JPH04116510A - Light source - Google Patents

Abstract

PURPOSE:To accurately control the quantity of output light by working the surface of a holder counter to a semiconductor light source in black. CONSTITUTION:The surface of a housing recessed part 37 faced to a laser diode 32 as the semiconductor light source mounted on a base plate 31 fixed to a light source holder 30 is worked in black. Therefore, since light generated from the diode 32 is absorbed on the surface of the recessed part 47, light reflected on the surface of the recessed part 47 is not photodetected by a photodetector 36. Namely, the photodetector 36 photodetects only a laser beam L12 radiated by the diode 32 in the direction of the base plate 31, and the output of this photodetector 36 is exactly corresponding to the quantity of output light from the diode 32. Therefore, an operating current I regulated by a driving circuit 70 is exactly corresponding to the desired quantity of output light from the diode 32. Thus, the optical output of the diode 32 is accurately controlled.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a light source device used in optical communications, optical fiber gyros, and the like.

<Prior Art> The configuration of a typical light source device that has been conventionally used as an optical fiber gyro is shown in FIG. The collimating lens 21 fixed to the first holder 11 and the condensing lens 2 fixed to the second holder 12
2, the light is focused and incident on the center of the end face of the optical fiber 2 whose tip is held by the ferrule 3.

The first holder 11 has a cylindrical second holder 12.
, the collimating lens 21 or fixed lens mounting part 1
A second holder 12 fitted with the second holder 1a and designated by the reference numeral 11.
It is attached by welding the peripheral edge of the Thereby, the optical axes of the collimating lens 21 and the condensing lens 22 are simultaneously aligned.

Further, the laser diode l is assembled with adhesive by fitting the light source holder 5 to which the substrate 4 is fixed into the mounting recess 6 formed on the opposite side of the first holder 11 to the second holder 12. The first holder 1 is fixedly attached to the first holder 1.
It is stored in a storage space 7 formed in 1. In this way, the optical axes of the laser diode 1 and the collimating lens 21 are simultaneously aligned.

The ferrule 3 is attached to the second holder 12 by welding the sleeve 8, which is rigged and welded to the ferrule 3, to the surface of the second holder 12 opposite to the first holder 11. Fixed.

When the laser diode 1 outputs the laser beam L1 toward the collimating lens 21, it simultaneously outputs the laser beam L2 in the opposite direction (that is, toward the substrate 4). The laser beam L2 directed toward the substrate 4 is received by a light receiving element 13 formed on the surface of the substrate 4, and the output of this light receiving element 13 is given to a laser drive circuit (not shown). This laser drive circuit defines the operating current to be supplied to the laser diode 1 based on the output of the light receiving element 13, and by regulating the operating current so that the output of the light receiving element 13 becomes a predetermined value, The laser specific power of the laser diode 1 is kept constant regardless of changes in the temperature of the chip.

<Problem to be Solved by the Invention> Since the first and second holders 11 and 12 are fixed to each other by welding as described above, each material constituting the first and second holders 11 and 12 is Both materials must be weldable, and stainless steel is generally used. On the other hand, when the first holder 11 is made of stainless steel, the light reflected from the wall surface of the storage space 7 of the first holder 11 enters the light receiving element 13 due to its high reflectance. For this reason, the light receiving element 13 cannot accurately monitor the output of the laser diode 1, which results in inaccurate control of the operating current of the laser diode, making it impossible to obtain the desired amount of output light. I'm afraid.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a light source device that solves the above-mentioned technical problems and allows accurate control of the amount of output light.

Means for Solving the Problems> A light source device of the present invention for achieving the above object includes a semiconductor light source that outputs output light in at least a first direction and a second direction that are different from each other; an optical member to which the output light in the second direction is guided; a holder to which the optical member is fixed; a light receiving element that receives the output light in the second direction; and an output light amount of the semiconductor light source based on the output of the light receiving element. In the light source device, the surface of the holder facing the semiconductor light source is processed to be black.

