JP2525982Y2 - Swept optical interferometer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a swept-type optical interference device used, for example, in an optical spectrum analyzer.

[Prior Art] FIG. 2 shows an application example of a conventional swept optical interference device. In this example, a case is shown in which an optical spectrum analyzer is configured by combining the swept interferometer 1 and the frequency analyzer 2.

In this example, a case where a Michelson interferometer is used as a swept optical interferometer is shown. That is, this type of swept optical interference device 1 is constituted by the half mirror 11, the fixed mirror 12, the movable mirror 13, and the light receiver 14.

The input light P _O is split by the half mirror 11 into 2P ₁ and 2P ₂ . Branched optical 2P ₁ is incident on the photodetector 14 is reflected by the fixed mirror 12. The split light 2P ₂ is
And is incident on the light receiver 14.

When the light P ₁ and P ₂ are incident on the photodetector 14, since the light P ₂ is the optical path length is changed by moving the movable mirror 13, the light P ₁
An optical path difference of light P ₂ is changed, the light P ₁ and P ₂ interfere with each other, the optical interference signal PI obtained from the light receiver 14 with respect to change in the position 1 of the movable mirror 13 as shown in FIG. 3 With a light interference waveform.

In the waveform of the optical interference signal PI shown in FIG. 3, the position l ₀ of the movable mirror 13 which the maximum amplitude is obtained is the position where the optical path difference of light P ₁ and P ₂ becomes zero.

The optical interference signal PI is input to the frequency analysis device 2, the frequency component of the signal is frequency-analyzed by, for example, fast Fourier transform, and the analysis result is displayed on the display 2A, whereby the spectrum of light can be displayed. .

Value of the peak point of the light spectrum to be displayed on the display device 2A is changed according to the light energy of the input light P _O. Therefore, in this type of instrument to measure the optical power of the input light P _O, it must be monitored.

As a method of measuring the optical power of the input light P _O , there are a method of using the optical spectrum displayed on the display 2A as a monitor, and a method of providing a half mirror 15 on the input side of the swept optical interference device 1, giving light P ₃ which is branched at 15 into the light receiver 16 of the monitor, and a method conceivable for monitoring the optical power of the input light P _O by an electrical signal obtained from the light receiver 16.

In the case of the method described in “Problems to be solved by the invention”, the optical spectrum displayed on the display 2A is delayed (about several seconds) by the time for performing the frequency analysis before the display, so the intensity of the input light P _O From the time of adjustment, the result is only after the delay time. That is, the adjustment is troublesome because the adjustment cannot be performed in real time.

In the case of the method described above, the input light P _O is branched for monitoring, so that there is a disadvantage that the intensity of the light for measurement is reduced. In other words, when the optical power for measurement is reduced, the inconvenience that the SN ratio is deteriorated and the measurement accuracy is reduced is caused.

An object of the present invention is to provide a swept-type optical interference device that can monitor the power of the input light in real time without lowering the power of the input light to the optical interference device.

"Means for solving the problem" In this invention, the means for extracting the DC component of the optical interference signal obtained from the optical receiver of the swept optical interference device and the level of the DC component extracted by the means for extracting the DC component are displayed. And a display device that performs the above-described operations to form a swept optical interference device.

According to the configuration of the present invention, an electric signal corresponding to the optical power of the input light P _O can be obtained by extracting the DC component of the optical interference signal obtained from the light receiver of the swept optical interference device. Therefore, by displaying the level of the electrical signal to the display unit can display the optical power of the input light P _O. In addition, since the electric signal responds to the fluctuation of the input light P _O without delay, the level of the input light P _O can be easily set.

"Embodiment" FIG. 1 shows an embodiment of the swept optical interference device according to the present invention. In FIG. 1, reference numeral 1 denotes a sweep type optical interference device, and 2 denotes a frequency analysis device. In the present invention, there is provided means 21 for extracting a DC component from the optical interference signal PI (see FIG. 3) output from the optical receiver 14 of the sweep type optical interference device 1. In this example, as the means 21 for extracting this DC component, a case is shown in which a low-pass filter constituted by an operational amplifier 21A and a capacitor 21B inserted in a negative feedback circuit of the operational amplifier 21A is used.

The DC component extracted by the DC component extracting means 21 is supplied to a logarithmic amplifier 22, and the level change of the DC component is logarithmically converted.

The logarithmically converted DC component is supplied to a display 25 through a gain adjustment amplifier 23 and an excessive input prevention circuit 24 constituted by a limiter. Reference numeral 26 denotes an offset voltage adjuster.

DC components of the optical interference signal PI output from the photodetector 14 is proportional to the optical power of the input light P _O. Therefore, by displaying the direct current component on the display unit 25 can display the optical power of the input light P _O.

"Explanation of Device" As described above, according to the present invention, the signal is input to the sweep-type optical interference device 1. Since displaying electrically removed optical power of the input light P _O, does not light power of the input light P _O input to the sweep-type optical interferometer device 1 is reduced. Therefore,
There is no risk of lowering the measurement accuracy of the optical spectrum analyzer.

Moreover, since the electric signal output from the light receiver 14 is used as a monitor, no time is required for arithmetic processing and the like.
Therefore, it is possible to view the change in the input light P _O immediately display device 25, the adjustment can be easily performed.

According to the present invention, the logarithmic amplifier 22 is provided, and the change in the DC component extracted by the DC component extracting means 21 is converted into a logarithmic change by the logarithmic amplifier 22 and given to the display 25. 25 can display a high level optical power from a low level optical power. Therefore, there is an advantage that the measurement of the optical power can be easily performed, and the sweep type optical interference device that can be easily handled can be provided.

[Brief description of the drawings]

FIG. 1 is a connection diagram showing an embodiment of the present invention, FIG. 2 is a connection diagram for explaining a conventional technique, and FIG. 3 is a waveform diagram showing an example of an optical interference signal. 1: Sweep type optical interference device, 2: Frequency analysis device, 14: Optical receiver of optical interference device, 21: Means for extracting DC component, 22: Logarithmic amplifier, 23: Amplifier for gain adjustment, 24: Excessive input prevention circuit, twenty five:
display.

Claims (1)

(57) [Scope of request for utility model registration] 1. A swept-type optical interference device, B. a light receiver for converting interference light into an interference light signal, and C. a DC component extracting means for extracting a DC component of the interference light signal output from the light receiver. D. a logarithmic amplifier that converts a change in the DC component extracted by the DC component extracting means into a logarithmic change; and E. an input light to which the amplified output of the logarithmic amplifier is supplied and input to the sweep type optical interference device And a display for displaying the optical power of the light.