The present invention relates to a method and a system of measuring surface temperature.
When object temperature is measured by radiation thermometry using a two-dimensional thermal imaging device or a one-dimensional scanning thermometer, normally, the emissivity of an object or the distribution thereof is unknown and changes depending on measurement conditions and the surface state. Thus, information of accurate surface temperature or temperature distribution can not be obtained from radiance detected by the thermal imaging device or the scanning radiation thermometer.
Moreover, even if the material emissivity of each area to be measured is known, in the case where fine emissivity distribution is present, there is also a problem in that apparent emissivity is different from the known emissivity due to the limitations of the imaging characteristics of the thermal imaging device.
In addition, various attempts have been made to correct for unknown emissivity, but unfortunately, there is no method suitable for measurement responding to a fast-changing object temperature.
The following methods have been previously applied to measure the temperature of an object whose emissivity is unknown in a non-contact manner by a radiation thermometer or a thermal imaging device.
(1) A method of measuring the radiance distribution after heating an object to a known temperature using a heater, in order to find the emissivity distribution of an object to be measured.
(2) A method of detecting two polarizations of a light beam in a spot-type radiation temperature measurement, measuring the object reflectance ratio in the two polarizations, and correcting emissivity from the ratio, as an emissivity correction technique in FLA (see Patent Document 1).
(3) A method of superimposing reflected light from a blackbody auxiliary radiating source on the object, regulating the temperature of the auxiliary radiation source so that the sum of the thermal radiance from the object and the reflected radiance from the object becomes equal to thermal radiance from the auxiliary radiating source, and measuring the temperature of the auxiliary radiating source at that time using a contact-type thermometer to determine the object temperature from the measured temperature (see Non-Patent Document 1).
(4) A method for obtaining the true object temperature through an arithmetic operation from measured radiances of a high-emissivity portion and a low-emissivity portion using an infrared radiation thermometer or a thermography capable of simultaneously measuring two or more points before and after changing the environmental temperature by means of an environmental radiance temperature switching device, such as a thermal infrared source as an auxiliary heat source before which a shutter is attached (see Patent Document 2).
However, each of these related arts have problems in the following points.
The method of (1) requires an additional process of heating the object using the heater and, in addition, a means to detect the object temperature at this time.
In the method of (2), polarizing optical elements are required, and thus the application of this method to long-wavelength infrared light used in low temperature radiation thermometry results in high cost. In addition, this method is not suitable for surface distribution measurement.
In the method of (3), the auxiliary radiation source is required to be a blackbody, but it is difficult to obtain a satisfactory blackbody having a planer form. When the auxiliary radiation source is not a blackbody, correction is required, but sufficient accuracy is not obtained. In addition, it is required to measure both the auxiliary radiating source and the object to be measured, and the above method cannot be applied to a case where a fast-changing object temperature is measured. In addition, the system structure becomes complicated.
In the method of (4), it is required to measure the temperature while switching the environmental temperature in a step form. The above method is not therefore suitable for measuring a fast-changing object temperature. In addition, the system becomes complicated.
The first task of the present invention is to provide a measuring method and a measuring system that are capable of accurately measuring a fast-changing surface temperature of a surface to be measured, without using an expensive optical element, being immune to the emissivity distribution of the surface to be measured.
In addition, the second task of the present invention is to provide a measuring method and a measuring system that are capable of accurately measuring the temperature of a surface to be measured being immune to the emissivity distribution of the surface to be measured, without expensive optical elements or a structurally-complex device.
According to the first aspect of the present invention, the following method and system of measuring the surface temperature are provided in order to solve the first task.
(1) A method of measuring surface temperature, including: preparing a surface to be measured that has an emissivity distribution, a radiometer that measures a radiance distribution of the surface to be measured, and an auxiliary heat source installed in a specular reflection position from the radiometer with respect to the surface to be measured; measuring radiances of two places having different emissivities of the surface to be measured at two different auxiliary-heat-source temperatures; calculating a reflectance ratio between the two places having the different emissivities on the basis of two measured radiances of the two places having the different emissivities; and obtaining the temperature of the surface to be measured, using the reflectance ratio and the measured radiances of the two places having the different emissivities.
