JP2001291928A - Optical module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical module which can reduce the number of components, reduces an assembly cost and adjusts a plurality of oscillation wavelengths highly precisely. SOLUTION: The optical module is provided with a first photosensitive level detection means 31 of a semitransparent structure which receives optical signal output from a light emission means 10, a second photosensitive level detection means 13 which receives optical signal transmitted via the first photosensitive level detection means 31 via filter means 23, and a control means 14 which controls operation temperature of the light emitting means 10 in accordance with electric signal output from the first photosensitive level detection means and the second photosensitive level detection means.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical module, and more particularly, to an optical module for stabilizing a wavelength of an output optical signal.

[0002]

2. Description of the Related Art Wavelength division multiplexing (Wavelength)
2. Description of the Related Art In an optical wavelength division multiplexing transmission system (hereinafter, referred to as a WDM system) using a division multiplexing technique, the transmission capacity is increased by increasing the number of wavelengths to be multiplexed. That is, in order to increase the transmission capacity, it is necessary to compress the wavelength interval. However, when the wavelength interval of the optical signal becomes narrow, it is necessary to improve the wavelength accuracy of the optical signal output from the optical module.

[0003] A conventional optical module has a module structure that suppresses a change over time or a change due to an ambient temperature of a wavelength of a laser diode light source and locks a wavelength of an output optical signal. As an optical module having such a module structure, for example, there is an optical module having a wavelength lock function of suppressing wavelength fluctuation of an optical signal.
The wavelength lock function is performed by using, for example, a wavelength detection module called a wavelength locker.

First, an optical module without a built-in wavelength locker will be described with reference to FIGS. FIG.
FIG. 2 shows a side view of an example of the optical module 1. FIG. 2 is a top view of an example of the optical module 1.

The optical module 1 includes a laser diode (hereinafter, referred to as LD) element 10, an LD carrier 11, a photodiode (hereinafter, referred to as PD) carrier 12, a monitor PD 13, and an electro-thermal conversion element (hereinafter, referred to as TEC). ), A first lens 15, a thermistor resistor 16, a mount carrier 17, an optical isolator 18, and a second lens 19.

[0006] An LD element 10 as a light emitting element is installed on an LD carrier 11, and outputs an optical signal in a forward direction and a backward direction. The optical signal output in the forward direction of the LD element 10 is converted into parallel light by the first lens 15 installed on the mount carrier 17 and supplied to the optical isolator 18.

The optical isolator 18 transmits the forward optical signal supplied from the first lens 15 and blocks the reflected light from the second lens 19, which will be described later, in the reverse direction, thereby preventing light reflection. . The optical signal transmitted through the optical isolator 18 is condensed by the second lens 19 and supplied to the optical fiber 20.

The optical signal output in the backward direction of the LD element 10 is transmitted to a monitor PD 1 mounted on a PD carrier 12.
The optical signal output is monitored by 3 and is used for automatic power control (hereinafter, referred to as APC control) for keeping the optical signal output output in the forward direction constant.

The above-described LD carrier 11, PD carrier 12, and first lens 15 are mounted on a TEC 14 via a mount carrier 17. A thermistor resistor 16 is further provided on the mount carrier 17,
The temperature near the LD element 10 is monitored. TEC14
Performs automatic temperature control (hereinafter, referred to as ATC control) so that the temperature near the LD element 10 becomes constant according to the result of temperature monitoring by the thermistor resistor 16.

Next, an optical module having a built-in wavelength locker will be described with reference to FIGS. FIG. 3 shows a side view of an example of the optical module 2. FIG. 4 shows a side view of an example of the optical module 2. The optical module 2 is the same as the optical module 1 shown in FIGS. 1 and 2 except for a part.

The optical module 2 comprises an LD element 10, an LD carrier 11, a PD carrier 12, a monitor PD 13, a TE
C14, first lens 15, mount carrier 17, optical isolator 18, second lens 19, rear lens 21, P
It is configured to include a D carrier 22, an optical filter 23, a beam splitter (hereinafter, referred to as BS) 24, and a monitor PD 25.

The optical signal output in the backward direction of the LD element 10 is collected by the rear lens 21 and supplied to the BS 24. The BS 24 reflects a part of the supplied optical signal and transmits the other part to split the optical signal into two. The optical signal output of one of the branched optical signals is monitored by a monitor PD 25 installed on the PD carrier 22.
APC to keep the optical signal output in the forward direction constant
Used for control. The other branched optical signal is supplied to the monitor PD 13 provided on the PD carrier 12 via the optical filter 23.

As the optical filter 23, a filter whose transmission characteristic is inclined with respect to the wavelength of the optical signal is used. For example, an etalon filter, a low-pass filter, a high-pass filter, a band-pass filter, and the like can be considered. Note that the wavelength fixing control method for locking the wavelength of the optical signal output from the LD
This is performed using the output of D13 and the monitor PD25.

FIG. 5 is a block diagram showing an example for explaining the wavelength fixing control method. A part of the optical signal output in the backward direction of the LD element 10 is reflected by the BS 24-1 and supplied to the monitor PD 25. The LD element 10
Among the optical signals output in the backward direction, the optical signal transmitted through the BS 24-1 is reflected by the BS 24-2 and, for example, passes through a
D13.

The monitor PDs 13 and 25 supply a monitor current as shown in FIG. 6 to a division circuit TEC 26 described later. FIG. 6 is a diagram illustrating an example of a monitor current value output from the monitor PD.

In FIG. 6, the monitor current value output from the PD 25 shows a flat characteristic without wavelength dependence. Also,
The monitor current value output from the PD 13 is
Since the optical signal is supplied through the optical filter 3, the characteristic of the optical filter 23 is shown.

