JP2018194531A - Thermal image display device, infrared imaging device, and thermal image data display method - Google Patents

Abstract

To provide an infrared imaging device that, when displaying an infrared image, can appropriately automatically set a temperature scale for determining allocation of colors.SOLUTION: When creating a temperature scale for determining allocation of colors in display, an infrared imaging device excludes temperature data outside a target temperature range with a temperature threshold. This prevents the creation of the temperature scale from being influenced by the temperature data outside the target temperature range, and enables colored display of an object truly desired to be analyzed with high resolution.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a thermal image display device, an infrared imaging device, and a thermal image data display method.

The infrared imaging device developed, manufactured and sold by the present applicant is capable of measuring the temperature of a remote object and is used in various fields and applications. Thermal image data captured by the infrared imaging device is a collection of temperature data indicating the temperature of the object.
For example, at a steel mill, the surface temperature of a ladle that is hung on a rail and filled with molten iron is measured in a non-contact manner from a long distance, thereby monitoring the degree of scraping of the concrete inner pot.
In addition, an outer wall of a building is photographed with an infrared imaging device, and a peeling portion of the outer wall of the building is estimated from a portion where the temperature rise of the outer wall is uneven.

Infrared imaging devices currently manufactured and sold by the Applicant support temperature values corresponding to colors in the color palette to make it easier to visually recognize temperature values when displaying captured thermal image data on the display. In addition, it has a function of coloring and displaying thermal image data. There are various types of color palettes, but the infrared imaging devices manufactured and sold by the applicant are blue, green, yellow, and finally red, corresponding to high temperature values from low temperature values. A color palette called “Rainbow”, which changes color continuously, is adopted.
In the coloring process for associating a color with a temperature value, first, the temperature data is converted into a corresponding index value using a temperature scale. Next, the color corresponding to the index value calculated using the temperature scale is specified using the color palette. An infrared imaging device manufactured and sold by the applicant has a function of automatically setting a temperature scale.
By associating the temperature value with the color of the color pallet and displaying the thermal image data in a colored manner, the user of the infrared imaging device or the like can determine whether the temperature of the thermal image data is high or low. It becomes possible to display the image data in a visually easy-to-understand manner.

  Patent document 1 is mentioned as a prior art document considered to be related to this invention. Patent Document 1 discloses a technique related to a thermal image capturing system and a thermal image capturing apparatus that reliably detect a moving direction of a heating element and automatically generate a signal for capturing.

JP 2009-198254 A

  The automatic setting function of the temperature scale in the infrared imaging apparatus first acquires the highest temperature and the lowest temperature indicated by the temperature data included in the captured thermal image data. Then, the acquired highest temperature is set as the highest value of the temperature scale, and the lowest temperature is set as the lowest value of the temperature scale.

  When a cityscape or the like is photographed with an infrared imaging device to obtain urban thermal image data, the thermal image data includes temperature data corresponding to the sky. The temperature of the sky tends to be extremely low compared to the temperature of buildings on the ground. Therefore, the temperature scale automatic setting function employs temperature data corresponding to the sky as temperature data indicating the lowest temperature. Then, the temperature scale is dragged by the temperature of the sky, and the resolution of the temperature scale is lowered for the temperature data of the building in the city area, which is the object that is really desired to be analyzed. In other words, the temperature data of the urban building is compressed to a narrow color range due to the presence of the empty temperature data even though the temperature data of the urban building is originally intended to be visually recognized on the temperature scale.

  The present invention has been made in view of such a point, and an object of the present invention is to provide a thermal image display device, an infrared imaging device, and a thermal image data display method capable of appropriately automatically setting a temperature scale. To do.

  In order to solve the above problems, a thermal image display device according to the present invention is a thermal image display device that applies color processing to thermal image data that is an aggregate of temperature data indicating the temperature of an object, and A temperature comparison processing unit that performs temperature comparison processing based on the included temperature data, and a temperature scale that associates temperature values with colors based on the processing results of the temperature comparison processing unit, and thermal image data based on the temperature scale A display processing unit for performing a coloring process, and a display unit for displaying the thermal image data subjected to the coloring process output by the display processing unit.

