FLIR A3 SERIES Installation Manual page 85

or, with simplified notation:
where C is a constant.
Should the source be a graybody with emittance ε, the received radiation would
consequently be εW
We are now ready to write the three collected radiation power terms:
1 – Emission from the object = ετW
is the transmittance of the atmosphere. The object temperature is T
2 – Reflected emission from ambient sources = (1 – ε)τW
flectance of the object. The ambient sources have the temperature T
It has here been assumed that the temperature T
within the halfsphere seen from a point on the object surface. This is of course
sometimes a simplification of the true situation. It is, however, a necessary simplification
in order to derive a workable formula, and T
a value that represents an efficient temperature of a complex surrounding.
Note also that we have assumed that the emittance for the surroundings = 1. This is
correct in accordance with Kirchhoff's law: All radiation impinging on the surrounding
surfaces will eventually be absorbed by the same surfaces. Thus the emittance = 1.
(Note though that the latest discussion requires the complete sphere around the object
to be considered.)
3 – Emission from the atmosphere = (1 – τ)τW
the atmosphere. The temperature of the atmosphere is T
The total received radiation power can now be written (Equation 2):
We multiply each term by the constant C of Equation 1 and replace the CW products
by the corresponding U according to the same equation, and get (Equation 3):
Solve Equation 3 for U
Publ. No. T559498 Rev. a461 – ENGLISH (EN) – August 19, 2010
.
source
obj
(Equation 4):
obj
, where ε is the emittance of the object and τ
is the same for all emitting surfaces
refl
can – at least theoretically – be given
refl
, where (1 – τ) is the emittance of
atm
22 – The measurement formula
.
obj
, where (1 – ε) is the re-
refl
.
refl
.
atm
79