For example, when it is desired to lock the oscillation wavelength to the wavelength λ1 in FIG. 6, the oscillation wavelength of the LD element 10 is set to λ1 by utilizing the fact that the oscillation wavelength of the LD element 10 varies according to the operating temperature. . Then, the monitor current values output from the PDs 13 and 25 are supplied to the division circuit TEC26.

The division circuit TEC 26 divides the supplied monitor current value and outputs a value as shown in FIG.
FIG. 7 is a diagram illustrating an example of a value output from the division circuit TEC.

As shown in FIG. 7, a dividing circuit TEC
The output value of 26 indicates a characteristic that increases or decreases when the oscillation wavelength deviates from λ1. The temperature control circuit 27 controls the TEC 14 according to the value supplied from the division circuit TEC 26, and adjusts the oscillation wavelength of the LD element 10 by controlling the temperature near the LD element 10.

[0020]

However, FIG.
The conventional optical module as shown in FIG. 4 has a problem that the mounting area becomes large because the optical signal is branched into two by the BS 24 or the like. Therefore, the LD element 10 and the monitor PD
The distance between the rear lens 21 and the rear lens 21 is increased, and the rear lens 21 is required. Therefore, there is a problem that the required number of parts increases and the cost increases.

In addition, there is a problem that the number of adjustment parts such as optical axis alignment increases due to an increase in the number of necessary optical parts, and the number of assembling steps increases.

Further, in order to increase the transmission capacity, a single optical module needs a tunable LD element capable of adjusting to several kinds of oscillation wavelengths, and an optical signal output from this tunable LD element is required. It was necessary to improve the wavelength accuracy of the.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and has an optical module capable of reducing the number of components, reducing assembly costs, and adjusting a plurality of oscillation wavelengths with high accuracy. The purpose is to provide.

[0024]

Therefore, in order to solve the above-mentioned problems, an optical module according to claim 1 has a semi-transparent first light receiving level detecting means (for example, a light receiving means) for receiving an optical signal output from a light emitting means. , Monitor PD31 in FIG. 8)
A second light receiving level detecting means (for example, a monitor PD13 in FIG. 8) for receiving the optical signal transmitted through the first light receiving level detecting means via a filter means; and the first light receiving level detecting means and the second light receiving level detecting means. Control means for controlling the operating temperature of the light emitting means according to the electric signal output from the light receiving level detecting means (for example, TEC14 in FIG. 8)
And characterized in that:

As described above, since the first light receiving level detecting means has a semi-transparent structure, it is possible to supply an optical signal transmitted through the first light receiving level detecting means to the second light receiving level detecting means. Therefore, components for splitting the optical signal are not required, and the assembly cost can be reduced.

The optical module according to the second aspect is characterized in that the filter means (for example, the optical filter 2 shown in FIG. 8)
3) attenuating the optical signal transmitted through the first light receiving level detecting means in accordance with the filter characteristic and outputting the attenuated optical signal to the second light receiving level detecting means.

As described above, by attenuating the optical signal supplied to the second light receiving level detecting means in accordance with the filter characteristics, the electric signal output from the first light receiving level detecting means and the electric signal output from the second light receiving level detecting means are attenuated. Difference can be provided with the electrical signal.

Further, the optical module according to the third aspect of the present invention provides the optical module (for example, the optical filter 2 shown in FIG. 8).
Item 3) is characterized in that the filter characteristics fluctuate in accordance with the fluctuation of the incident angle of the optical signal.

As described above, since the filter characteristics can be varied in accordance with the incident angle of the optical signal input to the filter means, a portion of the filter characteristics which can be easily used for detecting the light receiving level can be used.

According to a fourth aspect of the present invention, in the optical module, the control means compares the electric signal output from the first light receiving level detecting means with the electric signal output from the second light receiving level detecting means. Means (for example, a dividing circuit TEC26 in FIG. 11) and a temperature control means (for example, FIG. 11) for controlling the operating temperature of the light emitting means and adjusting the wavelength of an optical signal output from the light emitting means according to the result of the comparison. TEC 14).

As described above, the operating temperature of the light emitting means can be controlled in accordance with the result of comparison between the electric signal output from the first light receiving level detecting means and the electric signal output from the second light receiving level detecting means. The wavelength can be easily adjusted.

Further, the optical module according to the fifth aspect is characterized in that the temperature control means varies the operating temperature of the light emitting means by utilizing the Peltier effect.

As described above, the operating temperature of the light emitting means can be easily adjusted by utilizing the Peltier effect.

According to a sixth aspect of the present invention, in the optical module, the first light receiving level detecting means includes a first fixing means (for example,
It is installed on the PD carrier 30) in FIG.
The filter means is provided on the first fixing means.

As described above, by disposing the first light receiving level detecting means and the filter means in the first fixing means, the distance between the first light receiving level detecting means and the filter means can be reduced. Therefore, the distance between the second light receiving level detecting means and the light emitting means can be reduced, and the size of the optical module can be reduced.

Further, in the optical module according to the present invention, the light emitting means is provided on a second fixing means (for example, the LD carrier 11 in FIG. 18), and the first light receiving level is provided on the second fixing means. A detecting means is provided.

As described above, by providing the light emitting means and the first light receiving level detecting means on the second fixing means, the light emitting means and the first light receiving level detecting means can be integrated on the same substrate. Become. Therefore, when the number of components can be reduced, the size of the optical module can be reduced.

In the optical module according to the present invention, the light emitting means (for example, the LD element in FIG. 22) for changing the oscillation wavelength according to the operating temperature, and the branching means for branching the optical signal output from the light emitting means. (For example, FIG. 2
2), first light receiving level detecting means (for example, monitor PD25 in FIG. 22) for receiving one branched optical signal, and receiving another branched optical signal via a filter means. A second light receiving level detecting means (for example, monitor PD13 in FIG. 22) and a first control for controlling an operating temperature of the light emitting means according to electric signals output from the first light receiving level detecting means and the second light receiving level detecting means; Means (for example, TEC14 in FIG. 22)
-1) and second control means (for example, TEC 14-2 in FIG. 22) for controlling the operating temperature of the filter means according to the oscillation wavelength of the light emitting means.

