JPH0732648A - Optical axis/power adjusting circuit of laser diode - Google Patents

Abstract

PURPOSE:To enable good optical axis collimation adjustment and power adjustment by simple constitution. CONSTITUTION:In a laser drive circuit using a high speed negative feedback loop constituted so that the monitor current Im of a photodiode 2 is forcibly allowed to flow by the current I (the combination of i-16i of 5 current sources 8a-8e) corresponding to an emission intensity command signal (DATA 4-0) and a drive current Iop is allowed to flow to a laser diode 1 so as to obtain the emission quantity P0 corresponding to the monitor current Im, a land 10 becoming the access point from the outside is provided in order to allow the laser diode 1 to emit light by proper power for optical axis collimation adjustment before emission power is adjusted by a trimmable resistor Rt.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a laser diode optical axis / power adjusting circuit for adjusting optical axis collimation and emitting power of a laser diode used as a light source of an optical writing section of an image forming apparatus.

[0002]

2. Description of the Related Art In an image forming apparatus using a laser diode (LD) as a light source, it is required to improve the quality of an output image thereof, and in particular, the demand for the quality of a graphic image is becoming severe.

In order to meet the above requirements, it is desirable to speed up the on / off operation of the LD, which is the light source. However,
The LD has a characteristic that the emission power changes with a temperature change even if the drive current is constant (droop characteristic).

Therefore, the LD is forcibly turned on for each line in the main scanning direction or for each page, the light output is monitored, and the drive current of the LD according to the desired laser light intensity is fixed. Conventional intermittent APC (automatic P
In the ower control system, the stability of light output is poor.

Therefore, the light emission command signal is used as the monitor current of the monitor photodiode (PD) built in the LD,
A real-time APC system has been proposed in which a high-speed negative feedback loop is used to force a drive current according to the monitor current to flow through the LD to obtain a constant light output.

FIG. 6 is a circuit diagram showing an example of the circuit configuration of the real-time APC system. 1 is an LD, 2 is a monitor PD, 3 is a resistor R connected to PD2, and 4 is a trimable resistor. Resistance (semi-fixed volume, etc.) Rt, 5
Is a first differential amplifier having an input connected to PD2 and Rt4, 6 is a second differential amplifier having an input connected to the resistor 3 and the variable resistor 4, 7 is a zener diode, and 8a to 8e are It is five current sources that allow five stages of currents i to 16i to flow.

In FIG. 6, a light emission intensity command signal (DATA4
˜0) corresponding to the current I (= 5 current sources 8a to 8e i to 16i combination), the PD2 monitor current I _m is forced to flow. However,

[0008]

[Equation 1]

( _RT has been adjusted).

Therefore, the light emission amount P _o according to the monitor current I _m
Thus, the drive current I _op flows through the LD1.

At the time of adjusting the LD power, all the DATA 4 to 0 are made active (I = i + 2i + 4i + 8i + 16i) in order to obtain the maximum light emission power. Then, the value Rt of the variable resistor 4 is increased to gradually increase the emission power so that the desired maximum emission power is obtained. In this way, the influence of variations in the characteristics of the constituent elements can be suppressed.

During the optical axis collimation adjustment, the LD1 is caused to emit light to adjust the positions of the coupling lens, the holder and the like which form the optical system of the LD drive board.

[0013]

In the conventional manufacturing process of the LD drive board, the LD and the LD base are fixed to the drive substrate by soldering and thermal caulking, and then the LD is caused to emit light to thereby form a coupling lens and The position of the holder was adjusted to adjust the optical axis collimator, and then the aperture was attached to adjust the power.

In the above adjustment, in order to adjust the maximum light emission power of the LD, there is no choice but to adjust the trimmable resistance, and in order to adjust the optical axes of the aperture and the coupling lens, the original power adjustment is performed by using this drive substrate. L before
In order to make D emit light, a trimmerable resistor is used as a variable resistor, and this variable resistor is rotated in the positive direction at the time of adjusting the optical axis collimation, and is rotated in the reverse direction after the completion of this adjustment to return to the initial value, and the original power adjustment is performed. Was going on.

