JPH01105124A - Infrared temperature measuring instrument - Google Patents

Abstract

PURPOSE:To easily recognize a temperature setting range by varying the conversion table of a color converting circuit according to the temperature setting range for image arithmetic operation and then displaying the temperature setting range chromatically or monochromatically. CONSTITUTION:The color converting circuit 18 has conversion tables for color display and black-and-white display and primary color signals for color display and black-and-white display are outputted respectively. Then when image data supplied from an image memory 11 is within the upper-lower limit temperature range, the conversion table for color display is selected under the control of a CPU 14 and in other cases, the conversion table for black-and-white display is selected. Consequently, the part of a color bar corresponding to the upper- lower limit temperature range is displayed chromatically and other parts are displayed monochromatically. Further, the part of the image area on the display part of a color display 21 corresponding to the upper-lower limit temperature range is displayed chromatically and other parts are displayed mono chromatically. Thus, the upper-lower limit temperature range is easily discrimi nated.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an infrared temperature measurement device suitable for use in non-contact measurement of the temperature of an object to be measured.

[Summary of the invention]

The present invention provides an infrared temperature measuring device that sequentially scans an object to be measured in horizontal and vertical directions and two-dimensionally displays which region of a plurality of temperature regions the temperature at each scanning position falls into. By displaying the temperature setting range to be calculated separately in color or black and white, the temperature setting range can be easily recognized.

[Conventional technology]

FIG. 4 shows an example of an infrared temperature measuring device. In the same figure, (1) is an infrared sensor, and this infrared sensor (1) receives infrared rays emitted from a measured object (2) depending on the temperature through a mirror +33. +4) and the objective lens (5). In this case, mirrors (3) and 14) are scanning mirrors, and these mirrors (3) and (4) allow the focal position of the objective lens (5) to move on the object to be measured (2) in the horizontal direction H1 and the vertical direction. V is sequentially scanned. Therefore, the infrared sensor (1) has
Infrared rays emitted from each scanning position of the object to be measured (2) are sequentially supplied depending on the temperature. Figure 5 shows the object to be measured (
The horizontal and vertical scanning range (200) for 2) is omitted.

The output signal of this infrared sensor (1) is proportional to the energy of the infrared rays supplied, and the output signal of the infrared sensor (1) is
If the temperature at each scanning position is 'r, then it is proportional to T4 according to Stefan Boltzmann's law. Therefore, the output signal of this infrared sensor (1) is supplied to a linearizer (7) via an amplifier (6), and is converted into a signal proportional to the temperature T by this linearizer (7).

The output signal of this linearizer (7) is passed through a subtracter (8) and a gain switching circuit (91), and then converted into an 8-bit digital signal of, for example, 1 sample in an A/Di converter (10), and is converted into an image memory. (11) is supplied as image data and sequentially written.

In this case, the subtracter (8) includes a center temperature setting circuit (12).
A center temperature signal is supplied from the linearizer (7), and the center temperature signal is subtracted from the output signal of the linearizer (7). As will be described later, the color display is two-dimensionally color-coded to indicate which region the temperature at each scanning position of the object to be measured (2) falls within a plurality of temperature regions centered around a predetermined temperature region. However, the core temperature signal is displayed when the user enters the keyboard (13
) to set the temperature in the central predetermined temperature range (hereinafter referred to as "center temperature"), the center temperature setting circuit (
12) is controlled by the CPU (14) to produce a signal at a level corresponding to the set center temperature. Therefore, for example, when the temperature at the scanning position of the object to be measured (2) is equal to the set center temperature, the output signal of the subtracter (8) becomes 0.

Further, the gain switching circuit (91) is composed of an amplifier, and the output signal of the subtracter (8) is amplified by a predetermined factor.

As mentioned above, a color display can be used to measure objects (
2) The temperature at each scanning position falls within a plurality of temperature ranges centered around a predetermined temperature range, which is displayed in a two-dimensional color-coded manner.
), the CPU (14) controls the sensitivity setting circuit (92), which controls the gain switching circuit (92).
The gain of 1) is changed to set the temperature difference between each temperature region, and therefore the sensitivity.