The temperature comparison processing unit determines whether or not a position corresponding to the temperature data included in the thermal image data is included in a preset region of interest, and a temperature value indicated by the temperature data is set in advance. The position corresponding to the temperature data is included in the region of interest, and the temperature value indicated by the temperature data is the upper limit temperature threshold. And the minimum value and the maximum value of the temperature value indicated by the temperature data within the range specified by the lower limit temperature threshold value are calculated.
The display processing unit creates a temperature scale based on the processing result of the temperature comparison processing unit, and performs color processing on the thermal image data based on the temperature scale and the color palette.

According to the present invention, it is possible to provide a thermal image display device, an infrared imaging device, and a thermal image data display method capable of automatically and appropriately setting a temperature scale.
Problems, configurations, and effects other than those described above will be clarified by the following description of embodiments.

It is a block diagram which shows the hardware constitutions of the infrared imaging device which is an example of embodiment of this invention. It is a block diagram which shows the software function of an infrared imaging device. It is a flowchart which shows the flow of the coloring process with respect to temperature data. It is the conceptual diagram of the example of the thermal image data image | photographed with the prior art, the conceptual diagram of the setting procedure of the temperature scale in a prior art, and the conceptual diagram of the setting procedure of the temperature scale in embodiment of this invention. It is an example of the thermal image data image | photographed with the infrared imaging device which concerns on embodiment of this invention.

[Infrared imaging device 101: hardware configuration]
FIG. 1 is a block diagram illustrating a hardware configuration of an infrared imaging device 101, which is an example of an embodiment of the present invention.
Infrared light collected by the lens 102 is converted into an analog voltage signal by the infrared imaging device 103. The infrared imaging element 103 is placed on the carriage 104. In addition to the infrared imaging element 103, the carriage 104 has a buffer amplifier 105 that amplifies the analog voltage signal of the infrared imaging element 103, and converts the analog voltage signal of the infrared imaging element 103 amplified by the buffer amplifier 105 into digital raw data. An A / D converter 106 is also provided.

The digital raw data output from the A / D converter 106 is supplied through the input port 114 to the control unit 107 composed of a microcomputer.
A control unit 107, which is a microcomputer, is connected to a bus 113 by a CPU 108, a ROM 109, a RAM 110, a display unit 111 such as an LCD that displays a thermal image, which will be described later, and an operation unit 112 that receives user operations.
In addition to this, an input port 114, an output port 115, a nonvolatile storage 116 such as a flash memory, and a frame buffer 117 are connected to the bus 113. Note that the RAM 110 may have a large capacity, and the frame buffer 117 may also be used.

As the nonvolatile storage 116, for example, a flash memory is used. This flash memory can also be used as the ROM 109.
The ROM 109 or the nonvolatile storage 116 stores a program for operating the microcomputer as the control unit 107.
Digital raw data is temporarily stored in the frame buffer 117. The digital raw data is subjected to various arithmetic processing such as temperature correction processing by the control unit 107 and converted into digital temperature data. Then, it is output from the output port 115 to the outside.

[Infrared imaging device 101: software function]
FIG. 2 is a block diagram illustrating software functions of the control unit 107 of the infrared imaging device 101.
The digital raw data is temporarily stored in the frame buffer 117 through the input / output control unit 201. The input / output control unit 201 includes a functional block that performs predetermined processing on the raw data stored in the frame buffer 117.
The temperature data conversion processing unit 202 performs predetermined correction calculation processing on the raw data stored in the frame buffer 117 and converts the raw data into thermal image data that is a collection of data indicating the temperature of the object.

The region-of-interest coordinate information 204 stored in the RAM 110 is coordinate information of a region to be a target constituting the temperature scale 210 for the thermal image data. For example, the rectangular area in the frame can be designated by the coordinates of the upper left and lower right vertices using the coordinates in the frame.
The upper limit temperature threshold value 205 and the lower limit temperature threshold value 206 are used to calculate a minimum value and a maximum value for creating the temperature scale 210 in the RAM 110 out of the temperature data group in the region of interest specified by the region of interest coordinate information 204. Used to select the temperature data to be used. For example, when the temperature value indicated by the temperature data belonging to the region specified by the region-of-interest coordinate information 204 is out of the range of the upper limit temperature threshold value 205 or less and the lower limit temperature threshold value 206 or more, the temperature data indicates the temperature scale 210. It is excluded from the processing target for calculating the maximum value and the minimum value for creation.

