output of the laser diode 2 increases. When the optical output level signal f exceeds the reference level Vr, the comparator 10
becomes H level, and the counter 11 counts its rising edge. The integral value of the integrating circuit 12 decreases, and the output of the laser diode 2 decreases. Therefore, the optical output level signal f starts to decrease. By repeating this process, the optical output of the laser diode 2 becomes stable, with the optical output level f fluctuating around the reference level Vr while the temperature of the laser diode 2 becomes constant. When the counter 11 reaches a predetermined count value, the output signal d of the flip-flop 8 becomes L level, the contact S ₁ is opened, the contact S ₂ is closed, and the integration circuit 12 is held at the integral value at that time, and continues. The current of the laser diode 2 during the printing period _T1 is set. In this way, the set current of the constant current circuit 4 is set when the counter 11 confirms multiple times that the detected optical output level signal f has reached a predetermined value. Since there is a reference level Vr or signal f
Even if noise is added to , this means that it has been corrected.

FIG. 3 shows the state of each part from the initial stage when the control power is turned on until the steady state is reached. When the power is turned on, the control start signal a becomes L level.
At this time, if signal b is at L level or has its first falling edge, flip-flop 8 is set. Since it takes a certain amount of time for the rotation of the rotating polygon mirror to start up, the counter 11 does not count during the period from the time _t0 when the power is turned on to the time _t1 when the start-up is almost completed, and therefore the flip-flop 8 is not set. The integration circuit 12 continues to perform an integration operation. And since flip-flop 8 is set,
The laser diode 2 is independent of the video signal e,
Moreover, it is continuously driven by the set current of the constant current circuit 4 depending on the integral value of the integrating circuit 12. When the integral value reaches a steady value at time _t1 , the signal f reaches the potential Vr as in FIG. 2, so the counter 11 starts counting. When a predetermined count value is reached at time _t2 , the flip-flop 8 is reset, and the steady-state control described above is thereafter performed.

(Effects of the Invention) As explained above, according to the present invention, the comparator detects repeated minute changes in the set value of the constant current by the integrating circuit, and determines when these have reached a predetermined level. Since the confirmation is made by counting , the configuration is simplified, high-speed control is possible, and errors due to noise during detection are corrected. Variations in the optical output of the laser diode and changes in characteristics due to temperature are reflected in the counting speed of the counter, allowing uniform light control. At the beginning of control,
Since the laser diode and the integrating circuit operate continuously until the optical output level of the laser diode reaches the reference level, the optical output of the laser diode rises quickly and becomes stable. Furthermore, since it can be adjusted independently as an optical scanning unit, maintenance becomes easy.

[Brief explanation of drawings]

FIG. 1 is a light output control circuit diagram showing an embodiment of the present invention, FIG. 2 is a timing chart showing each operation of FIG. 1, and FIG. 3 is a diagram showing operating characteristics of the integrating circuit when the power is turned on. 2... Laser diode, 4... Constant current circuit, 8...
Flip-flop (switching circuit), 10...
Comparator, 11...Counter, 12...Integrator circuit.

Claims (1)

[Claims] 1. A comparison in which an optical output level signal obtained by detecting the optical output of a laser diode that emits light in response to a video signal is compared with a predetermined reference level value, and a mutual difference signal with the reference level is output. an integrating circuit that integrates the mutual difference signal; a constant current circuit that increases or decreases the current of the laser diode according to the integral value of the integrating circuit; a counter that counts the number of times the positive and negative signs are reversed over a predetermined number of times; and a switching circuit for disabling the integrating function of the integrating circuit and holding the integrated value when the counter has counted the predetermined number. .