JPH052408U - Reflective variable attenuator - Google Patents

Abstract

(57) [Summary] (Modified) [Purpose] To obtain a reflection type variable attenuator having a small output monitor circuit and capable of feedback control of attenuation amount by the output monitor circuit even if the input and output are connected in reverse. [Structure] Laser diodes 4 and 5 are attached to both output ports of the interdigital coupler 3 as variable impedance elements, and a light receiving element 6 for performing optical / electrical conversion is provided to monitor the output light of the laser diodes. Further, a detection circuit 7 for detecting the optically / electrically converted signal,
A bias circuit 8 is provided which controls the bias current applied to the laser diodes 4 and 5 by the output of this detection circuit. When a forward current is applied, the laser diode 4,
5 oscillates a laser, and the oscillated light is modulated in intensity by the applied high frequency.
In proportion to the high frequency power absorbed in 5, the high frequency demodulation output becomes feedback information and controls the bias current.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a reflective variable attenuator capable of varying the amount of high frequency attenuation.

[0002]

[Prior Art]

 FIG. 3 is a diagram showing a configuration of a conventional reflective variable attenuator. In the figure, 1 is an input terminal, 2 is an output terminal, 3 is an interdigital coupler, 11 is a directional coupling circuit, 7 is a detection circuit, 12 is a first diode, 13 is a second diode, and 8 is a balun. It is the Iias circuit.

Next, the operation will be described. The high frequency input from the input terminal 1 is distributed to the first diode 12 and the second diode 13 by the interdigital coupler 3. If voltage is not applied to the first diode 12 and the second diode 13 by the bias circuit 8, the first diode 12 and the second diode 13 have high impedance, and high frequency is generated in each diode. Is totally reflected and is output to the output terminal 2. At this time, at the input terminal 1, since the phase difference between the reflected waves from the first diode 12 and the second diode 13 is 180 °, no output appears at the input terminal 1.

Next, when a forward current is applied to the first diode 12 and the second diode 13 by the bias circuit 8, the impedances of the first diode 12 and the second diode 13 decrease, and high frequency Absorbs. Therefore, the reflection amount of the high frequency distributed by the interdigital coupler 3 in the first diode 12 and the second diode 13 is reduced, and as a result, the high frequency output to the output terminal 2 is attenuated to the input. However, it is generally difficult to determine an accurate forward current value for a desired attenuation amount in advance because of variations in the diode forward current-impedance characteristics. Therefore, it is necessary to adjust the bias current according to the individual difference of the attenuator.

Therefore, after the output of the interdigital coupler 3 is branched by the directional coupling circuit 11, it is detected by the detection circuit 7 and a signal having information on the attenuation amount is fed back to the bias circuit 8. In the bias circuit 8, the bias current is adjusted based on this feedback information, and the attenuation amount by the first diode 12 and the second diode 13 is changed to obtain the desired attenuator output power.

[0006]

[Problems to be solved by the device]

 Since the conventional reflective variable attenuator is configured as described above, a directional coupling circuit is required on the output side of the attenuator to monitor the output of the attenuator. Therefore, this directional coupling circuit causes an increase in the size of the attenuator, and if you want to use the reflective variable attenuator with the input and output directions reversed, you cannot use the output monitor for feedback. was there.

The present invention has been made to solve the above problems, and an object thereof is to obtain a reflection type variable attenuator which has a small output monitor circuit and is reversible with input and output.

[0008]

[Means for Solving the Problems]

 The reflective variable attenuator according to the present invention has a laser diode attached to both output ports of the interdigital coupler, and controls the bias current to this laser diode by monitoring the output light of either one of the laser diodes. This is based on the obtained signal.

Further, the output light from the two laser diodes attached to both output ports of the interdigital coupler is individually monitored, and the bias currents of the two laser diodes are controlled respectively.

[0010]

With the reflective variable attenuator according to the present invention, by monitoring the output light of the laser diode attached to the output port of the interdigital coupler, the amount of high frequency attenuation at each reflective terminal can be grasped, Send appropriate feedback information to the bias circuit to set the attenuation.