The region-of-interest temperature maximum value 208 is within the range specified by the upper limit temperature threshold 205 and the lower limit temperature threshold 206 among the temperature values indicated by the temperature data in the region of interest specified by the region of interest coordinate information 204, And it is the highest temperature value. The region-of-interest temperature minimum value 207 is within the range specified by the upper limit temperature threshold 205 and the lower limit temperature threshold 206 among the temperature values indicated by the temperature data in the region of interest specified by the region of interest coordinate information 204, And it is the lowest temperature value.
The region-of-interest maximum temperature value 208 and the region-of-interest temperature minimum value 207 are the basis of the temperature scale 210.

The temperature comparison processing unit 203 sequentially investigates temperature data groups constituting the thermal image data stored in the frame buffer 117.
First, it is determined whether or not the address where the temperature data to be investigated is stored in the frame buffer 117 is included in the region of interest specified by the region-of-interest coordinate information 204.
Next, when the address of the temperature data is within the region of interest specified by the region-of-interest coordinate information 204, the temperature comparison processing unit 203 determines that the temperature value indicated by the temperature data is the upper limit temperature threshold 205 and the lower limit temperature threshold 206. It is determined whether it is within the range specified by.
Next, the temperature comparison processing unit 203 includes the address of the temperature data in the region of interest specified by the region of interest coordinate information 204, and the temperature value indicated by the temperature data includes the upper limit temperature threshold 205 and the lower limit. If it is within the range specified by the temperature threshold 206, it is determined whether or not the temperature value indicated by the temperature data is smaller than the minimum temperature value 207 in the region of interest, which is the minimum temperature value at this time. If the temperature value indicated by the temperature data is smaller than the region-of-interest temperature minimum value 207, the region-of-interest temperature minimum value 207 is updated with the temperature value indicated by the temperature data.

Next, the temperature comparison processing unit 203 includes the address of the temperature data in the region of interest specified by the region of interest coordinate information 204, and the temperature value indicated by the temperature data includes the upper limit temperature threshold 205 and the lower limit. If it is within the range specified by the temperature threshold 206, it is determined whether or not the temperature value indicated by the temperature data is greater than the maximum temperature value 208 in the region of interest, which is the maximum temperature value at this time. If the temperature value indicated by the temperature data is larger than the maximum temperature value 208 in the region of interest, the maximum temperature value 208 in the region of interest is updated with the temperature value indicated by the temperature data.
The display processing unit 209 creates a temperature scale 210 based on the region-of-interest temperature maximum value 208 and the region-of-interest temperature minimum value 207, and the color palette stored in the temperature scale 210 and the nonvolatile storage 116 from the thermal image data. Based on 211, colored image data is generated. Then, the image data is displayed on the display unit 111.
The location where the color palette 211 is stored may be the ROM 109 in addition to the nonvolatile storage 116.

[Infrared imaging device 101: operation]
FIG. 3 is a flowchart showing the flow of the coloring process for the thermal image data by the input / output control unit 201. In this flowchart, it is assumed that the thermal image data converted from the raw data by the temperature data conversion processing unit 202 is stored in the frame buffer 117 in advance.
When the process is started (S301), the input / output control unit 201 initializes the address information of the temperature data to be processed among the thermal image data for one frame stored in the frame buffer 117 (S302). . Specifically, the address information in the frame buffer 117 in which the corresponding temperature data is stored in the upper left corner of the screen is set as the address information of the processing target temperature data. In S302, the minimum region-of-interest temperature value 207 and the maximum region-of-interest temperature value 208 are also initialized. The initial value of the maximum value is the lower limit temperature threshold, and the initial value of the minimum value is the upper limit temperature threshold.

Next, the input / output control unit 201 confirms whether the address information of the temperature data currently being processed is within the region of interest (S303).
If the address information of the temperature data currently being processed is not within the range of the region of interest (NO in S303), the input / output control unit 201 has nothing to do with the temperature data because the temperature data is out of processing. Without confirmation, the process proceeds to step S310 where it is confirmed whether the address information of the temperature data is the final position of the current temperature data, that is, the address at the bottom right of the screen.

If the address information of the temperature data that is currently processed is within the region of interest (YES in S303), the temperature data is the processing target. Therefore, the temperature comparison processing unit 203 of the input / output control unit 201 next determines whether or not the temperature value indicated by the temperature data is within the range specified by the upper limit temperature threshold value 205 and the lower limit temperature threshold value 206 (S305). ).
When the temperature value indicated by the temperature data is not within the range specified by the upper limit temperature threshold 205 and the lower limit temperature threshold 206, that is, the temperature is higher than the upper limit temperature threshold 205 or lower than the lower limit temperature threshold 206 (S305). NO), the temperature data is not subject to comparison processing between the maximum temperature value 208 in the region of interest 208 and the minimum temperature value 207 of the region of interest which will be determined later. Therefore, the input / output control unit 201 proceeds to the process of step S310 for confirming whether the address information of the temperature data is the final position of the current temperature data, that is, the lower right address of the screen.