(2) A system of measuring surface temperature, including: a surface to be measured that has an emissivity distribution; a radiometer that measures a radiance distribution of the surface to be measured; and an auxiliary heat source installed in a specular reflection position from the radiometer with respect to the surface to be measured, wherein radiances of two places having different emissivities of the surface to be measured are measured at two different auxiliary-heat-source temperatures, a reflectance ratio between the two places having the different emissivities is calculated on the basis of two measured radiances of the two places having the different emissivities, and the temperature of the surface to be measured is obtained using the reflectance ratio and the measured radiances of the two places having the different emissivities.
(3) The system of measuring surface temperature according to the above (2), wherein the radiometer that measures a radiance distribution is a thermal imaging device or a one-dimensional scanning radiometer.
According to the second aspect of the present invention, the following method and system of measuring surface temperature is provided in order to solve the second task.
(4) A method of measuring surface temperature, including: preparing a surface to be measured that has an emissivity distribution, a radiometer that measures a radiance distribution of the surface to be measured, and a radiance-variable auxiliary heat source installed in a specular reflection position from the radiometer with respect to the surface to be measured; changing radiance of the auxiliary heat source so that measured radiances of a high-emissivity portion and a low-emissivity portion of the surface to be measured become equal to each other; and obtaining the temperature of the surface to be measured from the measured radiances at that time.
(5) A system of measuring surface temperature, including: a surface to be measured that has an emissivity distribution; a radiometer that measures a radiance distribution of the surface to be measured; and a radiance-variable auxiliary heat source installed in a specular reflection position from the radiometer with respect to the surface to be measured, wherein a radiance of the auxiliary heat source is changed so that the measured radiances of a high-emissivity portion and a low-emissivity portion of the surface to be measured become equal to each other, and the temperature of the surface to be measured is obtained from the measured radiances at that time.
(6) The system of measuring surface temperature according to the above (5), wherein the radiometer that measures the radiance distribution is a thermal imaging device or a one-dimensional scanning radiometer.
According to the present invention, surface temperature distribution can be accurately measured without being influenced by the emissivity distribution of the object, in a surface temperature distribution measurement intended for heating area identification and generated heat measurement within a semiconductor device or within a circuit component using a power device, or a surface temperature distribution measurement intended for plant facility inspection or defect detection of a building structure. In addition, according to the first aspect of the present invention, accurate measurement is possible of a fast-changing surface temperature distribution. In addition, according to the second aspect of the present invention, surface temperature measurement is possible without using a structurally-complex device.
In addition, the object temperature can be accurately measured without being influenced by the blurring of the imaging, even for an object to be measured such as an electronic device having a fine emissivity pattern approaching the limit of the imaging capabilities of the thermal imaging device.
(Principle of the Present Invention)
When radiance distribution is measured by a thermal imaging device with attention on a portion having a large variation in the emissivity distribution on the surface to be measured, the emissivity distribution is detected as the radiance distribution. Assume, at this time, that the temperature of the object is uniform in a certain region, or the temperature distribution is spatially sufficiently smooth in comparison with the emissivity distribution.
First, a first invention will be described.
As shown in
Next, the blackbody radiance is calculated using Expression (9) represented below from measured radiance of the high-emissivity portion and the low-emissivity portion and the ratio between reflectances calculated from the values. Treating the object as a blackbody of which the emissivity is 1, the object temperature is obtained by applying the Planck's law of radiation. Thus, the true temperature of the object can be found without the need for finding the object emissivity distribution.
The measurement principle of the first invention will be described below in detail.
Let the emissivities of the higher-emissivity portion and the lower-emissivity portion to be εHi and εLo, and the reflectances thereof to be ρHi and ρLo, respectively, in two places of which the emissivities of the object to be measured that has an emissivity distribution are different from each other. When the object is an opaque body, the relations εHi+ρHi=1 and εLo+ρLo=1 hold from the Kirchhoff's law.