As described above, the provision of the first control means and the second control means makes it possible to separately adjust the operating temperature of the light emitting means and the operating temperature of the filter means.
Therefore, it is possible to adjust the wavelength of the optical signal output from the light emitting unit with high accuracy.

According to a ninth aspect of the present invention, in the optical module, the filter means attenuates the other optical signal in accordance with a filter characteristic and outputs the attenuated optical signal to the second light receiving level detecting means. It is characterized by.

As described above, by attenuating the optical signal supplied to the second light receiving level detecting means in accordance with the filter characteristic, the electric signal outputted from the first light receiving level detecting means and the electric signal outputted from the second light receiving level detecting means are outputted. Difference can be provided with the electrical signal.

The optical module according to claim 10 is
The filter means is characterized in that the filter characteristic fluctuates in accordance with a change in an incident angle of the optical signal.

As described above, since the filter characteristics can be varied in accordance with the incident angle of the optical signal input to the filter means, a portion of the filter characteristics which can be easily used for detecting the light receiving level can be used.

The optical module according to claim 11 is
The first control means compares the electric signal output from the first light reception level detection means with the electric signal output from the second light reception level detection means (for example, FIG. 24).
And a first temperature control means (for example, a temperature control circuit in FIG. 24) that controls the operating temperature of the light emitting means according to the result of the comparison and adjusts the wavelength of an optical signal output from the light emitting means. 53, TEC14-
1).

As described above, the operating temperature of the light emitting means can be controlled according to the result of comparison between the electric signal output from the first light receiving level detecting means and the electric signal output from the second light receiving level detecting means. The wavelength can be easily adjusted.

The optical module according to claim 12 is
The second control means responds to a temperature detection means (for example, a thermistor resistor 16-2 in FIG. 24) for detecting an operation temperature of the filter means and an operation temperature set for each oscillation wavelength of the light emission means. Reference value output means for outputting a reference value (for example, REF circuits 42 to 4 in FIG. 24)
5) a comparison means (for example, a comparison circuit 40 in FIG. 24) for comparing a value corresponding to an operating temperature outputted from the temperature detection means with the reference value, and an operation of the filter means according to a result of the comparison. And a second temperature control means (for example, a temperature control circuit 27 in FIG. 24) for controlling the temperature.

As described above, since the operating temperature of the filter means can be adjusted for each oscillation wavelength in accordance with the value corresponding to the operating temperature output from the temperature detecting means and the reference value, the optical signal output from the light emitting means can be adjusted. Can be adjusted with high precision.

The optical module according to claim 13 is
The light emitting means is characterized by being constituted by a laser diode having an array structure (for example, the structure in FIG. 25) or a tandem structure (for example, the structure in FIG. 26).

As described above, even if the light emitting means is an optical module having a laser diode having an array structure or a tandem structure, the oscillation wavelength of each laser diode can be adjusted with high accuracy.

The optical module according to claim 14 is
The filter means is an etalon filter.

As described above, by using the etalon filter as the filter means, the second light receiving level detecting means can receive an optical signal having periodicity. Therefore, it is possible to adjust the optical signal output from the light emitting means to a wide range of oscillation wavelength.

The optical module according to claim 15 is:
Light emitting means (for example, the LD element 10 in FIG. 23);
A first temperature control unit (for example, TEC 14-1 in FIG. 23) for controlling the temperature of the light emitting unit, and a first light receiving unit (for example, FIG. 23) for receiving light from the light emitting unit.
, A second light receiving means (for example, monitor PD13 in FIG. 23) for receiving light from the light emitting means via a filter means, and a second temperature control means for controlling the temperature of the filter means. (For example, TEC 14-2 in FIG. 23).

As described above, the provision of the first temperature control means and the second temperature control means makes it possible to separately adjust the operating temperature of the light emitting means and the operating temperature of the filter means. Therefore, it is possible to adjust the wavelength of the optical signal output from the light emitting unit with high accuracy.

The optical module according to claim 16 is:
The filter means (for example, the optical filter 23 in FIG. 23) is a Fabry-Perot etalon.

As described above, by using the etalon filter as the filter means, the second light receiving means can receive an optical signal having periodicity. Therefore, it is possible to adjust the optical signal output from the light emitting means to a wide range of oscillation wavelength.

The optical module according to claim 17 is:
Temperature measuring elements (for example, thermistor resistors 16-1 and 16-2 in FIG. 23) are arranged on the first temperature control means and the second temperature control means, respectively. I do.

As described above, by disposing the temperature measuring elements on the first temperature control means and the second temperature control means, respectively, it is possible to adjust the operating temperatures of the light emitting means and the filter means. it can.

The optical module according to claim 18 is:
First branching means (for example, BS24- in FIG. 28) for branching the light from the light emitting element to the first light receiving means.
1) and second branching means (for example, BS in FIG. 28) for branching the light from the light emitting element to the second light receiving means.
24-2).

As described above, by installing the first branching means and the second branching means, the light from the light emitting means is transmitted to the first branching means.
And a second light receiving means.

The optical module according to claim 19 is:
The first light receiving means is a light receiving element having a semi-transparent structure (for example, 31 in FIG. 30), and the filter means filters the light of the first light receiving means to produce the second light receiving means. Is output.

As described above, since the first light receiving means has a semi-transparent structure, an optical signal transmitted through the first light receiving means is transmitted to the second light receiving means.
Can be supplied to the light receiving means. Therefore,
Components for splitting the optical signal are not required, and the assembly cost can be reduced.

