JPH0675014B2 - Range setting method - Google Patents

Description

Description: [Industrial field of application] The present invention automatically determines the measurement range of a measuring device when measuring the temperature of the measuring target by measuring infrared rays emitted from the measuring target. It relates to a range setting method to be performed.

[Prior Art] It is known that all objects having a temperature of absolute zero or more radiate infrared rays from the surface thereof, and between the radiated infrared ray amount (energy amount) and the surface temperature of the object, There is a certain relationship called Planck's radiation formula. Therefore, the surface temperature of the object can be known by measuring the amount of infrared radiation. This infrared amount is detected by the infrared detector, but one infrared detector can only detect infrared rays coming from a certain direction. However, if a mechanism for bending the light path, that is, a scanning mechanism is provided in front of the infrared detector, infrared radiation coming from various directions can be detected.

FIG. 4 is a view showing an example of this method, in which 1 is a rotary mirror which is formed in an annular shape with 10 plane mirrors having slightly different vertical angles, 2 is a silicon window, 3 is a folding mirror, and 4 is a mirror. Is a condenser lens, 5 is a positioning motor, 6 is an infrared detection element arranged in a vertical direction, and 7 are
Is an amplifier provided for each infrared detection element, and is designed to send independent output signals for 10 channels.

In the device thus configured, only infrared rays pass through the silicon window 2 and reach the rotating mirror 1. As described above, since the plane mirrors of the rotary mirror 1 are provided so as to be slightly displaced in the vertical direction, each plane mirror laterally scans a portion of the subject that is slightly displaced in the vertical direction. One rotation of the rotary mirror 1 scans a range of 10 degrees in the vertical direction. On the other hand, ten infrared detectors 6 are arranged in the vertical direction, and the distance between them corresponds to an angle of 1.0 degree in the vertical direction. For this reason, the infrared detector 6 of 10 elements receives the thermal image signal at every 1.0 degree at the same time by the plane mirror of one surface, and the infrared image signal at the position shifted by 1.0 degree from the previous position at the same time at the next plane mirror. . In this way, one rotation of the rotating mirror 1 scans the subject 10 degrees in the vertical direction. In the horizontal direction, the horizontal viewing angle (about 18 degrees) of each plane mirror of the rotating mirror is scanned.

The thermal image signal thus obtained is amplified by each of the ten amplifiers 7 and output. Reference numeral 8 is a temperature table in which data such as that shown in Table 1 whose temperature is corrected by the black body furnace is stored. If a temperature range of, for example, 14 degrees to 23 degrees is required among the temperature ranges shown in Table 1, the temperature range indicated by the symbol a is selected by the switch 9, and the data of the range is written in the conversion table 10.

For this writing, as shown in FIG. 5, the voltage corresponding to the energy of infrared rays, that is, the input voltage value in Table 1 is written on the horizontal axis, and the temperature at that time is written on the vertical axis. Although Table 1 is described with an analog signal, since writing is performed with an 8-bit digital signal, it takes a value of 0 to 255. Therefore, the first
Interpolate the missing parts from the values in the table to create data. In this case, set the lowest value to zero and the highest value to 255. However, the linearity of the infrared detector is guaranteed only in a certain range. Therefore, if the linearity is out of the linear range, the input signal may be attenuated by a filter or the amplifier gain may be adjusted so that the maximum and minimum values of the measurement target are within the linear range of the measuring instrument. I am trying. Further, in order to ensure good linearity and perform accurate measurement, the measurement range is set narrow.

[Problems to be Solved by the Invention] However, for example, when an attempt is made to measure a change in the temperature distribution of a measurement target while heating the measurement target, the temperature of the measurement target changes with time. However, when performing highly accurate measurements, the temperature measurement setting range is narrow, so the temperature of the measurement target may deviate from the set temperature range of this device depending on the temperature change of the measurement target. It becomes necessary, and it is difficult to measure the temperature change while simultaneously performing other measurements.

[Means for Solving the Problem] In order to solve such a problem, the first aspect of the present invention provides a measurement target temperature range every time the temperature of the measurement target changes, the temperature range of the measurement target changes every time the temperature of the measurement target changes. The temperature range is detected (step 200), and when there is no measurement target in the current setting range (step 117), the setting range is sequentially expanded by the range at that time (step 119), and a new temperature range is detected. Each time the temperature of a specific part located within the temperature range is detected (step 201), each time the temperature of the specific part is detected, the temperature is slid to the center of the setting range (step 204), and within the setting range. When it is detected that the maximum and minimum values of the measurement target are included (step 118), a predetermined amount is added to the minimum and maximum values of the range (step 112).
~ 116) and then stop the expansion of the range.

