JP2003287689A - Automatic temperature compensator for tunable filter and its method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an automatic temperature compensator for a new tunable filter having no constitution (a temperature control portion) for maintaining the tunable filter at constant temperature and requiring no manual adjustment of the constant of a temperature compensation circuit for a working temperature change. <P>SOLUTION: The automatic temperature compensator of the tunable filter selects a conversion table showing a correlation between a variation mechanism parameter and a selected wavelength in a tunable filter 1 according to the working temperature change. A temperature detecting means 10 for detecting working temperature of the tunable filter and a conversion table 5 showing the correlation between the variation mechanism parameter of the tunable filter and the selected wavelength are provided for a plurality of temperatures. Thus, the automatic thermal compensator of the tunable filter selects the conversion table corresponding to temperature close to detected temperature according to the detection output of the temperature detecting means. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tunable filter that performs correction according to temperature changes.

[0002]

2. Description of the Related Art The relationship between a variable function control parameter in a tunable filter (for example, in a diffraction grating type tunable filter, the number of control pulses of a motor for rotating a diffraction grating) and a selected output wavelength is as follows: It has temperature dependence. Since there are about 1000 measurement points of the variable mechanism control parameter, the data capacity of the conversion table between the variable function control parameter and the wavelength is large even if it corresponds to the temperature when one piece is used.

FIG. 4 is a diagram showing an example of the configuration of a conventional tunable filter that is adaptable to temperature changes. In FIG. 4, 1 is a tunable filter, 2 is a heater, and 3 is a constant temperature of the tunable filter according to the output of a temperature detection means (for example, a thermistor) (not shown) for detecting the temperature of the tunable filter. The temperature control unit outputs a heating control signal to the heater for controlling the temperature.

Further, 6 is an operation unit, 4 is a variable function control unit, and in the case of a diffraction grating type tunable filter,
It is a control unit that changes (adjusts) the rotation angle of the diffraction grating. Reference numeral 5 denotes an arithmetic control unit, which includes a conversion table, and calculates a wavelength selected by the tunable filter 1 based on a variable parameter given from the variable function control unit. To be done.

[0005]

The variable function control parameter in the tunable filter (the number of control pulses of the motor for rotating the diffraction grating in the diffraction grating type tunable filter) and the selected output wavelength are used. Has a temperature dependence. Conventionally, the following solutions exist for the temperature dependence of this tunable filter. In the first method, as shown in FIG. 4, a temperature detecting means for detecting the temperature in the vicinity of the tunable filter is provided, and the current flowing through the heater is controlled according to the detection output of the temperature detecting means, The temperature of the tunable filter is controlled to be constant. Also, the second method is
The constant of the temperature correction circuit is manually adjusted according to the operating temperature of the tunable filter.

As described above, in the first method of eliminating the temperature dependence of the conventional tunable filter, since it is necessary to provide a heater for heating the tunable filter, the size of the device is increased and the temperature control is performed. There is a problem of requiring the electric power of. In addition, in the second method, it is necessary to measure the operating temperature of the tunable filter and adjust the constant of the temperature correction circuit according to the detected temperature. However, there was a problem that it needed to be adjusted at any time.

An object (object) of the present invention is to provide a structure (temperature controller) for maintaining the temperature of the tunable filter constant.
It is an object of the present invention to provide a novel automatic temperature compensating device for a tunable filter that does not include the above and does not need to manually adjust the constants of the temperature compensating circuit with respect to changes in operating temperature.

