The Sakuma–Hattori equation is a mathematical model for predicting the amount of

thermal radiation Thermal radiation is electromagnetic radiation generated by the thermal motion of particles in matter. Thermal radiation is generated when heat from the movement of charges in the material (electrons and protons in common forms of matter) i ...

, radiometric flux or radiometric power emitted from a perfect

blackbody A black body or blackbody is an idealized physical body that absorbs all incident electromagnetic radiation, regardless of frequency or angle of incidence. The name "black body" is given because it absorbs all colors of light. A black body ...

or received by a thermal radiation detector.

History

The Sakuma–Hattori equation was first proposed by Fumihiro Sakuma, Akira Ono and Susumu Hattori in 1982. In 1996, a study investigated the usefulness of various forms of the Sakuma–Hattori equation. This study showed the Planckian form to provide the best fit for most applications. This study was done for 10 different forms of the Sakuma–Hattori equation containing not more than three fitting variables. In 2008, BIPM CCT-WG5 recommended its use for radiation thermometry uncertainty budgets below 960 °C.

General form

The Sakuma–Hattori equation gives the electromagnetic signal from thermal radiation based on an object's

temperature Temperature is a physical quantity that expresses quantitatively the perceptions of hotness and coldness. Temperature is measurement, measured with a thermometer. Thermometers are calibrated in various Conversion of units of temperature, temp ...

. The signal can be electromagnetic flux or signal produced by a detector measuring this radiation. It has been suggested that below the silver point, a method using the Sakuma–Hattori equation be used. In its general form it looks like

S(T) = \frac,

where: *

C

is the scalar coefficient *

c_2

is the second radiation constant (0.014387752 m⋅K) *

\lambda_x

is the temperature-dependent effective wavelength in meters *

T

is the absolute temperature in

kelvin The kelvin, symbol K, is the primary unit of temperature in the International System of Units (SI), used alongside its prefixed forms and the degree Celsius. It is named after the Belfast-born and University of Glasgow-based engineer and phy ...

Planckian form

Derivation

The Planckian form is realized by the following substitution:

\lambda _x = A + \frac

Making this substitution renders the following the Sakuma–Hattori equation in the Planckian form. ; Sakuma–Hattori equation (Planckian form) :

S(T) = \frac

; Inverse equation :

T = \frac - \frac

; First derivative ''ASTM Standard E2758-10 – Standard Guide for Selection and Use of Wideband, Low Temperature Infrared Thermometers'', ASTM International, West Conshohocken, PA, (2010). :

2 \frac\exp\left(\frac\right)

Discussion

The Planckian form is recommended for use in calculating uncertainty budgets for radiation thermometry and infrared thermometry.
MSL Technical Guide 22 – Calibration of Low Temperature Infrared Thermometers
' (pdf), Measurement Standards Laboratory of New Zealand (2008). It is also recommended for use in calibration of radiation thermometers below the silver point. The Planckian form resembles Planck's law.

S(T) = \frac

However the Sakuma–Hattori equation becomes very useful when considering low-temperature, wide-band radiation thermometry. To use Planck's law over a wide spectral band, an

integral In mathematics, an integral assigns numbers to functions in a way that describes displacement, area, volume, and other concepts that arise by combining infinitesimal data. The process of finding integrals is called integration. Along wit ...

like the following would have to be considered:

S(T) = \int_^\frac d\lambda

This integral yields an

incomplete polylogarithm In mathematics, the Incomplete Polylogarithm function is related to the polylogarithm function. It is sometimes known as the incomplete Fermi–Dirac integral or the incomplete Bose–Einstein integral. It may be defined by: : \operatorname_s(b,z ...

function, which can make its use very cumbersome. The standard numerical treatment expands the incomplete integral in a geometric series of the exponential

\int_0^ \frac d\lambda
=c_1 \left(\frac\right)^4\int_^ \frac dx

after substituting

\lambda = c_2/(xT)

d\lambda = -c_2/\left(x^2T
\right)dx

. Then

\begin
J(c)&\equiv \int_c^\infty \fracdx
=\int_c^\infty \fracdx \\
&=\int_c^\infty \sum_x^3 \exp(-nx) dx
\\
&=\sum_ \exp(-nc)\frac
\end

provides an approximation if the sum is truncated at some order. The Sakuma–Hattori equation shown above was found to provide the best curve-fit for interpolation of scales for radiation thermometers among a number of alternatives investigated.Sakuma F, Kobayashi M., "Interpolation equations of scales of radiation thermometers", ''Proceedings of TEMPMEKO 1996'', pp. 305–310 (1996). The inverse Sakuma–Hattori function can be used without iterative calculation. This is an additional advantage over integration of Planck's law.

Other forms

The 1996 paper investigated 10 different forms. They are listed in the chart below in order of quality of curve-fit to actual radiometric data.

Notes

References

{{DEFAULTSORT:Sakuma-Hattori equation Statistical mechanics Equations 1982 in science