The second invention detects the temperature range of the measurement target each time the temperature of the measurement target changes (step 200), and if there is no measurement target within the current setting range (step 117), the setting ranges are sequentially changed to the ranges at that time. Scale up (step 11
9), each time a new temperature range is detected, the temperature of a specific portion located within that temperature range is detected (step 201),
Whenever the temperature of a specific part is detected, that temperature is slid to the center of the setting range (step 204), and it is detected that the maximum and minimum values of the measurement target are included in the setting range (step 118). The value obtained by subtracting a predetermined amount from the minimum value of the target is set as the minimum value of the measurement range, and the value obtained by adding the predetermined amount to the maximum value of the measurement target (steps 112 to 116) is set as the maximum value of the measurement range. is there.

[Operation] In the invention of claim 1, the temperature range of the measurement target automatically follows the center of the measurement range, and the measurement range also automatically follows so that the maximum temperature and the minimum temperature of the measurement target fall within the measurement range.

The invention of claim 2 is set such that the measurement range set in claim 1 is in a state in which measurement is easy.

[Embodiment] This apparatus is designed to automatically set the temperature measurement setting range according to FIG. 1 according to the temperature of the measurement object.
The operation of FIG. 1 will be described later.

It is assumed that the setting range is determined according to FIG. 1, and in the first invention, the setting range is automatically shifted within the determined setting range as shown in FIG. Second
In the figure, first, the temperature distribution of the measurement target is stored as shown in step 200, the temperature of the specific point is determined as shown in step 201, and the setting range is determined so that this temperature is in the center of the setting range. This specific point can be anywhere, but it must always be within the range of the maximum and minimum temperatures to be measured, in this example 80% of the maximum temperature.
Took to the temperature.

When the specific point is determined, it is then determined in step 202 whether or not the temperature of the specific point has changed. If the temperature has changed, the amount of change is detected as shown in step 203, and the detection is performed as shown in step 204. The set range is shifted by the changed amount, and the flow returns to step 200. Therefore, a new temperature distribution is stored again in step 200, and the same processing as described above is performed. Therefore, every time the temperature changes, the processes of steps 200 to 204 are repeated, and the portion of the specific temperature is always in the center of the set range. For this reason,
It is possible to measure the temperature change of a heated object without setting the device according to the temperature change.

FIG. 3 is a flow chart showing an example in which the cursor position is set to the measurement center point. As shown in step 300, the temperature of the cursor set point is measured and the temperature is set to the center of the set range. It When the temperature change is detected in step 301, the change amount is detected as shown in step 302, the set range is shifted by the change amount, and the flow returns to step 300. Therefore, even if the temperature of the measurement target changes, the temperature at the cursor set point is always set at the center of the set range.

Next, the operation of automatic setting of the setting range shown in FIG. 1 will be described. Each signal in FIG. 1 is defined as follows.

Pmax: Maximum input in Fig. 5 (digital amount from 0 to 255 corresponding to infrared energy) Pmin: Minimum input in Fig. 5 (digital amount from 0 to 255 corresponding to infrared energy) T _L : Measuring range Minimum temperature set value (analog amount) T _H : Maximum temperature set value in measurement range (analog amount) T _OH : Maximum temperature of measurement target [T _OH = f (max), analog amount] T _OL : Measurement Target minimum temperature [T _OL = f (Pmin), which is an analog amount] In FIG. 1, the case where Pmax and Pmin are equal will be described. In this case, both the minimum value and the maximum value are outside the setting range (just Including the case at the boundary), or within the setting range but the maximum value and the minimum value of the set value are equal.

Minimum input value Pmin and maximum input value Pmax in step 100
If it is determined that the input data P is not 255 as shown in step 101 and is not 0 as shown in step 103, the maximum and minimum values of the present set values are too close to each other. If there is. At this time, as shown in step 105, the minimum temperature setting value T _L of the measurement range is lowered by 10% of the current setting range, and the maximum temperature setting value T _H of the measurement range is increased by 10% of the current setting range. Then, as shown in step 106, it is determined whether or not the temperature difference of the measurement target is 60% of the set range, and the set range is changed until the condition is satisfied.