Here, (15) is a ROM, and (16) is a RAM.

Also, as mentioned above, the color display shows the temperature of each color.
A number indicating the color par and the temperature corresponding to this color par is displayed. The image data that displays color par is CP
It is written in advance to the image memory (11) from U (14). The number indicating the temperature changes according to the user's center temperature setting and sensitivity setting, and the character data that displays this number is sent from the CPU (14) to the character memory (1
7).

Also, the image memory (11) is controlled by the CPU (14).
), the image data is sequentially read out and supplied to a color conversion circuit (18) having a conversion table made of, for example, a ROM, where it is converted into three primary color signals of red, edge and blue, and sent to an adder (19). Supplied. In this case, for example, the subtractor (
8) When the output signal is 0, it is converted so that green is displayed, and when the output signal is positive, it is converted so that the color becomes closer to red as the level increases. When the level is negative, the color becomes closer to blue as the level becomes larger. Also, under the control of the CPU (14), the three primary colors of red, green, and blue are displayed from the character memory (17). The character data are sequentially read out and supplied to the adder (box 9).In this case, for example, white numbers are assumed to be displayed.

The three primary color signals from addition a (19) are converted into analog signals by a D/A converter (20) and then supplied to a color display (21). On the screen (100) of this color display (21), the image is displayed as shown in FIG. 6, for example. In the figure, (101) is a display section in which a plurality of temperature regions of the object to be measured (2) are displayed in different colors.

Further, (102) is a color par, and (103) is a number indicating temperature. Note that only some numbers are shown to simplify the drawing. In this case, the center temperature and sensitivity (temperature difference between each temperature range) are the values set by the user.

By the way, in such a temperature measuring device, it is known that predetermined image calculations are performed.
By setting a frame of any size in 1) and further setting the upper and lower temperature limits, the average temperature, maximum temperature, and minimum temperature within the specified frame are calculated and displayed within the upper and lower limit temperature ranges. be. For example, a color display (21
) by setting a frame of any size in the display area (101) on the screen (100) and selecting the upper limit temperature, lower limit temperature, and temperature step, the frequency distribution of temperature vs. number of data items (percentage) can be calculated. It calculates and displays.

Such image calculation processing is performed, for example, according to a flowchart as shown in FIG.

In the same figure, in step ■, the user presses the keyboard (
When a display mode such as frequency distribution is selected by operating 13), the processing state becomes that of the selected mode,
Initial values such as the designated frame, upper limit temperature, lower limit temperature, etc. are set.

Then, in step (2), after the image data is supplied from the CPU (14) to the graphic memory (22) and written, the three primary colors of red, dark and blue are stored in the graphic memory (22) under the control of the CPU (14). specified frame,
The data indicating the upper and lower temperature limits are read out sequentially and sent to the adder (1
9). This allows the color display (
21), marks indicating a designated frame, an upper limit temperature, a lower limit temperature, etc. are displayed in white, for example, on the display section (101) on the screen (100). FIG. 8 shows an example of the display on the screen (100) when the average temperature mode is selected. In the figure, (31) is a designated frame. Also, (32)
are marks indicating the upper limit temperature and lower limit temperature.
The upper limit temperature is displayed next to the color par (102) corresponding to the lower limit temperature.

The lower temperature limit is indicated.

Returning to FIG. 7, in step ■, the user operates the keyboard (13) to set the specified frame and upper limit temperature.

When you instruct to change the set value such as upper limit temperature, the specified frame and upper limit temperature are changed through step ■ and step ■.

Setting values such as the lower limit temperature are changed. Then, in step ■, the graph ink memory (22) is sent from the CPU (14).
) is supplied with data indicating the specified frame and the upper and lower temperature limits and written therein, and then sequentially read out under the control of the CPU (14) and supplied to the adder (19), and displayed on the display section (101).
The specified frame that has been changed to , marks indicating the upper and lower temperature limits, etc. will be displayed.