When the thermal radiance of the auxiliary heat source is LHeat-source,1, thermal radiances SHi,1 and SLo,1 of the high-emissivity portion and the low-emissivity portion are expressed by the following expressions, respectively.
S
Hi,1=εHiL(T)+ρHiLHeat-source,1 (1)
S
Lo,1=εLoL(T)+ρLoLHeat-source,1 (2)
Herein, T is the temperature of the object to be measured, and L(T) is the thermal radiance of the blackbody of temperature T.
Next, the thermal radiance of the auxiliary heat source is changed to LHeat-source,2, and thermal radiances SHi,2 and SLo,2 of the high-emissivity portion and the low-emissivity portion are expressed by the following expressions, respectively.
S
Hi,2=εHiL(T)+ρHiLHeat-source,2 (3)
S
Lo,2=εLoL(T)+ρLoLHeat-source,2 (4)
The ratio Rρ between the reflectances of the high-emissivity portion and the low-emissivity portion can be calculated from the four measured quantities SHi,1, SLo,1, SHi,2, and SLo,2 and is obtained by the following Expression (5) derived from Expressions (1) to (4).
R
ρ=ρHi/ρLo=(SHi,2−SHi,1)/(SLo,2−SLo,1) (5)
When the relations of εHi+ρHi=1 and εLo+ρLo=1 are applied to Expressions (3) and (4) and are transformed, Expressions (6) and (7) are obtained.
S
Hi,2
=L(T)+ρHi(−L(T)+LHeat-source,2) (6)
S
Lo,2
=L(T)+ρLo(−L(T)+LHeat-source,2) (7)
When L(T) is subtracted from both sides of Expressions (6) and (7) and then the ratio is taken and Expression (5) is applied, Expression (8) is obtained.
(SHi,2−L(T))/(SLo,2−L(T))=Rρ (8)
When Expression (8) is transformed, L(T) can be expressed in the form of Expression (9) using Rρ.
L(T)=(SHi,2−RρSLo,2)/(1−Rρ) (9)
The accurate temperature T is obtained from the measured radiance L(T) by treating the emissivity as 1. That is, it is possible to perform measurement in which unknown emissivity is corrected. Note that Expressions (6) to (9) are established even when SHi,2, SLo,2, and LHeat-source,2 are replaced by SHi,1, SLo,1, and LHeat-source,1, respectively.
Moreover, Expression (9) is a relational expression that is always established regardless of the auxiliary-heat-source radiance LHeat-source or the object temperature T. For this reason, the use of the ratio Rρ obtained in advance and the radiances SHi and SLo measured at an arbitrary timing enables calculating L(T) at that time on the basis of Expression (9), unless the reflectance ratio Rρ changes with time.
Accordingly, when measuring a phenomenon in which temperature changes fast, the measurement responding to the object temperature variation is enabled: by obtaining Rρ from the radiance measurement at two auxiliary-heat-source temperatures in steady state before starting the temperature change of the object; and by correcting the emissivity by Expression (9), using the value of this Rρ in a state where the auxiliary-heat-source radiance is unchanged after starting the temperature change of the object.
Herein, as a method of achieving a different auxiliary-heat-source temperature, the front surface of the auxiliary heat source may be covered by a shutter or the like having a temperature different from that of the auxiliary heat source and may be opened and closed, instead of changing the auxiliary-heat-source temperature in a step form. In this case, LHeat-source,2 is a value obtained by combining the thermal radiation radiated by the shutter with the reflected radiance from the surroundings by the shutter.
Next, a second invention will be described.
Similarly to the first invention, as shown in
At this time, since the relation of reflectance+emissivity=1 is established in an opaque surface from the Kirchhoff's law, the reflectance of the low-emissivity portion is higher. When the temperature of the auxiliary heat source is changed in this state, the radiance distribution changes, and the radiances of the high-emissivity portion and the low-emissivity portion increase with a rise in the auxiliary-heat-source temperature. However, in the way of the increase, the low-emissivity portion having high reflectance increases, and the difference between the radiances decreases. When the auxiliary-heat-source temperature is further increased, the difference between the radiances is no longer present, and thus the pattern due to the emissivity distribution of an image detected by the thermal imaging device disappears. When the heat-source temperature is further increased, the distributions of the radiances are inverted. Thus, the radiance of the low-emissivity portion becomes higher than that of the high-emissivity portion, and an emissivity distribution pattern comes in sight again. The object temperature is obtained: by detecting the radiance when the difference between the radiances is not present, that is, the emissivity distribution pattern of the image disappears; and by applying the Planck's law of radiation, treating the object as a blackbody of which the emissivity is 1. Thus, the true temperature of the object can be found without the need for finding the object emissivity distribution.