[0008]

In order to solve the above-mentioned problems, a tunable filter for selecting a conversion table showing a correlation between a variable mechanism parameter and a selected wavelength in a tunable filter according to a temperature change during use. In the automatic temperature correction device, a temperature detection means for detecting the temperature when the tunable filter is used, and a conversion table showing the correlation between the variable mechanism parameter of the tunable filter and the selected wavelength are provided for a plurality of temperatures. The conversion table corresponding to the temperature close to the detected temperature is selected according to the detection output of the temperature detecting means. (Claim 1)

Further, in the tunable filter automatic temperature compensator for selecting the conversion table showing the correlation between the variable mechanism parameter and the selected wavelength in the tunable filter according to the temperature change during use, use of the tunable filter Temperature detecting means for detecting an hourly temperature, a conversion table corresponding to a plurality of temperatures indicating the correlation between the variable mechanism parameter of the tunable filter and the selected wavelength, and an interpolation table for an arbitrary temperature between the plurality of conversion tables. And an interpolating unit that creates a conversion table for selecting a conversion table corresponding to a temperature that matches the detected temperature, or based on two conversion tables that are close to the detected temperature. The interpolation table at the detected temperature is obtained by interpolation processing. (Claim 2)

Further, in the automatic temperature correction method for a tunable filter, which selects a conversion table showing a correlation between a variable mechanism parameter and a selected wavelength in the tunable filter in accordance with a temperature change during use, the tunable filter is changed. The step of providing a conversion table showing the correlation between the mechanism parameter and the selected wavelength for a plurality of temperatures, the step of detecting the operating temperature of the tunable filter, and the operating temperature depending on the operating temperature. The automatic temperature correction of the tunable filter is performed by the step of selecting the conversion table corresponding to the near temperature. (Claim 3)

Further, in the automatic temperature correction method for a tunable filter, a conversion table showing the correlation between the variable mechanism parameter and the selected wavelength in the tunable filter is selected according to the temperature change during use. Providing a conversion table corresponding to a plurality of temperatures indicating the correlation between the mechanical parameter and the selected wavelength; detecting the temperature during use of the tunable filter; and using the temperature according to the detected temperature during use. If the conversion table corresponding to the temperature matching the hour temperature exists, the step of selecting the conversion table, and if the conversion table corresponding to the temperature matching the operating temperature does not exist, Using two conversion tables close to the operating temperature, the interpolation conversion table corresponding to the operating temperature is used. Performing automatic temperature compensation of the tunable filter by the steps of creating a table. (Claim 4)

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 3 is a diagram showing an example of the configuration of a tunable filter for automatically temperature-correcting according to a temperature change of the present invention. In FIG. 3, 1 is a tunable filter, 10 is a thermistor (temperature detecting means), 4 is a variable function controller, and in the case of a diffraction grating type tunable filter, the rotation angle of the diffraction grating is variable (adjusted). ) Control unit. A temperature conversion unit 9 converts the detection output of the thermistor into temperature and outputs the temperature to the arithmetic control unit 5. Further, 6 is an operation unit, 5 is an arithmetic control unit, the arithmetic control unit includes a conversion table corresponding to a plurality of temperatures, and a plurality of conversions are performed according to signals from the temperature conversion unit 5. The table is selected, and the calculation of the wavelength selected by the tunable filter 1 is executed based on the variable parameter given from the variable function control unit.

Next, how to select a plurality of conversion tables in the arithmetic control unit 5 will be described in detail with reference to FIGS. 1 and 2. FIG. 1 is a graph showing an example of the first conversion table of the present invention. The horizontal axis of the graph in FIG. 1 represents a variable function control parameter (for example, in the case of a diffraction grating type tunable filter controlled by a motor, it is the number of pulses for varying (adjusting) the rotation angle of the diffraction grating). ing. The vertical axis shows the wavelength selected by the tunable filter.

Further, G1, G2, and G3 in the graph of FIG. 1 are conversion tables, G1 is a conversion table 1 at + 25 ° C., G2 is a conversion table 2 at + 30 ° C., and G3 is a conversion table at + 35 ° C. 3 shows the relationship between the variable mechanism control parameter and the wavelength at each temperature.
In Figure 1, the conversion table is + 25 ℃, + 30 ℃ and + 35 ℃.
Although three conversion tables of ° C are provided, the number and temperature of the conversion tables are not limited to those shown in Fig. 1 and can be appropriately changed as necessary. here,
If the temperature detected by the thermistor is + 35 ℃,
The detected temperature is output to the arithmetic control unit 5, and the calibration table of the temperature close to the detected temperature (the conversion table 3 in this case) is selected from the three conversion tables.