The optical module according to claim 20 is
A light emitting unit (for example, the LD element 10 in FIG. 8; a translucent first light receiving unit (for example, a monitor PD31 in FIG. 8) for receiving light from the light emitting unit);
A second light receiving means (for example, a monitor PD13 in FIG. 8) for receiving light from the light emitting means transmitted through the light receiving means through a filter means, and a first temperature control means for controlling the temperature of the light emitting means. (For example, TEC in FIG. 8
14).

As described above, since the first light receiving means has a semi-transparent structure, an optical signal transmitted through the first light receiving means is transmitted to the second light receiving means.
, And a component for splitting the optical signal is not required, and the assembly cost can be reduced. Further, since the operating temperature of the light emitting means can be controlled, the wavelength of the optical signal can be easily adjusted.

Note that the description in parentheses is provided for easy understanding, and is merely an example.

[0065]

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

FIG. 8 is a side view of a first embodiment of the optical module according to the present invention. FIG. 9 shows a top view of the first embodiment of the optical module of the present invention. The optical module 3 is L
D element 10, LD carrier 11, PD carrier 12, monitor PD 13, TEC 14, first lens 15, thermistor resistor 16, mount carrier 17, optical isolator 1
8, second lens 19, optical filter 23, PD carrier 3
0 and the monitor PD 31.

An LD element 10 as a light emitting element is installed on an LD carrier 11 and outputs an optical signal in a forward direction and a backward direction. The optical signal output in the forward direction of the LD element 10 is converted into parallel light by the first lens 15 installed on the mount carrier 17 and supplied to the optical isolator 18.

The optical isolator 18 transmits light signals in the forward direction supplied from the first lens 15 and blocks reflected light in the reverse direction supplied from the second lens 19 to be described later, thereby preventing light reflection. . The optical signal transmitted through the optical isolator 18 is condensed by the second lens 19 and supplied to the optical fiber 20.

The optical signal output from the LD element 10 in the backward direction is monitored by a semi-transparent monitor PD 31 installed on the PD carrier 30. The monitor PD 31 realizes translucency (for example, transmittance of 50% or less) by thinning the absorption layer of the photodiode.

The PD carrier 30 on which the monitor PD 31 is installed is provided with a hole 3 at a position facing the light receiving section of the monitor PD 31.
2 are provided. That is, the optical signal output in the backward direction of the LD element 10 passes through the monitor PD 31 having a semi-transparent structure, passes through the hole 32 provided in the PD carrier 30, and is supplied to the optical filter 23. Then, the optical signal supplied to the optical filter 23 is supplied to the monitor PD 13 installed on the PD carrier 12 via the optical filter 23.

The above-described LD carrier 10, PD carrier 12, first lens 15, optical filter 23, and PD
The carrier 30 is mounted on the TEC 14 by the mount carrier 17.
Is installed through. A thermistor resistor 16 is provided on the LD carrier 11 and monitors the temperature near the LD element 10. The TEC 14 can adjust the temperature near the LD element 10 by using, for example, the Peltier effect.

When the operating temperature fluctuates, the LD element 10 shown in FIG.
0, the oscillation wavelength fluctuates.
A desired oscillation wavelength can be obtained by adjusting the temperature in the vicinity. FIG. 10 is a diagram illustrating an example for explaining the temperature characteristic of the oscillation wavelength of the LD element 10. In the example of FIG. 10, the LD element 10 has a temperature dependence of the oscillation wavelength of 0.09 n.
m / ° C.

Since the monitor PDs 13 and 31 have temperature characteristics in light receiving sensitivity, they are installed on the TEC 14 via the PD carriers 12 and 30 like the LD element 10, and the temperature around them is adjusted.

The optical filter 23 to which the optical signal transmitted through the monitor PD 31 having the semi-transparent structure is supplied is composed of, for example, an etalon filter, a low-pass filter, a high-pass filter, a band-pass filter and the like.

Next, a wavelength fixing control method for locking the wavelength of the optical signal output from the LD element 10 will be described with reference to FIG. FIG. 11 is a block diagram illustrating an example for explaining the wavelength fixing control method.

The optical signal output in the backward direction of the LD element 10 is supplied to a monitor PD 31 having a translucent structure. The optical signal transmitted through the monitor PD 31 is, for example, an optical filter 2
Monitor PD1 via a bandpass filter used as
3 is supplied. The monitor PDs 13 and 31 divide the monitor current as shown in FIG.
6

In FIG. 6, the monitor current value output from the monitor PD 31 has a flat characteristic without wavelength dependence.
The monitor current value output from the monitor PD 13 is
Since an optical signal is supplied via the optical filter 23,
The characteristics of the optical filter 23 will be described. For example, FIG. 6 shows a monitor PD when a bandpass filter is used for the optical filter 23.
13 is a monitor current output from

The dividing circuit TEC 26 divides the supplied monitor current value and outputs, for example, the value as shown in FIG. The output value of the division circuit TEC26 shows a characteristic of increasing or decreasing when the oscillation wavelength deviates from λ1. The temperature control circuit 27 controls the TEC 14 according to the value supplied from the division circuit TEC 26,
The oscillation wavelength of the LD element 10 can be adjusted by controlling the temperature in the vicinity.

Next, a monitor current output from the monitor PD 13 when an etalon filter is used as the optical filter 23 will be described with reference to FIG. FIG. 12 is a diagram illustrating an example of a monitor current value output from the monitor PD 13.

When an etalon filter is used as the optical filter 23, the wavelength transmission characteristics of the etalon filter are periodically repeated, so that the monitor current value output from the monitor PD 13 has a characteristic as shown in FIG. That is,
By controlling the TEC 14 to adjust the oscillation wavelength of the LD element 10, it becomes possible to lock to a plurality of oscillation wavelengths, for example, λ1 to λ4 in FIG.

Here, the principle of the etalon filter will be briefly described with reference to FIG. FIG. 13 is a diagram illustrating an example of the principle of the etalon filter.