The measurement principle of the second invention will be described below in detail.
Let the emissivity of the high-emissivity portion of the object to be measured that has an emissivity distribution to be εHi, and the emissivity of the low-emissivity portion to be εLo.
The thermal radiances SHi and SLo of the high-emissivity portion and the low-emissivity portion are expressed by the following expressions, respectively.
S
Hi=εHiL(T)
S
Lo=εLoL(T)
Herein, L(T) is the thermal radiance of a blackbody of temperature T.
Next, an auxiliary heat source of radiance LHeat-source is installed, and radiation of the auxiliary heat source is superimposed on the object radiation. The radiances detected by the thermal imaging device are given as follows.
S
Hi=εHiL(T)+ρHiLHeat-source
S
Lo=εLoL(T)+ρLoLHeat-source
Herein, the reflectance of the high-emissivity portion is set to ρHi, and the reflectance of the low-emissivity portion is set to ρLo.
Herein, the auxiliary-heat-source radiance LHeat-source is regulated so that the high-emissivity portion and the low-emissivity portion are equal to each other.
That is, from SHi=SLo
εHiL(T)+ρHiLHeat-source=εLoL(T)+ρLoLHeat-source
When −L(T) is added to both sides of the above expression, and then the expression is transformed using the relations of εHi+ρHi=1 and εLo+ρLo=1 obtained from the Kirchhoff's law, the following expression is obtained.
ρHi(−L(T)+LHeat-source)=ρLo(−L(T)+LHeat-source)
Due to the relation of ρHi≠ρLo, the equal sign is established when L(T)=LHeat-source.
At this time, since the following expression is established
S
Hi
=S
Lo=εHiL(T)+ρHiL(T)=εLoL(T)+ρLo(T)=L(T)
the measured radiance SHi=SLo is equal to the radiance from a blackbody of the same temperature T as that of the object, and the accurate temperature T is obtained from the measured radiance SHi=SLo by treating the emissivity as 1.
The emissivity distribution of the object focused on the first and second inventions may be, for example, a metal interconnect pattern on a circuit substrate or a device, a pattern caused by a fine structure distribution of the device. In addition, when the usable emissivity distribution is not present, a coating material, a metal film or the like may be coated or pasted on the object surface.
An embodiment of the first invention will be described below. The thermal imaging device captures a two-dimensional thermal image with a focus on a surface to be measured. Here, an object to be measured is a print circuit board, a semiconductor device or the like. A surface blackbody device of which the surface is blackened is used as the auxiliary heat source. First of all, thermal images are taken when changing the temperature of the auxiliary heat source in a step form while the object temperature is maintained approximately constant, or opening and closing the shutter that covers the front surface of the auxiliary heat source. Next, in the thermal images obtained, one place is selected from each of the high-emissivity portion and the low-emissivity portion which are so close as to be regarded to be isothermal. The radiances of the high-emissivity portion and the low-emissivity portion of the 2-level thermal image are obtained, the reflectance ratio Rρ is obtained on the basis of Expression (5), and the radiance L(T) is further obtained using Expression (9). The object temperature is obtained from the radiance measured at this time treating the emissivity as 1.
Examples of the thermal images obtained when the temperature of the auxiliary heat source is changed in a step form are shown in
In this example, the measured radiance temperature of the high-emissivity portion a in
It can be seen from
In this manner, generally, the size-of-source effect changes the apparent radiance temperature, and thus obstructs an accurate temperature measurement. In response to such a problem, the following describes that the present invention can eliminate the influence.