If the input data P = 255 is determined in step 101, the maximum value of the setting range is too low. Therefore, as shown in step 102, the maximum value is moved to the side higher by the temperature difference of the current setting range amount, and will be described later. The processing after step 117 is performed. If it is determined in step 103 that the input data P = 0, the setting range minimum value is too high, so the minimum value is moved to the lower side by the temperature difference of the current setting range as shown in step 104. Then, whichever of the processing of steps 102 and 104 is performed, it is determined whether or not there is a measurement target in the measurement range as shown in step 117, and when there is no measurement target in the measurement range, the processing is shown in step 119. The measurement range is set to double. If there is still no measurement target within the measurement range, the measurement range is changed to twice the current set range each time until the measurement target falls within the measurement range. Then, the measurement target comes to fall within the measurement range, but as shown in step 118, the measurement range is continuously expanded until both the minimum value and the maximum value of the measurement target fall within the set range.

When it is determined in step 118 that both the minimum and maximum values of the measurement target are within the setting range, as shown in step 112, whether the temperature difference of the measurement target is 60% or less of the setting range. Is judged. The temperature difference of the measurement target is 60% of the measurement range
If it is larger, the measuring range is too narrow, so as shown in steps 115 and 116, until it reaches 60%,
The minimum setting value is lowered by 10% of the current setting range, and the maximum setting value is raised by 10% of the current setting value. When the temperature difference of the measurement target is 60% or less of the set range in step 112, the reverse operation is performed as shown in steps 113 and 114.

In step 100, it is determined that Pmax = Pmin is not satisfied,
When it is determined in step 107 that the data Pmax is 255 and Pmin is 0, the setting range is too narrow compared to the temperature difference of the measurement target. Therefore, step 105,
As described above in 106, the setting range is expanded until the temperature difference of the measurement target reaches 60% of the setting range. However, if it is determined in step 108 that only the maximum value Pmax of the input data is 255 and the minimum value Pmin is not 0, only the maximum value of the measurement target is outside the measurement range, so as shown in step 109, the set value maximum After increasing the value by 10% of the current setting range, it is determined in step 112 whether the temperature difference of the measurement target is larger or smaller than 60% of the setting range. Thereby, as mentioned above, steps 113,114 or 115,1
By the process of 16, the process of expanding or contracting the setting range is performed until the temperature difference of the measurement target becomes 60% of the setting range.
If the minimum value Pmin of input data is 0 and the maximum value Pmax is not 255, the minimum set value is too high.
As shown in 111, the minimum setting value is lowered by 10% of the current setting range, and the setting range is automatically adjusted in the same manner as above so that the temperature difference of the measurement target is 60% of the setting range. To do.

[Effect of the invention] As described above, the invention of claim 1 is such that the temperature range of the measurement target automatically follows the center of the measurement range and the maximum temperature and the minimum temperature of the measurement target are within the measurement range. The second aspect of the invention is to automatically follow
Since the measurement range set in step 3 is set so that it can be easily measured, the operator needs to update the set range each time the temperature of the measurement target changes even if the temperature changes. Since there is no such measurement, the temperature change can be measured while performing other measurements at the same time, which has the effect of enabling a wide range of measurements.

[Brief description of drawings]

FIG. 1 is a flow chart for explaining an operation for automatically setting a setting range, FIG. 2 is a flow chart showing an embodiment of the first invention, and FIG. 3 is a flow chart showing an embodiment of the second invention. FIG. 4 is a diagram showing the configuration of the infrared detecting section, and FIG. 5 is a graph showing the characteristics of the conversion table. 1 ... Rotating mirror, 2 ... Silicon window, 6 ... Infrared detecting element, 7 ... Amplifier, 8 ... Temperature table, 10
...... Conversion table.

Claims (2)

[Claims] 1. A range setting method for automatically setting a measurement range, the temperature range of the measurement target is detected each time the temperature of the measurement target changes, and the setting range is set when there is no measurement target within the current setting range. Sequentially expands by the range at that point in time, each time a new temperature range is detected, the temperature of the specific part located within that temperature range is detected, and that temperature is set range each time the temperature of the specific part is detected. When sliding to the center and detecting that the maximum and minimum values of the measurement target are included in the set range, add a predetermined amount to the minimum and maximum values of the range and then stop expanding the range. Characteristic range setting method. 2. A range setting method for automatically setting a measurement range, the temperature range of the measurement target is detected each time the temperature of the measurement target changes, and the setting range is set when there is no measurement target within the current setting range. Sequentially expands by the range at that point in time, each time a new temperature range is detected, the temperature of the specific part located within that temperature range is detected, and that temperature is set range each time the temperature of the specific part is detected. Slide to the center, and when it is detected that the maximum and minimum values of the measurement target are included in the set range, the value obtained by subtracting a predetermined amount from the minimum value of the measurement target is set as the minimum value of the measurement range, and the maximum value of the measurement target is set. A range setting method, wherein the value obtained by adding a predetermined amount to the value is set as the maximum value of the measurement range.