In FIG. 13, a parallel plate or a parallel film having a refractive index n and a thickness h is provided in a medium having a refractive index n ', and a plane wave is incident from the top at θ'. The traveling light travels at an angle of θ represented by the following equation (1), but reaches the lower surface and is partially reflected.

Θ = sin ⁻¹ [(n ′ / n) sin θ ′] (1) The reflected light reaches the upper surface again, is reflected, and travels at an angle of θ. As described above, since reflection is repeated on the upper surface and the lower surface, countless light wave components having the same propagation angle cause multiple interference. The wave vectors of a plane wave traveling downward and upward in a parallel plate or a parallel film are κ ₊ and κ _{−, respectively.}
Then, the amplitude of these plane waves becomes exp (−jκ
_- r), is proportional to exp (-jκ ₊ r), the phase rotation provided between propagating a thickness h, equal to -nκ ₀ hcosθ. Therefore, when making one round trip, a phase rotation of -φ represented by the following equation (2) is accompanied.

Φ = nκ ₀ hcos θ (κ ₀ = 2π / λ = ω / c) (2) Assuming that the transmittance of the parallel plate or the parallel film at the upper and lower boundary surfaces with respect to the light wave is R, T, The transmittance in a flat plate or a parallel film is represented by the following equation (3).

Transmittance = − (1−R) ² / (1−R) ² +4 sin ² (φ2) (3) As described above, when φ = 2mπ is satisfied, light waves generated by repeated reflection When the components overlap in phase, resonance can be generated, and characteristics as a filter can be obtained. The peak interval FSR of the filter characteristic at this time is expressed by the following equation (4).

FSR = c / 2 ^* n ^* L (c: speed of light, L: thickness of etalon) (4) Returning to FIGS. 8 and 9, an etalon filter is used for the optical filter 23. In this case, the filter characteristic changes as shown in FIG. 14 by changing the incident angle of the optical signal to the etalon filter. FIG. 14 is a diagram illustrating an example for explaining the incident angle dependence of the etalon filter. Therefore, the peak of the etalon filter can be shifted by changing the incident angle of the optical signal to the etalon filter.

For example, the optical filter 23 of the optical module 3
When an etalon filter of FSR 100 GHz is used, the oscillation wavelength of the LD element 10 may be shifted from the desired lock wavelength of the etalon filter by ± 0.4 nm at the maximum.

FIG. 15 shows an example of the filter characteristics of the etalon filter when the incident angles are 0 ° and 3 °. For example, if the wavelength shift is 1 nm when the incident angle of the optical signal to the etalon filter is 0 °, the oscillation wavelength of the LD element 10 is set to be desired by setting the incident angle of the optical signal to the etalon filter to 3 °. Can be locked to the oscillation wavelength.

Therefore, in order to realize the optical module 3 capable of changing the peak of the etalon filter by about ± 0.4 nm, a structure capable of changing the incident angle by about ± 3.0 ° may be used.

Similarly, when using an etalon filter having an FSR of 200 GHz or more, a structure capable of changing the incident angle by about ± 40 ° may be used so that the maximum deviation amount of the oscillation wavelength of the LD element 10 can be corrected.

The optical signal supplied to the monitor PD 13 of the optical module 3 is a diffused light, and a part of the optical signal is absorbed by the monitor PD 31 having a semi-transparent structure. .

Therefore, the optical module 3 is
It is necessary to make the distance between 0 and the monitor PD 13 as close as possible and raise the transmittance of the monitor PD 31 to the limit level of the monitor current value of the monitor PD 31. For example, the distance between the LD element 10 and the monitor PD 13 is 6 mm or less,
The transmittance of D31 is desirably 50% or more.

As described above, the optical module 3 can reduce the assembly cost by reducing the number of parts.

FIG. 16 is a side view of a second embodiment of the optical module according to the present invention. FIG. 17 shows a top view of a second embodiment of the optical module of the present invention. Note that FIGS.
The optical module 3 of 7 has the same configuration as that of FIGS. 8 and 9 except for a part, and the same portions are denoted by the same reference numerals and description thereof is omitted.

In the optical module 3, the optical filter 23 has a PD
It is installed on the carrier 30. The optical filter 23 is P
The D carrier 30 is installed on the surface opposite to the surface on which the monitor PD 31 having the translucent structure is installed. Note that the optical filter 23 is installed so as to cover the hole 32 provided in the PD carrier 30.

That is, the optical signal output in the backward direction of the LD element 10 passes through the monitor PD 31 and
Is supplied to the optical filter 23 through the hole 32 provided in the first embodiment, but the distance between the monitor PD 31 and the optical filter 23 can be reduced. Therefore, the distance between the monitor PD 13 and the LD element 10 can be reduced.

FIG. 18 is a side view of a third embodiment of the optical module according to the present invention. FIG. 19 shows a top view of a third embodiment of the optical module of the present invention. In addition, FIG.
The optical module 9 of FIG. 9 has the same configuration as that of FIGS. 8 and 9 except for a part, and the same portions are denoted by the same reference numerals and description thereof is omitted.

The optical module 3 integrates an LD element 10 and a monitor PD 31 having a translucent structure, and forms an LD carrier 11.
Installed above. Note that the LD element 10 and the monitor PD3
Since 1 is a semiconductor element, they can be integrated on the same substrate.

Therefore, the number of parts of the optical module 3 can be reduced, and the assembly cost can be reduced.

Next, a tunable LD element that can be locked to a plurality of oscillation wavelengths by using an etalon filter for the optical filter 23 will be described.

For example, as described above with reference to FIG. 10, when the operating temperature of the LD element changes, the oscillation wavelength changes. Therefore, a desired oscillation wavelength can be obtained by adjusting the temperature near the LD element 10. Assuming that the temperature dependence of the oscillation wavelength is 0.1 nm / ° C., 100 GHz
WDM systems have an adjacent wavelength interval of 0.8 nm.
That is, when the operating temperature of the LD element 10 is changed by 8 ° C., the oscillation wavelength can be moved to the adjacent wavelength.