The increase and decrease in the radiance due to the size-of-source effect are proportional to the radiance difference between the high-emissivity portion and the low-emissivity portion. As the proportional ratio, the radiance is observed to decrease by rHi in the high-emissivity portion a which is a measurement place of the fine line portion, and the radiance is observed to increase by rLo in the low-emissivity portion b.
Herein, rHi and rLo are coefficients that represent the size-of-source effect. The following expressions are obtained by rewriting Expressions (1) to (4) in consideration of the size-of-source effect.
S
Hi,1=(1−rHi)(εHiL(T)+ρHiLHeat-source,1)+rHi(εLoL(T)+ρLoLHeat-source,1)
S
Lo,1=(1−rLo)(εLoL(T)+ρLoLHeat-source,1)+rLo(εHiL(T)+ρHiLHeat-source,1)
S
Hi,2=(1−rHi)(εHiL(T)+ρHiLHeat-source,2)+rHi(εLoL(T)+ρLoLHeat-source,2)
S
Lo,2=(1−rLo)(εLoL(T)+ρLoLHeat-source,2)+rLo(εHiL(T)+ρHiLHeat-source,2)
When Rρ is calculated similarly to Expression (5), the following expression is obtained.
R
ρ=(SHi,2−SHi,1)/(SLo,2−SLo,1)=((1−rHi)ρHi+rHiρLo)/((1−rLo)ρLo+rLoρHi)
On the other hand, when transformation is performed similarly to Expressions (6) and (7), SHi,2 and SLo,2 are as follows.
S
Hi,2=(1−rHi)(L(T)−ρHi(L(T)−LHeat-source,2))+rHi(L(T)−ρLo(L(T)−LHeat-source,2))=L(T)−ρHi((1−rHi)+ρLorHi)(L(T)−LHeat-source,2))
S
Lo,2
=L(T)+ρLo((1−rLo)+ρHirLo)(L(T)−LHeat-source,2))
When transformation is performed similarly to the derivation of Expression (8), the relation of (SHi,2−L(T))/(SLo,2−L(T))=Rρ is obtained.
This is the same as Expression (8). Accordingly, the true temperature T can be obtained by obtaining the blackbody radiation L(T) using (9) expression. This shows that, even when the apparent radiance temperature changes due to the size-of-source effect, the accurate temperature can be measured without being influenced by the effect.
An embodiment of the second invention will be described below. The thermal imaging device captures a two-dimensional thermal image with a focus on a surface to be measured. Here, an object to be measured is a print circuit board, a semiconductor device or the like. A surface blackbody device of which the surface is blackened is used as the auxiliary heat source. In this state, while the object temperature is maintained approximately constant and the temperature of the auxiliary heat source is changed, the thermal image is measured to find out conditions in which a pattern of the thermal image caused by the emissivity distribution of the object to be measured disappears.
The object temperature is obtained from the radiance measured at this time treating the emissivity as 1. When the emissivity of the auxiliary heat source is sufficiently close to 1, the object temperature may be obtained by measuring the auxiliary-heat-source temperature using a contact-type thermometer or the like.
Examples of the thermal images obtained when the temperature of the auxiliary heat source is raised are shown in
In
On the other hand, a radiance distribution pattern (see 11 in
In the first and second embodiments, the surface blackbody device is used as the auxiliary heat source, but the auxiliary heat source is not limited thereto. For example, any auxiliary heat sources may be used, provided that the surface of the light source is sufficiently large with respect to the object to be measured, and the radiance is uniform and variable (e.g., an integrating sphere including a lamp light source or a laser light source, a liquid temperature bath surface, a planar heater, or the like).
In addition, in cases where the thermal imaging device measures a high-temperature object, the thermal imaging device may also be a camera such as a CCD that measures visible light and near infrared light. In addition, measurement by a linear sensor may be used instead of using a two-dimensional image.
Number | Date | Country | Kind |
---|---|---|---|
2010276899 | Dec 2010 | JP | national |
2010276941 | Dec 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/078536 | 12/9/2011 | WO | 00 | 7/8/2013 |