For this reason, it is necessary that the variable resistor has a structure in which the resistance value can be adjusted in both the forward and reverse directions. However,
Such variable resistors are costly and have a large footprint,
Also, if adjustment takes time and the required accuracy is strict,
The disadvantage is that two types of variable resistors, one for coarse adjustment and one for fine adjustment, are required.

An object of the present invention is to provide a circuit for adjusting the optical axis and power of an LD, which has a simple structure and is well adjusted.

[0017]

To achieve the above object, according to the present invention, a current corresponding to a light emission intensity command signal is supplied as a monitor current for a laser diode, and a stable light emission intensity is obtained by using a high-speed negative feedback loop. In the optical axis / power adjusting circuit of the laser diode including the light source control unit, the power adjusting trimmer resistor and the optical axis collimating adjusting land are provided.

A fixed resistance jig is brought into contact with the land.

A variable resistance jig is brought into contact with the land.

A resistance jig is brought into contact with the land and the voltage value applied to the jig side is made variable.

Further, in the optical axis / power adjusting circuit of the LD, a fixed resistor is mounted for adjusting the optical axis collimation.

The resistance value of the fixed resistor is set to a value not exceeding the maximum rating of the laser diode.

Further, in the optical axis / power adjusting circuit of the LD, a trimmable resistor is mounted for optical axis collimating adjustment.

Further, the trimmable resistor can be separated after the optical axis collimation adjustment.

Further, it is characterized in that a gain adjusting means is provided.

[0026]

In the optical axis / power adjusting circuit of the LD having the above-mentioned structure, the land for adjusting the optical axis collimate is provided. Therefore, the land emits light with an appropriate power before the light emitting power is adjusted by the trimmable resistor. It becomes an access point from the outside.

Further, when adjusting the optical axis collimation, an appropriate jig for fixed resistance value is prepared, and the jig is applied to the land to obtain the required light emission power.

Further, when adjusting the optical axis collimation, a variable resistance jig is applied to the land to change the resistance value,
The desired emission power can be easily obtained.

Further, when adjusting the optical axis collimation, the monitor current is made variable by changing the voltage value on the jig side, so that the desired light emission power can be obtained more reliably.

Further, even if a fixed resistor is mounted for adjusting the optical axis collimation, it can be sufficiently dealt with when the variation of the emission power required for the optical axis collimating adjustment is not so severe.

Further, by suppressing the resistance value of the fixed resistor within a range not exceeding the maximum rating of the LD, it is possible to prevent the LD from changing during the adjustment of the optical axis collimation.

By mounting a trimmable resistor for adjusting the optical axis collimation, the light emission power required for the optical axis collimation adjustment can be obtained easily and accurately.

Further, by cutting the mounted trimmable resistor completely after the optical axis collimation adjustment and opening it, the work of monitoring whether or not the trimmable resistor is cut at an appropriate value is omitted, and the working efficiency is improved. To do.

Furthermore, since the gain can be adjusted on the jig side, variations caused by the characteristics of the LD can be suppressed equivalently.

[0035]

Embodiments of the present invention will be described below with reference to the drawings. The members corresponding to those described in FIG. 6 are designated by the same reference numerals and detailed description thereof will be omitted.

FIG. 1 is a circuit diagram of a first embodiment of the present invention. The circuit shown in FIG. 6 is one of the input parts of a second differential amplifier 6 which is electrically stable by a Zener diode 7.
The difference is that the land 10 is formed by extending from the (Vref portion).

In the first embodiment, the light emission control of the LD 1 and the LD power adjustment are the same as those in the conventional example described above, but when the optical axis collimation adjustment is performed, the current is forcibly supplied by using the land 10. The monitor current I _m is increased to cause the LD1 to emit light. Therefore, since the optical axis collimation adjustment is performed before the emission power adjustment, the LD 1 can easily emit light with an appropriate output.