When the etalon filter is used as the optical filter 23, the monitor current output from the PD 13 has the wavelength transmission characteristic periodically repeated as described above with reference to FIG. When locking the oscillation wavelength, it is desirable to fix the oscillation wavelength to the steepest part of the wavelength transmission characteristic graph of FIG. This is because if the inclination is large, the wavelength fluctuation can be detected with high accuracy.

As described above with reference to FIG. 14, the method of locking at the largest slope portion of the wavelength transmission characteristic graph is adjusted by changing the incident angle of the optical signal to the etalon filter. Is possible. When the oscillation wavelength is locked, the oscillation wavelength may be locked to either the right slope or the left slope of the wavelength transmission characteristic graph.

Here, the filter characteristics of the etalon filter fluctuate due to fluctuations in the refractive index temperature of the material and fluctuations in the resonator length due to thermal expansion of the material. Therefore,
The temperature dependence of the filter characteristics of the etalon filter will be described with reference to FIG. FIG. 20 is a diagram illustrating an example for explaining the temperature dependence of the filter characteristic.

As for the filter characteristics of the etalon filter shown in FIG. 20, the peak wavelength shifts to a long wave while maintaining the waveform shape at high temperatures. The peak fluctuation amount of the etalon filter is determined by the material, and is about 8 to 22 pm / ° C.

In the optical modules of the first to third embodiments, the LD carrier 11 in which the LD element 10 is installed and the optical filter 23 are provided on the same TEC 14. Therefore, when a desired oscillation wavelength is obtained by adjusting the operating temperature of the LD element 10, the operating temperature of the etalon filter also fluctuates, and the peak wavelength fluctuates.

For this reason, it is necessary to design the FSR of the etalon filter in consideration of the temperature dependence of the filter characteristics. FIG. 21 is a diagram illustrating an example of the peak interval FSR designed in consideration of the temperature dependence of the filter characteristic.

Assuming that the temperature dependency of the oscillation wavelength of the LD element 10 is 0.1 nm / ° C., it is possible to move the oscillation wavelength to an adjacent wavelength by changing the operating temperature by 8 ° C. Wavelength λ
Assuming that the operating temperature at which the oscillation wavelength can be locked to 1 is 15 ° C., the operating temperature at which the oscillation wavelength can be locked at wavelength λ2 is 23 ° C., the operating temperature at which the oscillation wavelength can be locked at wavelength λ3 is 31 ° C., and the oscillation wavelength is at wavelength λ4. The operating temperature at which can be locked is 39 ° C.

Therefore, the FSR of the etalon filter is WD
The design should be such that the temperature dependence of the etalon filter is adjusted by 8 ° C. from 100 GHz (about 0.8 nm) of M pitch.

On the other hand, if the LD carrier 11 on which the LD element 10 is installed and the optical filter 23 are arranged on different TECs, the operating temperature of the LD element 10 and the operating temperature of the optical filter 23 are separately adjusted. It becomes possible.

FIG. 22 is a side view of a fourth embodiment of the optical module according to the present invention. FIG. 23 is a top view of a fourth embodiment of the optical module according to the present invention. 22 and 2
The optical module 3 has the same configuration as that of FIGS. 3 and 4 except for a part, and the same portions are denoted by the same reference numerals and description thereof is omitted.

The optical module 3 comprises an LD element 10, an LD carrier 11, a PD carrier 12, a monitor PD 13, a TE
C14-1, TEC14-2, first lens 15, mount carrier 17-1, mount carrier 17-2, optical isolator 18, second lens 19, rear lens 21, P
It is configured to include a D carrier 22, an optical filter 23, a BS 24, and a monitor PD 25.

The mount carrier 1 is provided on the TEC 14-1.
The LD carrier 11, the first lens 15, and the rear lens 21 on which the LD element 10 is mounted are mounted on the mount carrier 17-1. Also,
A mount carrier 17-2 is installed on the TEC 14-2, and the monitor PD1 is mounted on the mount carrier 17-2.
3, the PD carrier 12, the optical filter 23, the PD carrier 22 with the monitor PD 25, and the BS
24 are installed.

A thermistor resistor 16-1 is provided on the LD carrier 11 and a thermistor resistor 16-2 is provided on the mount carrier 17-2 to monitor the temperature in the vicinity. Therefore, the operating temperature of the LD element 10 and the operating temperature of the optical filter 23 can be separately monitored.

The design of the temperature characteristics of the etalon filter will be described below. First, the temperature variable range of the TEC 14-2 in which the etalon filter is installed is defined as A ° C., the temperature characteristic of the etalon filter is defined as B nm / ° C., and the FSR of the etalon filter is defined as C nm. When the oscillation wavelength is locked to one slope of the wavelength transmission characteristic graph, the etalon filter can be varied more than the FSR by adjusting the operating temperature when the following equation (5) is satisfied.

A × B ≧ C (5) When the oscillation wavelength is locked to the slopes on both sides of the wavelength transmission characteristic graph, the etalon filter operates at the operating temperature when the following equation (6) holds. By adjusting the FS
Variables of R or more are possible.

A × B ≧ C / 2 (6) Specifically, the FSR of the etalon filter is 10
0 GHz (about 800 pm), TEC14-2 equipped with an etalon filter has a variable temperature range of 10 to 65 ° C.
In the case of, the temperature characteristic of the etalon filter that can be locked to any wavelength is 14.5 pm / ° C. when locked on one side of the wavelength transmission characteristic graph and 7.2 pm / ° C. when locked on both sides of the graph. Is calculated.

Therefore, by selecting an etalon filter material that satisfies the above temperature characteristics, an optical module that can be locked to any wavelength can be realized.