[0011]

【Example】

 Example 1. An embodiment of the present invention will be described below with reference to FIG. In FIG. 1, 4 is a first laser diode, 5 is a second laser diode 6, is a first light receiving element, and 7 is a first detection circuit.

Next, the operation will be described. The high frequency input from the input terminal 1 is distributed to the first laser diode 4 and the second laser diode 5 by the interdigital coupler 3. Here, if no voltage is applied to the first laser diode 4 and the second laser diode 5 by the bias circuit 8, the first laser diode 4 and the second laser diode 5 have high impedance, and each laser diode 4 has a high impedance. The diode high frequency is totally reflected and output to the output terminal 2. At this time, at the input terminal 1, since the phase difference between the reflected waves from the first laser diode 4 and the second laser diode 5 is 180 °, no output appears at the input terminal 1.

Next, when a forward current is applied to the first laser diode 4 and the second laser diode 5 by the bias circuit 8, the impedances of the first laser diode 4 and the second laser diode 5 become It lowers and absorbs high frequencies. Therefore, the reflection amount of the high frequency distributed by the interdigital coupler 3 in the first laser diode 4 and the second laser diode 5 is reduced, and the high frequency output to the output terminal 2 consequently becomes higher than the input wave. Decay.

At this time, since a forward current is applied to the first laser diode 4 and the second laser diode 5, laser oscillation occurs, and the oscillation light is modulated in light intensity by the applied high frequency. It takes. The amount of change in the modulation factor is proportional to the amount of change in the high frequency power absorbed by the laser diode.

The output light of the first laser diode 4 is photo / electrically converted by the first light receiving element 6, and the high frequency is demodulated. This high frequency is detected by the first detection circuit 7 and fed back to the bias circuit 8 as information regarding the amount of attenuation in the first laser diode 4. The bias circuit 8 controls the bias current applied to the first laser diode 4 and the second laser diode 5 based on this feedback information, and the impedance of the first laser diode 4 and the second laser diode 5 is controlled. A desired amount of attenuation is obtained by changing. In this case, the attenuation is constant power attenuation that a certain amount of power is attenuated regardless of the input power. The same operation is performed even if the input and output of the attenuator are connected in reverse.

Example 2. Another embodiment will be described with reference to FIG. Reference numeral 9 is a second light receiving element, and 10 is a second detection circuit. In the case of the embodiment shown in FIG. 2, the output light of the second laser diode 5 is optically / electrically converted by the second light receiving element 9 similarly to the first laser diode 4, and the demodulated high frequency is subjected to the second detection. It is detected by the circuit 10 and is fed back to the bias circuit 8 as information on the amount of attenuation in the second laser diode 5. In the bias circuit 8, the impedances of the first laser diode 4 and the second laser diode 5 are adjusted based on the feedback signal from the second detection circuit 10 and the feedback signal from the first detection circuit 7. A desired amount of attenuation is obtained by changing each individually.

[0017]

[Effect of the device]

 Since the present invention is configured as described above, the attenuation amount can be monitored without providing a directional coupling circuit, and even if the input and output are connected in reverse, the same attenuation amount monitoring function can be used. Therefore, there is an effect that a small and inexpensive reflection type variable attenuator can be obtained.

[Brief description of drawings]

FIG. 1 is a diagram showing the configuration of a reflective variable attenuator according to an embodiment of the present invention.

FIG. 2 is a diagram showing a configuration of a reflective variable attenuator showing another embodiment of the present invention.

FIG. 3 is a diagram showing a configuration of a conventional reflective variable attenuator.

[Explanation of symbols]

 3 Inter-Digital Coupler 4 First Laser Diode 5 Second Laser Diode 6 First Light-Receiving Element 7 First Detection Circuit 8 Bias Circuit 9 Second Light-Receiving Element 10 Second Detection Circuit

Claims (1)

Claims for utility model registration 1. In a reflective variable attenuator using an interdigital coupler, an interdigital coupler and a first laser diode connected to one output port of the interdigital coupler. A second laser diode connected to the other output port, a first light receiving element for receiving the output light of the first laser diode, and a first detection circuit connected to the first light receiving element And a bias circuit that is connected to the first detection circuit and applies a bias to the first laser diode and the second laser diode, the reflective variable attenuator.