FIG. 2 is a graph showing an example of the second conversion table of the present invention. The horizontal axis of the graph of FIG. 2 represents a variable function control parameter (for example, in the case of a diffraction grating type tunable filter controlled by a motor, it is the number of pulses for varying (adjusting) the rotation angle of the diffraction grating). ing.
The vertical axis shows the wavelength selected by the tunable filter.

Further, G1 and G3 in the graph of FIG. 2 are conversion tables, G1 is conversion table 1 at + 25 ° C., G3 is conversion table 2 at + 30 ° C., and variable mechanism control at each temperature is performed. The relationship between the parameter and the wavelength is shown. Here, when the temperature detected by the thermistor is + 30 ° C., the detected temperature is output to the arithmetic control unit 5 and compared with the two conversion tables.
Since there is no conversion table of the matched temperature, the conversion table at + 30 ° C. is obtained by the interpolation process using the data of the two conversion tables. Although two conversion tables of + 25 ° C. and + 35 ° C. are provided in FIG. 2, the number and temperature of the conversion tables are not limited to those shown in FIG. 1 and are necessary. It can be changed as appropriate.

In the above description, the diffraction tunable filter is used as an example of the tunable filter. However, the present invention is also applicable to other types of tunable filters such as a bandpass filter type and an etalon type. It is possible to apply the technology of the conversion table of the invention.

[0018]

According to the first aspect of the invention, the automatic temperature correction of the tunable filter is performed by selecting the conversion table showing the correlation between the variable mechanism parameter and the selected wavelength in the tunable filter according to the temperature change during use. In the apparatus, a temperature detecting means for detecting a temperature when the tunable filter is used, and a conversion table showing a correlation between a variable mechanism parameter of the tunable filter and a selected wavelength are provided for a plurality of temperatures to detect the temperature. By selecting the conversion table corresponding to the temperature close to the detected temperature according to the detection output of the means, the optimum conversion table can be selected according to the temperature change.

According to the second aspect of the invention, the automatic temperature correction of the tunable filter is performed by selecting the conversion table showing the correlation between the variable mechanism parameter and the selected wavelength in the tunable filter according to the temperature change during use. In the device, a temperature detecting means for detecting a temperature when the tunable filter is used, a conversion table corresponding to a plurality of temperatures indicating a correlation between a variable mechanism parameter of the tunable filter and a selected wavelength, and the plurality of conversions. An interpolating means for creating an interpolating table for any temperature between the tables, and selecting the conversion table corresponding to the temperature that matches the detected temperature, or close to the detected temperature, according to the detection output of the temperature detecting means. An interpolation table at the detected temperature is obtained by interpolation processing based on the two conversion tables. By allows temperature compensation with less conversion table.

According to the third aspect of the invention, the automatic temperature correction of the tunable filter is performed by selecting the conversion table showing the correlation between the variable mechanism parameter and the selected wavelength in the tunable filter according to the temperature change during use. In the method, a step of providing a conversion table showing a correlation between a variable mechanism parameter of the tunable filter and a selected wavelength for a plurality of temperatures, a step of detecting a temperature when the tunable filter is used, and a step of detecting the temperature when the tunable filter is used The automatic temperature correction of the tunable filter is performed by the step of selecting the conversion table corresponding to the temperature close to the operating temperature according to the temperature, so that the optimum conversion table can be selected according to the temperature change. .