In FIGS. 22 and 23, the oscillation wavelength of the optical signal output from the LD element 10 is L using the TEC 14-1.
By adjusting the operating temperature of the D element 10, it is locked to a desired oscillation wavelength. The temperature characteristic of the etalon filter is set so that the desired oscillation wavelength is locked to, for example, one side of the wavelength transmission characteristic graph by adjusting the operating temperature of the etalon filter using the TEC 14-2.

FIG. 24 is a block diagram showing an example for explaining the wavelength fixing control method. First, the operating temperature of the etalon filter is set for each desired oscillation wavelength. By switching the switch 41, the operating temperature 42 to 45 set for each channel, in other words, the thermistor resistance value at the desired operating temperature becomes the switch 41.
Is supplied to the comparison circuit 40 via the.

The temperature control circuit 27 includes a thermistor resistor 16
It is possible to control the TEC 14-2 according to the comparison result between the thermistor resistance value supplied from −2 and the thermistor resistance value supplied via the switch 41, and adjust the operating temperature of the etalon filter.

On the other hand, the monitor current output from the monitor PD 13 is supplied to the comparison circuit 52 via the amplifier circuit 46. The monitor current output from the monitor PD 25 is supplied to the amplifier circuits 47 to 50. Amplifier circuits 47 to 50
Is set to an amplification value that provides a desired oscillation frequency for each channel. By switching the switch 51, one of the outputs of the amplification circuits 47 to 50 is output to the comparison circuit 52.
Supplied to

The temperature control circuit 53 controls the TEC 14-1 according to the comparison result between the monitor current supplied through the amplifier 46 and the monitor current supplied through the switch 51, and controls the operating temperature of the LD element 10. Can be adjusted.

By adjusting the operating temperature of the etalon filter, an optical module lockable to any wavelength can be realized. Therefore, an arrayed LD element as shown in FIG. 25 or a tandem LD as shown in FIG. The present invention can be applied to an optical module using an element or the like.

In the optical modules of the first to fourth embodiments described above, the oscillation wavelength is adjusted using the optical signal output in the backward direction of the LD element 10, but is adjusted in the forward direction. It is also possible to use the output optical signal.

FIG. 27 is a side view of a fifth embodiment of the optical module according to the present invention. FIG. 28 is a top view of a fifth embodiment of the optical module according to the present invention. The optical module 3 of FIG. 27 and FIG.
Each of 4-1 and 24-2 branches into two. BS24-
The optical signal split at 1, 24-2 is applied to the PD carrier 22.
Are supplied to the monitor PD 25 installed on the PD carrier 12 and the monitor PD 13 installed on the PD carrier 12. Other processes are the same as in the fourth embodiment, and a description thereof will be omitted.

FIG. 29 is a side view of a sixth embodiment of the optical module according to the present invention. FIG. 30 is a top view of a sixth embodiment of the optical module of the present invention. The optical module 3 of FIGS. 29 and 30 is the same as the TEC 1 of the optical module 3 of FIG.
4 and the mount carrier 14 are divided into two.

As described above, by dividing the TEC 14 and the mount carrier 14 into two, the operating temperature of the LD element 10 and the operating temperature of the filter 23 can be separately adjusted. The other processes are the same as those in the above-described embodiments, and the description is omitted.

[0129]

As described above, according to the present invention, the first light receiving level detecting means has a semi-transparent structure, so that the optical signal transmitted through the first light receiving level detecting means is supplied to the second light receiving level detecting means. It is possible to do. Therefore, components for splitting the optical signal are not required, and the assembly cost can be reduced.

Also, the provision of the first control means and the second control means makes it possible to separately adjust the operating temperature of the light emitting means and the operating temperature of the filter means. Therefore, it is possible to adjust the wavelength of the optical signal output from the light emitting unit with high accuracy.

[Brief description of the drawings]

FIG. 1 is a side view of an example of an optical module.

FIG. 2 is a top view of an example of the optical module.

FIG. 3 is a side view of another example of the optical module.

FIG. 4 is a top view of another example of the optical module.

FIG. 5 is an example block diagram illustrating a wavelength fixing control method.

FIG. 6 is a diagram illustrating an example of a monitor current value output from a monitor PD;

FIG. 7 is a diagram illustrating an example of a value output from a division circuit TEC;

FIG. 8 is a side view of a first embodiment of the optical module of the present invention.

FIG. 9 is a top view of the first embodiment of the optical module of the present invention.

FIG. 10 is a diagram illustrating an example of a temperature characteristic of an oscillation wavelength of an LD element.

FIG. 11 is a block diagram illustrating an example for explaining a wavelength fixing control method.

FIG. 12 is a diagram illustrating an example of a monitor current value output from a monitor PD;

FIG. 13 is a diagram illustrating an example of the principle of an etalon filter.

FIG. 14 is a diagram illustrating an example of an incident angle dependence of an etalon filter.

FIG. 15 is a diagram illustrating an example of a filter characteristic when incident angles are 0 ° and 3 °.

FIG. 16 is a side view of a second embodiment of the optical module of the present invention.

FIG. 17 is a top view of a second embodiment of the optical module of the present invention.

FIG. 18 is a side view of a third embodiment of the optical module of the present invention.

FIG. 19 is a top view of a third embodiment of the optical module of the present invention.

FIG. 20 is a diagram illustrating an example for explaining temperature dependence of a filter characteristic;

FIG. 21 is a diagram illustrating an example of a peak interval FSR designed in consideration of temperature dependence of a filter characteristic;

FIG. 22 is a side view of a fourth embodiment of the optical module of the present invention.

FIG. 23 is a top view of a fourth embodiment of the optical module of the present invention.

FIG. 24 is an example block diagram illustrating a wavelength fixing control method.

FIG. 25 is a configuration diagram of an example of an arrayed LD element.

FIG. 26 is a configuration diagram of an example of a tandem LD element.