According to the above configuration, the surface of the holder holding the optical member facing the semiconductor light source is processed to be black, so the light emitted from the semiconductor light source and reaching the surface of the holder is absorbed by this surface. be done. Therefore, since the light reflected from the surface of the holder is not guided to the light-receiving element, the amount of output light from the semiconductor light source in the light-receiving element can be accurately monitored based only on direct light. Therefore, the drive circuit that drives the semiconductor light source based on the output of the light receiving element described above can reliably control the output light amount of the semiconductor light source to a predetermined value.

<Example> Embodiments will be described in detail below with reference to the accompanying drawings showing embodiments.

FIG. 1 is a sectional view showing the basic configuration of a light source device according to an embodiment of the present invention. This light source device is used as a light source for an optical fiber gyro, for example, and transmits laser light Lll from a laser diode 32, which is a semiconductor light source, mounted on a substrate 31 fixed to a light source holder 30 to a first holder 41. After collimating the light into parallel light using the collimating lens 51, which is a fixed optical member, the second holder 4
The condensing lens 52 fixed to the ferrule 3 condenses the light.
The optical fiber 33 is guided to the center of the end face of the optical fiber 33 whose tip end is fixed to the optical fiber 4.

On the surface of the substrate 31, there is a signal from the laser diode 32 to the substrate 3.
A light receiving element 36 is formed to receive the laser beam L12 output in one direction. 35 is the ferrule 34
This is a sleeve for joining the second holder 42 to the second holder 42, and is fixed to the second holder 42 by, for example, laser welding. Reference numeral 37 denotes a lead for supplying an operating current from a drive circuit to be described later to the laser diode 32, and for supplying the output of the light receiving element 36 to the drive circuit.

The first holder 41 is press-fitted into the mounting recess 45 of the second holder 42, and the light source holder 30 is attached to the mounting recess 45 of the second holder 42.
It is press-fitted into the mounting recess 46 of the holder 41 and attached. In this way, by fixing the holders 30, 41, 42 by press-fitting, a clearance (gap) 9 is created between each holder, as in the case of the configuration shown in FIG.
．． 10, the optical axes of the laser diode 32 and lenses 51 and 52 are accurately aligned.

A storage recess 47 for accommodating the laser diode 32 is formed on the light source holder 30 side of the first holder 41, and has a larger diameter than the storage recess 47 to fix the light source holder 30. The above-mentioned mounting recess 46 is formed. The surface of the storage recess 47 is processed to be black by painting or black metal plating.

FIG. 2 is an electrical circuit diagram showing the electrical configuration of the above light source device. The drive circuit 70 is composed of a semiconductor integrated circuit element (for example, 1R3C02 manufactured by Sharp Corporation) 71, resistors R1 and R2 externally attached to the semiconductor integrated circuit element 71, and a variable resistor VRI. The amount of light output from the diode 32 can be adjusted.

The operating current I of the laser diode 32 is supplied via a line 72 from a resistor R1, and the output of the light receiving element 36 is monitored via a line 73.

The drive circuit 70 controls the operating current I applied to the laser diode 32 so that the output of the light receiving element 36 becomes a predetermined value determined by the setting of the variable resistor R1, etc., and thereby controls the output light amount of the laser diode 32 according to changes in the temperature of the chip. It is kept almost constant by eliminating the effects of In this way, the drive circuit 70 and the light receiving element 36 control the output of the laser diode 32 by feeding back the output of the light receiving element 36.
er Control) circuit.

According to the light source device of this embodiment configured as described above, the surface of the storage recess 47 facing the laser diode 32 is processed to be black, so that the light generated from the laser diode 32 is not transmitted on the surface of the storage recess 47. Or absorbed. Therefore, the light reflected on the surface of the storage recess 47 is not received by the light receiving element 36. That is, the light receiving element 36 receives the laser beam L1 emitted by the laser diode 32 toward the substrate 31.
2 will be received, and the output of this light receiving element 36 will accurately correspond to the output light amount of the laser diode 32. As described above, since the output of the light receiving element 36 accurately corresponds to the optical output of the laser diode 32, the operating current (2) specified by the drive circuit 7o accurately corresponds to the desired output light amount of the laser diode 32. Become. In this way, the optical output of the laser diode 32 can be controlled with high precision.