Specifically, the fixed resistance jig 11 having the fixed resistance R ₁ shown in FIG. 2 and one end of which is grounded is connected to the land 10. Then, since the reference voltage (Vref) in the circuit is applied to the land 10 portion, the current determined by the value of the fixed resistor R ₁ is forced to flow. In addition,
Since the current I described in FIG. 6 is added as the current, it is desirable to set DATA to 0 so that an excessive optical output is not output.

However, since the photoelectric conversion efficiency of the PD2 of the LD1 varies depending on the individual components, the light output varies as a result.
There is a possibility that the optical output required for optical axis collimation adjustment may not be obtained. Therefore, by connecting the variable resistance jig 12 having the variable resistance R _V shown in FIG. 3 to the land 10 and adjusting while changing the resistance value R _V (I = Vref / R _V ), the desired value can be obtained. The optical output of is obtained.

As in the second embodiment of the present invention shown in FIG. 4, the voltage level E is adjusted by using the resistance jig 14 in which one end of the fixed resistor R ₁ is connected to the variable voltage source 13 without being grounded. By doing so (I = (Vref−E) / R ₁ ), the monitor current I _m can be made variable, and variations in characteristics of individual parts can be absorbed.

In this case, as shown in FIG.
Sensor for optical output monitoring, power meter 16, CPU
It is also possible to provide the voltage level adjusting unit 18 including the (central processing unit) 17, monitor the optical output P _{1 of the} LD ₁ , and automatically adjust the voltage level at the variable voltage source 13.

Up to now, the explanation has been made on the premise that the adjustment is made on the jig side, but considering that the variation of the optical output required for the optical axis collimation adjustment is not so severe, it is shown in FIG. As in the third embodiment of the present invention, a fixed resistor R _S is mounted on the Vref portion on the LD driving substrate to
1 may be made to emit light in a certain range.

By the way, in such a case, it is necessary to remove the fixed resistor R _S in order to stop the forced light emission after the optical axis collimation adjustment is completed and to start the original power adjustment. That is, there is a waste of discarding the fixed resistance R _S. Therefore, for example, if pins are set up on the substrate and a socket-shaped resistor is inserted to perform the optical axis collimation adjustment, the optical axis collimation adjustment can be removed at the end so that it can be used even during the adjustment in another LD driving substrate, which is a waste. I can omit it.

It is also possible to use a trimmable chip resistor instead of the fixed resistor. In this case, after completion of the optical axis collimation adjustment, the trimmable chip resistor is cut while observing the light emission output, and the light emission is stopped when the value of the high negative feedback loop reaches a normal value.

Since it may be considered that this monitor is not efficient, it is also possible to separately provide a bias resistor, connect the trimmable chip resistors in parallel, and completely disconnect the trimmable chip resistor at the end of collimation.

In such a case, as described above, there is a possibility that the optical output range in which the optical axis collimation adjustment is possible is exceeded. In this case, the range of variations can be suppressed by providing the jig side (adjuster side) with a gain adjusting means.

[0047]

As described above, since the optical axis / power adjusting circuit of the LD of the present invention has the land for adjusting the optical axis collimate according to the configuration of the first aspect,
The land serves as an access point from the outside for illuminating the LD with an appropriate power before power adjustment, and the structure for adjusting the optical axis collimator is simple, the cost can be reduced, and the adjustment is easy.

According to the second aspect of the invention, the adjustment can be made by bringing the fixed resistance value jig into contact with the land. Therefore, the necessary power can be obtained by preparing the jig necessary for the collimation adjustment. be able to.

According to the third aspect of the invention, since the resistance value is variable, a desired power can be obtained.

According to the fourth aspect of the present invention, the desired power can be more reliably obtained by changing the voltage value on the jig side when adjusting the optical axis collimation.