Further, in step (2), when the user instructs execution of the calculation by operating the keyboard (13), the calculation is executed in step (2) via step (2). And the CPU
(14), the image data representing the result is supplied to the graph ink memory (22) and written, and then the CP
It is read out sequentially under the control of U (14) and added to the adder (1
9), and the result is displayed on the display unit (101).

[Problem that the invention seeks to solve]

Conventionally, as shown in Fig. 8, the mark (32) indicating the upper limit temperature and lower limit temperature is displayed next to the color par (102) corresponding to the upper limit temperature and lower limit temperature. However, the upper temperature limit and the lower limit temperature are difficult to read, and the upper temperature limit and the lower limit temperature range cannot be identified in the image area of the display section (101).

The present invention takes these points into consideration and aims to make it possible to easily recognize the temperature setting range.

[Means for solving problems]

The present invention sequentially scans an object (2) to be measured in horizontal and vertical directions, supplies infrared rays emitted from each scanning position depending on the temperature to an infrared sensor (1), and ) is converted into a signal corresponding to temperature by a linearizer (7), this converted signal is written as m-image data in the image memory (11), and this image memory (
The image data from 11) is supplied to a color conversion circuit (18), and the primary color signal from this color conversion circuit (18) causes the temperature at each scanning position of the object to be measured (2) to be determined within a plurality of temperature ranges. An infrared temperature measurement device that two-dimensionally displays which region the temperature falls into, and has means for changing the conversion table of the color conversion circuit (18), and changes the conversion table according to the temperature setting range for image calculation. This allows the temperature setting range to be displayed in color or black and white.

[Effect]

In the above configuration, the temperature setting range is displayed separately in color or black and white.
In 2), the portions corresponding to the upper and lower temperature limits are displayed in color, and the other portions are displayed in black and white, making it easier to follow the upper and lower temperature limits. Also, for example, in the image area of the display unit (101), the portion corresponding to the upper limit temperature and lower limit temperature is displayed in color, and the other portions are displayed in black and white, so the upper limit temperature.

The lower limit temperature range can be easily identified.

〔Example〕

An embodiment of the present invention will be described below with reference to FIG. In FIG. 1, parts corresponding to those in FIG. 4 are designated by the same reference numerals, and detailed explanation thereof will be omitted.

In this example, the color conversion circuit (18) is configured to have a conversion table for monochrome display in addition to the conversion table for color display as in the example of FIG. in this case,
When the conversion table of the color conversion circuit (18) is changed to one for color display, this color conversion circuit (18)
From 18) onwards, the image memory (11) as in the example in Figure 4.
The color conversion circuit (18) outputs three primary color signals of red, green, and blue for color display corresponding to the image data supplied from the image memory. (11) Three colors of red, green, and blue, each at the same level, corresponding to the image data supplied by
Primary color signals (three primary color signals for black and white display) are output.

The conversion table of this color conversion circuit (18) is changed by C.
Normally, a conversion table for color display is selected, but when performing image calculation processing, the upper limit temperature is controlled by the PU (14).

When the lower limit temperature is set, if the image data supplied from the image memory (11) corresponds to the upper limit temperature and lower limit temperature, a conversion table for color display is selected; otherwise, the conversion table is selected. , the conversion table for black and white display is selected.

For example, the image calculation process in this example is performed according to a flowchart as shown in FIG.

In the same figure, in step ■, the user presses the keyboard (1
When a display mode such as frequency distribution is selected by operating 3), the processing state of the selected mode is entered, and initial values such as a specified frame, upper limit temperature, lower limit temperature, etc. are set. Then, in step (2), data indicating the specified frame from the CPU (14) is added via the graphic memory (22)! (19), and as a result, the designated frame is displayed, for example, in white, on the display section (101) on the screen (10G) of the color display (21). In parallel with this, C.
Under the control of the PU (14), the color conversion circuit (18)
If the image data supplied from the image memory (11) corresponds to the upper and lower temperature limits as a conversion table, a conversion table for color display is selected, and if it is other than that, a conversion table for black and white display is selected. conversion table is selected. As a result, among the color pars (102),
Parts corresponding to the upper and lower temperature limits are displayed in color, and other parts are displayed in black and white. In addition, the display section (
Of the image area 101), the portions corresponding to the upper and lower temperature limits are displayed in color, and the other portions are displayed in black and white. FIG. 3 shows an example of the display on the screen (100) when the average temperature mode is selected. The shaded areas of the color par (102) and the display section (101) each indicate a portion to be displayed in color.