Test examples by the inventor of the present invention are shown below.

In the test, the voltage V between both terminals of the resistor R1 was determined in two cases: (1) when the inner surface of the storage recess 47 of the first holder 41 was not black-treated, and (2) when the surface of the storage recess 47 was black-treated. I tried to make a comparison.

In other words, since the voltage V between both terminals of the resistor R1 corresponds to the operating current I, if the conditions other than the treatment state of the surface of the storage recess 47 are made the same, the voltage between the cases The change in V corresponds to the change in the operating current I due to the state of light reflection on the surface of the storage recess 47. Therefore, by measuring the voltage V, the effect of the black processing can be evaluated. The blackening process was carried out by painting the surface of the recess 47 with black paint.

Test Example 1 The voltage V was measured with a voltmeter before and after the surface of the storage recess 47 was coated with black powder, and the amount of light output from the lens 51 was measured with a power meter. It was measured. 22Ω for resistor R1, 100Ω for R2
For the variable resistor VRI, a 50Ω resistor was used.

The measurement results are as follows.

Test Example 2 A laser diode 32 different from that used in Test Example 1 was used, and the same measurements as in Test Example 1 were performed. The measurement results are as follows.

As shown in Test Examples 1 and 2 above, there is a clear difference in the voltage V and the amount of light (μW) output from the lens 51 before and after the black coating, and the storage recess 47 It is understood that the operating current I can be controlled with high accuracy by significantly reducing the influence of reflection of laser light on the surface of the substrate. The voltage V before the black painting is smaller than the voltage V after the black painting is because before the black painting, the light receiving element 36 receives direct light from the laser diode 32 as well as the storage recess 4.
This is because the operating current I supplied from the laser drive circuit 70 to the laser diode 36 is limited to a small value since only the reflected light from the surface of the laser diode 5 is received. On the other hand, after refurbishing to black color, the influence of the above-mentioned reflected light can be eliminated, so a large operating current can be supplied and a sufficient amount of light can be obtained.

Note that the present invention is not limited to the above embodiments. For example, in the above embodiment, the output light of the laser diode 32 is collimated by the collimating lens 51 and condensed by the condensing lens 52. When optically coupling to an optical member fixed to a holder consisting of
The present invention is not limited to a configuration in which a semiconductor light source and a lens are combined.

In addition to lenses, examples of optical members include concave mirrors, diffraction gratings, polarizers, and the like. Furthermore, in the above embodiment, the case where the application is applied to an optical fiber gyro is taken as an example, but the present invention is a light source that uses a so-called APC circuit that monitors the output light of a semiconductor light source and keeps the light output almost constant. It is widely applicable to devices. Various other design changes can be made without changing the gist of the present invention.

<Effects of the Invention> As described above, according to the light source device of the present invention, the reflected light from the holder surface is not guided to the light receiving element, so that the light receiving element can accurately monitor the output light amount of the semiconductor light source. become. Therefore, the drive circuit that drives the semiconductor light source based on the output of the light receiving element described above can reliably control the output light amount of the semiconductor light source to a predetermined value, and in this way, the output light amount of the semiconductor light source can be controlled with precision. It will be done well.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing the structure of a light source device of the present invention, FIG. 2 is a block diagram showing its electrical structure, and FIG. 3 is a sectional view showing the structure of a conventional technique. 32... Laser diode (semiconductor light source), 36...
- Light receiving element, 41... First holder, 47... Storage recess, 70... Drive circuit

Claims (1)

[Claims] 1. A semiconductor light source that directs output light in at least a first direction and a second direction that are different from each other, an optical member to which the output light in the first direction is guided, and this optical member. A light source device comprising a fixed holder, a light receiving element that receives output light in the second direction, and a drive circuit that controls the amount of output light of the semiconductor light source based on the output of the light receiving element, A light source device characterized in that a surface facing a semiconductor light source is processed to be black.