According to the structure of the fifth aspect, by mounting the fixed resistor, it becomes possible to easily emit light with the power required for the optical axis collimation adjustment.

According to the structure of claim 6, the value of the fixed resistance is suppressed to a range not exceeding the maximum rating of the LD.
It is possible to prevent LD deterioration during optical axis collimation adjustment.

According to the structure of claim 7, a trimmable resistor is mounted for adjusting the optical axis collimation.
Moreover, it becomes possible to emit light with the power required for the accurate adjustment of the optical axis collimation.

According to the structure of the eighth aspect, the trimmable resistor is mounted for adjusting the optical axis collimation, and after the adjustment, the trimmable resistor is completely cut off to be opened. Eliminating the work of monitoring whether or not to improve efficiency.

According to the structure described in claim 9, since the gain adjusting means is mounted on the jig side, it is possible to equivalently suppress the variation caused by the characteristics of the LD.

[Brief description of drawings]

FIG. 1 is a first circuit for adjusting the optical axis and power of an LD according to the present invention.
It is a circuit diagram of an example.

FIG. 2 is an explanatory diagram of a fixed resistance value jig.

FIG. 3 is an explanatory diagram of a variable resistance jig.

FIG. 4 is a circuit diagram of a second embodiment of the present invention.

FIG. 5 is a circuit diagram of a third embodiment of the present invention.

FIG. 6 is a circuit diagram of a conventional real-time APC method.

[Explanation of symbols]

1 ... LD (laser diode), 2 ... PD (photodiode), 3 ... Resistor, 4 ... Trimmable resistor, 5, 6
... Differential amplifier, 7 ... Zener diode, 8a-8e ...
Current source, 10 ... Land, 11 ... Fixed resistance jig, 12
… Variable resistance jig, 13… Variable voltage source, 14… Resistance jig.

Claims (9)

[Claims] 1. An optical axis of a laser diode provided with a light source control unit, which allows a current according to a light emission intensity command signal to flow as a monitor current of a laser diode and obtains stable light emission intensity by using a high-speed negative feedback loop. An optical axis / power adjustment circuit for a laser diode, comprising a trimmable resistor for power adjustment and a land for optical axis collimation adjustment in the power adjustment circuit. 2. A circuit for adjusting the optical axis and power of a laser diode according to claim 1, wherein a jig for fixed resistance value is brought into contact with the land. 3. The circuit for adjusting the optical axis and power of a laser diode according to claim 1, wherein a jig for variable resistance is brought into contact with the land. 4. The laser diode optical axis / power adjustment according to claim 2 or 3, wherein a resistance jig is brought into contact with the land, and a voltage value applied to the jig side is made variable. circuit. 5. An optical axis of a laser diode provided with a light source control unit, which allows a current according to a light emission intensity command signal to flow as a monitor current of a laser diode and obtains stable light emission intensity by using a high-speed negative feedback loop. A circuit for adjusting the optical axis and power of a laser diode, in which a fixed resistor is mounted for adjusting the optical axis collimation in the power adjusting circuit. 6. The optical axis / power adjusting circuit for a laser diode according to claim 5, wherein the resistance value of the fixed resistor is set to a value not exceeding the maximum rating of the laser diode. 7. An optical axis of a laser diode provided with a light source control unit, wherein a current according to a light emission intensity command signal is supplied as a monitor current of a laser diode and a stable light emission intensity is obtained by using a high-speed negative feedback loop. A laser diode optical axis / power adjustment circuit in which a trimmable resistor is mounted for optical axis collimation adjustment in the power adjustment circuit. 8. The optical axis / power adjustment circuit for a laser diode according to claim 7, wherein the trimmable resistor is made separable after the optical axis collimation adjustment. 9. The optical axis / power adjusting circuit for a laser diode according to claim 5, further comprising a gain adjusting means.