Returning to FIG. 2, in step 2, the user selects the specified frame and upper limit temperature by operating the keyboard (13).

When instructed to change the set value such as the lower limit temperature, the specified frame and upper limit temperature are changed through step ■ and step ■.

Setting values such as the lower limit temperature are changed. Then, in step (2), data indicating the specified frame from the CPU (14) is supplied to the adder (19) via the graphic memory (22), and the changed specified frame is displayed on the display section (101'). Ru. In parallel with this, the conversion table of the color conversion circuit (18) is changed under the control of the CPU (14), and the conversion table of the color conversion circuit (18) is changed.

The color and black and white display portions of the display section (101) are changed in accordance with the changed upper limit temperature and lower limit temperature.

Further, in step (2), when the user instructs execution of the calculation by operating the keyboard (13), the calculation is executed in step (2) via step (2). And the CPU
(14), image data representing the result is supplied to the adder (19) via the graphic memory (22),
The results are displayed on the display section (101).

According to this example, the portion of the color par (102) that corresponds to the upper and lower temperature limits is displayed in color, and the other portions are displayed in black and white, allowing the user to select the upper and lower temperature limits. This has the benefit of making the temperature easier to read.

Further, according to this example, of the image area of the display section (101), the portion corresponding to the upper limit temperature and lower limit temperature is displayed in color, and the portion corresponding to the upper limit temperature is displayed in black and white. Therefore, the user has the benefit of being able to easily identify the upper and lower temperature ranges.

Note that the color display part and the monochrome display part in the above embodiment may be reversed. This can be realized by reversing the selection of the conversion table of the color * conversion circuit (18). .

In addition, in the above embodiment, the upper and lower temperature limits were set, but for example, when performing image calculations by setting a predetermined threshold, the temperature portion higher than the threshold may be displayed in color or in black and white. By changing the conversion table of the color conversion circuit (18), it is also possible to display the temperature area lower than the threshold value in black and white or in color.

〔Effect of the invention〕

According to the present invention described above, since the temperature setting range for image calculation is displayed separately in color or black and white,
The user has the benefit of being able to easily recognize the temperature setting range.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram showing an embodiment of the present invention, FIGS. 2 and 3 are explanatory diagrams, and FIG. 4 is a configuration diagram of a conventional example.
FIGS. 5 to N48 are diagrams for explaining the same. (1) is an infrared sensor, (2) is an object to be measured, (7) is a beam nearer, (11) is an image memory, (13) is a keyboard, (14) is a CPU, (18) is a color conversion circuit,
(21) is a color display, (101) is a display section,
(102) is a color par.

Claims (1)

[Claims] The object to be measured is sequentially scanned in horizontal and vertical directions, and infrared rays emitted from each scanning position depending on the temperature are supplied to an infrared sensor, and the output signal of this infrared sensor is sent to a linearizer. The converted signal is converted into a signal corresponding to the above temperature, and this converted signal is written as image data to an image memory. The image data from this image memory is supplied to a color conversion circuit, and the primary color signal from this color conversion circuit is used to convert the An infrared temperature measurement device that two-dimensionally displays which region of a plurality of temperature regions the temperature of each scanning position of an object falls into, which has means for changing the conversion table of the color conversion circuit, and includes means for changing the conversion table of the color conversion circuit, An infrared temperature measurement device characterized in that the temperature setting range is displayed separately in color or black and white by changing the conversion table according to the temperature setting range.