When the temperature data is within the range specified by the upper limit temperature threshold 205 and the lower limit temperature threshold 206, that is, the temperature is not more than the upper limit temperature threshold 205 and is not less than the lower limit temperature threshold 206 (YES in S305), The temperature data is a target of comparison processing between the maximum temperature value 208 in the region of interest 208 and the minimum temperature value 207 in the region of interest which will be determined later. Therefore, the temperature comparison processing unit 203 next determines whether or not the temperature value indicated by the temperature data is lower than the minimum temperature 207 in the region of interest at this time (S306). In FIG. 3, the minimum temperature value 207 in the region of interest is read as “minimum value” because of the number of displayed characters.
When the temperature value indicated by the temperature data is lower than the region-of-interest temperature minimum value 207 (YES in S306), at this time, the temperature value indicated by the temperature data is the lowest temperature within the region of interest. Therefore, the temperature comparison processing unit 203 overwrites the region-of-interest temperature minimum value 207 with the temperature value indicated by the current temperature data (S307).

In either case of step S307 and the case where the temperature value indicated by the temperature data is equal to or greater than the region-of-interest temperature minimum value 207 (NO in S306), the temperature comparison processing unit 203 next selects the temperature indicated by the temperature data. It is determined whether or not the value is higher than the region-of-interest temperature maximum value 208 (S308). In FIG. 3, the maximum temperature value 208 in the region of interest is read as “maximum value” because of the number of displayed characters.
When the temperature value indicated by the temperature data is higher than the maximum temperature value 208 in the region of interest (YES in S308), the temperature value indicated by the temperature data is the highest temperature within the region of interest range at this time. Therefore, the temperature comparison processing unit 203 overwrites the maximum temperature value 208 in the region of interest with the temperature value indicated by the current temperature data (S309).

In any case of NO in step S303, NO in step S305, NO in step S308, and step S309, the input / output control unit 201 next determines that the address information of the temperature data is the final position of the current temperature data, that is, It is confirmed whether or not the address is at the bottom right of the screen (S310).
If the address information of the current temperature data is not the final position of the thermal image data for one frame (NO in S310), the input / output control unit 201 increments the address information of the processing target temperature data (S304), and step S303 is performed again. Repeat the process.
When the address information of the current temperature data is the final position of the thermal image data for one frame (YES in S310), the display processing unit 209 of the input / output control unit 201 displays the current maximum temperature 208 in the region of interest and the interest. The in-region temperature minimum value 207 is determined. Based on these, the temperature scale 210 is created (S311). Then, the thermal image data is colored based on the created temperature scale 210 and the color palette 211 stored in the non-volatile storage 116 and displayed on the display unit 111 (S312), and the series of processing ends ( S313).

FIG. 4A is an example of thermal image data taken by the prior art. In FIG. 4A, the thermal image data which image | photographed the building of a city area is shown as an example.
In FIG. 4A, there is a house roof at point P401. In FIG. 4A, this point P401 is the place showing the highest temperature.
Point P402 is the upper floor of the high-rise housing complex. In FIG. 4A, this point P402 is a place showing the lowest temperature “among the buildings reflected in this thermal image data”.
Point P403 is empty. In FIG. 4A, this point P403 is a portion indicating the lowest temperature “among the thermal image data”.
In FIG. 4A, a region surrounded by a dotted line is a region of interest A404.
At the right end of FIG. 4A, a temperature scale created based on points P401 and P403 and a color bar S405 displayed based on a color palette are displayed.