FIG. 27 is a side view of a fifth embodiment of the optical module of the present invention.

FIG. 28 is a top view of a fifth embodiment of the optical module of the present invention.

FIG. 29 is a side view of a sixth embodiment of the optical module of the present invention.

FIG. 30 is a top view of a sixth embodiment of the optical module of the present invention.

[Explanation of symbols]

 Reference Signs List 3 optical module 10 laser diode element 11 laser diode carrier 12, 30, 22 photodiode carrier 13, 25, 31 monitor photodiode 14, 14-1, 14-2 electro-thermal conversion element 15 first lens 16, 16-1 , 16-2 Thermistor resistance 17, 17-1, 17-2 Mount carrier 18 Optical isolator 19 Second lens 21 Rear lens 23 Optical filter 24 Beam splitter 26 Division circuit TEC 27, 53 Temperature control circuit 40, 52 Comparison circuit 41, 51 switch 46-50 amplifier circuit

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Yoshimitsu Sakai 1-3-3 Kita-Nanajo-Nishi, Kita-ku, Sapporo-city, Hokkaido 1 Fujitsu Hokkaido Digital Techonoji Co., Ltd. (72) Inventor Masaki Kuribayashi Kita-ku, Sapporo, Hokkaido 4-3 Nanjo Nishi 1 F-Term within Fujitsu Hokkaido Digital Technology Co., Ltd. F-term (reference) 5F073 AB04 AB25 EA03 FA02 FA25 GA22

Claims (20)

[Claims] 1. A first light receiving level detecting means having a semi-transparent structure for receiving an optical signal output from a light emitting means, and a light receiving means for receiving the optical signal transmitted through the first light receiving level detecting means via a filter means. (2) An optical module comprising: a light receiving level detecting means; and a control means for controlling an operating temperature of the light emitting means according to an electric signal output from the first light receiving level detecting means and the second light receiving level detecting means. 2. The apparatus according to claim 1, wherein the filter unit attenuates an optical signal transmitted through the first light receiving level detecting unit in accordance with a filter characteristic, and outputs the attenuated optical signal to the second light receiving level detecting unit. The optical module according to claim 1. 3. An optical module according to claim 2, wherein said filter means changes said filter characteristic in accordance with a change in an incident angle of said optical signal. 4. The comparison means for comparing an electric signal output from the first light reception level detection means with an electric signal output from the second light reception level detection means, and the control means according to a result of the comparison. 2. The optical module according to claim 1, further comprising a temperature control unit that controls an operating temperature of the light emitting unit and adjusts a wavelength of an optical signal output from the light emitting unit. 5. The optical module according to claim 4, wherein said temperature control means changes an operating temperature of said light emitting means using a Peltier effect. 6. The optical module according to claim 1, wherein said first light receiving level detecting means is provided on a first fixing means, and said filter means is provided on said first fixing means. . 7. The optical module according to claim 1, wherein the light emitting means is provided on a second fixing means, and the first light receiving level detecting means is provided on the second fixing means. . 8. A light emitting means for changing an oscillation wavelength according to an operating temperature; a branching means for branching an optical signal output from the light emitting means; a first light receiving level detecting means for receiving one of the branched optical signals. A second light receiving level detecting means for receiving another branched optical signal through a filter means; and the light emitting means in accordance with an electric signal output from the first light receiving level detecting means and the second light receiving level detecting means. An optical module, comprising: first control means for controlling an operating temperature of the light emitting element; and second control means for controlling an operating temperature of the filter means in accordance with an oscillation wavelength of the light emitting means. 9. The apparatus according to claim 8, wherein the filter unit attenuates the other optical signal according to a filter characteristic and outputs the attenuated optical signal to the second light receiving level detecting unit. Optical module. 10. An optical module according to claim 9, wherein said filter means changes said filter characteristic in accordance with a change in an incident angle of said optical signal. 11. The comparison device according to claim 1, wherein the first control unit compares an electric signal output from the first light reception level detection unit with an electric signal output from the second light reception level detection unit. 9. The optical module according to claim 8, further comprising: a first temperature control unit that controls an operating temperature of the light emitting unit according to the following formula, and adjusts a wavelength of an optical signal output from the light emitting unit. 12. The second control means includes: a temperature detecting means for detecting an operating temperature of the filter means; and a reference value for outputting a reference value corresponding to an operating temperature set for each oscillation wavelength of the light emitting means. An output unit, a comparison unit that compares a value corresponding to an operation temperature output from the temperature detection unit with the reference value, and a second temperature control unit that controls an operation temperature of the filter unit according to a result of the comparison. The optical module according to claim 8, comprising: 13. The optical module according to claim 1, wherein said light emitting means is constituted by a laser diode having an array structure or a tandem structure. 14. The optical module according to claim 1, wherein said filter means is an etalon filter. 15. A light emitting means, first temperature control means for controlling the temperature of the light emitting means, first light receiving means for receiving light from the light emitting means, and filter means for filtering light from the light emitting means. An optical module, comprising: a second light receiving unit that receives light through the second unit; and a second temperature control unit that controls a temperature of the filter unit. 16. The optical module according to claim 15, wherein said filter means is a Fabry-Perot etalon. 17. The optical module according to claim 15, wherein a temperature measuring element is disposed on each of said first temperature control means and said second temperature control means. 18. A first branching unit for branching light from the light emitting element to the first light receiving unit, and a second branching unit for branching light from the light emitting device to the second light receiving unit. The optical module according to claim 15, further comprising: 19. The first light receiving means is a light receiving element having a translucent structure, and the filter means filters the light of the first light receiving means and outputs the light to the second light receiving means. The optical module according to claim 15, wherein: 20. A light emitting means, a translucent first light receiving means for receiving light from the light emitting means, and a light from the light emitting means transmitted through the first light receiving means via a filter means. An optical module, comprising: a second light receiving unit that performs the operation;