Further, in the invention according to the fourth aspect, the automatic temperature correction of the tunable filter for selecting the conversion table showing the correlation between the variable mechanism parameter and the selected wavelength in the tunable filter according to the temperature change during use. In the method, the step of providing a conversion table corresponding to a plurality of temperatures showing the correlation between the variable mechanism parameter of the tunable filter and the selected wavelength, the step of detecting the temperature during use of the tunable filter, If there is a conversion table corresponding to the temperature corresponding to the operating temperature, the conversion table is selected, and the conversion corresponding to the temperature matching the operating temperature is performed. If there is no table, use two conversion tables close to the operating temperature Since the automatic temperature compensation of the tunable filter by the steps of generating an interpolation conversion table corresponding to the temperature, it is possible to temperature correction with less conversion table.

[Brief description of drawings]

FIG. 1 is a diagram showing a first usage example of a conversion table in the present invention.

FIG. 2 is a diagram showing a second usage example of a conversion table according to the present invention.

FIG. 3 is a diagram showing a configuration of a temperature correction device for a tunable filter of the present invention.

FIG. 4 is a diagram showing a configuration of a conventional temperature correction device for a tunable filter.

[Explanation of symbols]

1 Tunable filter 2 Temperature detection means (thermistor) 3 Temperature controller 4 Variable function controller 5 Operation controller (conversion table) 6 Operation part 7 Optical input section Optical connector 8 Optical output part optical connector 9 Temperature converter

Claims (4)

[Claims] 1. An automatic temperature compensator for a tunable filter, which selects a conversion table showing a correlation between a variable mechanism parameter and a selected wavelength in the tunable filter according to a temperature change during use, wherein the tunable filter is used. A temperature detecting means for detecting an hour temperature and a conversion table showing the correlation between the variable mechanism parameter of the tunable filter and the selected wavelength are provided for a plurality of temperatures, and the detection table is detected according to the detection output of the temperature detecting means. An automatic temperature correction device for a tunable filter, wherein the conversion table corresponding to a temperature close to a temperature is selected. 2. An automatic temperature compensator for a tunable filter, which selects a conversion table showing a correlation between a variable mechanism parameter and a selected wavelength in the tunable filter according to a temperature change during use, wherein the tunable filter is used. Temperature detection means for detecting an hourly temperature, a conversion table corresponding to a plurality of temperatures indicating the correlation between the variable mechanism parameter of the tunable filter and the selected wavelength, and an interpolation table for an arbitrary temperature between the plurality of conversion tables An interpolating means for creating a conversion table, and selecting the conversion table corresponding to a temperature that matches the detected temperature according to the detection output of the temperature detecting means,
Or, based on two conversion tables close to the detected temperature,
An automatic temperature correction device for a tunable filter, characterized in that an interpolation table at a detected temperature is obtained by interpolation processing. 3. An automatic temperature correction method for a tunable filter, wherein a conversion table showing a correlation between a variable mechanism parameter and a selected wavelength in the tunable filter is selected according to a temperature change during use. A step of providing a conversion table showing a correlation between a mechanical parameter and a selected wavelength for a plurality of temperatures, a step of detecting a temperature in use of the tunable filter, and a temperature in use depending on the temperature in use. And a step of selecting the conversion table corresponding to a close temperature, the automatic temperature correction method for a tunable filter, comprising: 4. An automatic temperature correction method for a tunable filter, wherein a conversion table showing a correlation between a variable mechanism parameter and a selected wavelength in the tunable filter is selected according to a temperature change during use. Providing a conversion table corresponding to a plurality of temperatures indicating the correlation between the mechanical parameter and the selected wavelength; detecting the operating temperature of the tunable filter; and using the operating temperature according to the detected operating temperature. If the conversion table corresponding to the temperature corresponding to the hour temperature exists, the step of selecting the conversion table; and if the conversion table corresponding to the temperature corresponding to the operating temperature does not exist, By using two conversion tables that are close to the operating temperature, the interpolation conversion table corresponding to the operating temperature is used. Automatic temperature compensation method of a tunable filter which comprises a step of creating a Le, a.