FIG. 4B is a conceptual diagram of a temperature scale setting procedure in the prior art.
The temperature of the point P401 existing in the region of interest A404 in FIG. 4A corresponds to the temperature value T406. Similarly, the temperature at the point P402 in FIG. 4A corresponds to the temperature value T407. Therefore, the temperature range between the temperature value T406 and the temperature value T407 is the range of the temperature distribution of the building in the urban area in the thermal image data of FIG. 4A.
However, sky is reflected in the region of interest A404, and for this reason, the temperature at the point P403 in FIG. 4A corresponds to the temperature value T408. Then, in the temperature range R409 of the temperature scale, the temperature upper limit value becomes the temperature value T406, and the temperature lower limit value becomes the temperature value T408. For this reason, the resolution of a temperature scale falls and it becomes difficult to examine in detail the temperature distribution of the building reflected in thermal image data.
Specifically, when the color palette “Rainbow” is used, the lowest temperature is dyed blue based on the temperature scale. This blue color is assigned to a temperature value T408 that is sky temperature data. When the color palette “Rainbow” is used, the temperature value T407 at the point P402, which is the upper floor of the high-rise housing complex, is set to yellowish green based on the temperature scale.

FIG. 4C is a conceptual diagram of a temperature scale setting procedure based on the embodiment of the present invention.
FIG. 5 is an example of thermal image data photographed based on the embodiment of the present invention.
Before determining the temperature upper limit value and the temperature lower limit value, an upper limit temperature threshold T410 and a lower limit temperature threshold T411 are determined in advance.
As shown in FIG. 4C, temperature data that falls outside the range of the upper limit temperature threshold value T410 and the lower limit temperature threshold value T411 is excluded from the targets for determining the upper temperature limit value and the lower temperature limit value (step S305 in FIG. 3). . Then, the temperature value T408, which is an empty temperature, falls below the lower limit temperature threshold value T411, and thus deviates from the temperature lower limit value determination candidate. And a temperature lower limit becomes temperature value T407 of point P402 which is the temperature of an original building. That is, in the temperature range R412 of the temperature scale, the temperature upper limit value is the temperature value T406, and the temperature lower limit value is the temperature value T407. For this reason, the resolution of the temperature scale is ensured, and the temperature distribution of the building reflected in the thermal image data can be examined in detail.
As a result, when the color palette “Rainbow” is used, based on the temperature scale, the blue color corresponding to the lowest temperature is assigned to the temperature value T407 of the point P402 which is the upper floor of the high-rise housing estate. An empty portion (point P403, temperature value T408) is also displayed in blue corresponding to the lowest temperature of the color palette “rainbow” (the color corresponds to the lowest temperature).

The appropriate upper limit temperature threshold value 205 and lower limit temperature threshold value 206 vary depending on the object to be imaged. Therefore, the upper limit temperature threshold 205 and the lower limit temperature threshold 206 constitute a predetermined GUI (Graphical User Interface) using the display unit 111 and the operation unit 112, and are set by numerical input or the like.
The present invention can also be carried out when the thermal image data that has already been photographed and created is displayed in color. Therefore, the embodiment is not necessarily limited to the infrared imaging apparatus, and can be implemented even with an upper processing apparatus such as a personal computer. In this case, the hardware configuration of the information processing apparatus is such that the control unit 107 in FIG. 1 is independent as an information processing apparatus such as a personal computer. The software function of the information processing apparatus has a function excluding the temperature data conversion processing unit 202 among the functions as the control unit 107 shown in the block diagram of FIG. 2, and reads thermal image data instead of raw data. Then, the information processing apparatus executes data processing according to the flowchart of FIG.

  The infrared imaging device 101 disclosed in the embodiment of the present invention excludes temperature data outside the target temperature range according to a temperature threshold when color-displaying thermal image data created by photographing with an infrared imaging element. For this reason, it is possible to prevent the temperature scale 210 from being affected by temperature data outside the target temperature range, and to color-display the target to be truly analyzed with high resolution.

If the imaging function is removed from the infrared imaging device 101, it can be diverted to a thermal image display device that applies color processing to thermal image data that is an aggregate of temperature data indicating the temperature of an object.
That is, the thermal image display device
A temperature comparison processing unit that executes a temperature comparison process based on the temperature data included in the thermal image data;
Based on the processing result of the temperature comparison processing unit, a temperature scale that associates the temperature value with the color is created, and a display processing unit that performs color processing on the thermal image data based on the temperature scale;
A display unit for displaying the thermal image data subjected to the coloring process output by the display processing unit,
The temperature comparison processor
It is determined whether or not the position corresponding to the temperature data included in the thermal image data is included in the preset region of interest,
Furthermore, it is determined whether or not the temperature value indicated by the temperature data is within a range specified by the preset upper limit temperature threshold and lower limit temperature threshold,
The position corresponding to the temperature data is included in the region of interest, and the temperature value indicated by the temperature data is within the range specified by the upper limit temperature threshold value and the lower limit temperature threshold value. Calculate the maximum value,
The display processing unit creates a temperature scale based on the processing result of the temperature comparison processing unit, and performs color processing on the thermal image data based on the temperature scale and the color palette.

The embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and other modifications and application examples are provided without departing from the gist of the present invention described in the claims. including.
For example, the above-described embodiment is a detailed and specific description of the configuration of the apparatus and the system in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to the one having all the described configurations. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Moreover, it is also possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.

DESCRIPTION OF SYMBOLS 101 ... Infrared imaging device, 102 ... Lens, 103 ... Infrared imaging device, 104 ... Carriage, 105 ... Buffer amplifier, 106 ... A / D converter, 107 ... Control part, 108 ... CPU, 109 ... ROM, 110 ... RAM, DESCRIPTION OF SYMBOLS 111 ... Display part, 112 ... Operation part, 113 ... Bus, 114 ... Input port, 115 ... Output port, 116 ... Non-volatile storage, 117 ... Frame buffer, 201 ... Input / output control part, 202 ... Temperature data conversion process Reference numeral 203: Temperature comparison processing unit 204: Region of interest coordinate information 205: Upper limit temperature threshold value 206: Lower limit temperature threshold value 207: Minimum temperature value in the region of interest 208: Maximum temperature value in the region of interest 209: Display processing Part

Claims (3)

A thermal image display device that performs a coloring process on thermal image data that is an aggregate of temperature data indicating the temperature of an object,
A temperature comparison processing unit that executes a temperature comparison process based on temperature data included in the thermal image data;
Based on the processing result of the temperature comparison processing unit, a temperature scale that associates a temperature value with a color is created, and a display processing unit that performs a coloring process on the thermal image data based on the temperature scale;
A display unit that displays the thermal image data that has been subjected to the coloring process that is output by the display processing unit;
The temperature comparison processing unit
Determining whether a position corresponding to the temperature data included in the thermal image data is included in a preset region of interest;
Furthermore, it is determined whether or not the temperature value indicated by the temperature data is within a range specified by a preset upper limit temperature threshold and lower limit temperature threshold,
The temperature data indicates that a position corresponding to the temperature data is included in the region of interest, and a temperature value indicated by the temperature data is within a range specified by the upper limit temperature threshold and the lower limit temperature threshold. Calculate the minimum and maximum temperature values,
The display processing unit creates a temperature scale based on the processing result of the temperature comparison processing unit, and performs a coloring process on the thermal image data based on the temperature scale and a color palette.
Thermal image display device. An infrared imaging device that images the temperature of the object and outputs an analog temperature signal;
An A / D converter that converts an analog temperature signal of the infrared imaging device into digital raw data;
A temperature data conversion processing unit that converts the digital raw data into thermal image data that is a collection of data indicating the temperature of the object;
The infrared imaging device according to claim 1, further comprising the thermal image display device that performs a coloring process on the thermal image data. A region-of-interest range determination step for determining whether or not a position corresponding to the temperature data included in the thermal image data that is a collection of data indicating the temperature of the object is included in the region of interest set in advance;
A temperature threshold range determination step for determining whether or not the temperature value indicated by the temperature data is within a range specified by a preset upper limit temperature threshold and a lower limit temperature threshold;
A position corresponding to the temperature data in the region of interest determination step is included in the region of interest, and the temperature value indicated by the temperature data in the temperature threshold range determination step is the upper limit temperature threshold and the lower limit When it is within the range specified by the temperature threshold, it is determined whether or not the temperature value indicated by the temperature data is the minimum value of the temperature value in the region of interest, and if it is the minimum, the minimum value is updated. A minimum value judgment update step to be performed;
A position corresponding to the temperature data in the region of interest determination step is included in the region of interest, and the temperature value indicated by the temperature data in the temperature threshold range determination step is the upper limit temperature threshold and the lower limit If it is within the range specified by the temperature threshold, it is determined whether or not the temperature value indicated by the temperature data is the maximum value of the temperature value in the region of interest, and if it is maximum, the maximum value is updated. A maximum value checking and updating step
A temperature scale creating step for creating a temperature scale based on the minimum value and the maximum value;
A thermal image data display method comprising: a thermal image display step of performing color processing on the thermal image data based on the temperature scale.