User:The Lamb of God/sandbox-Signal Transfer Function (SiTF)

The Signal transfer function (SiTF) is a measure of the signal output versus the signal input of an infrared system or sensor.

Evaluation

In evaluating the SiTF curve, the signal input and signal output are measured differentially; meaning, the differential of the input signal and differential of the output signal are calculated and plotted against eachother. An operator, using computer software, defines an arbitrary area, with a given set of data points, within the signal and backround regions of the output image of the infrared sensor, i.e. of the (Unit Under Test), (see Half Moon image below). The average signal and backround are calculated by averaging the data of each arbitrarily defined region. A second order polynomial curve is fitted to the data of each line. Then, the polynomial is subtracted from the average signal and backround data to yield the new signal and backround. The difference of the new signal and backround data is taken to yield the net signal. Finally, the net signal is plotted versus the signal input. The signal input of the UUT is within its own spectral response. (e.g. Color Correlated Temperature, Pixel intensity, etc.). The slope of the linear portion of this curve is then found using the method of least squares.^[1]

SiTf Calculations

Half moon target. On the left the image of the backround region and on the right an image of the signal region. Using specialized software, an operator arbitrarily defines an area of evaluation in both regions to be used in determining the signal transfer function.

The average signal and backround are calculated by the following equations:

${\displaystyle \mu \,Sig_{ave}={\frac {\sum _{i=o}^{n}X_{i}}{n}}\qquad \qquad \mu \,Backround_{ave}={\frac {\sum _{i=0}^{p}Y_{i}}{p}}}$

• • Where ${\displaystyle n\,}$ = the number of lines in the target area ${\displaystyle X\,}$ or ${\displaystyle Y\,}$
  • ${\displaystyle p\,}$ = the horizontal pixel resolution in the target area ${\displaystyle X\,}$ or ${\displaystyle Y\,}$
  • ${\displaystyle i\,}$ = the ${\displaystyle i\,}$^th line or horizontal pixel resolution in the target area ${\displaystyle X\,}$ or ${\displaystyle Y\,}$
  • ${\displaystyle X\,}$ = an arbitrarily defined area in the illuminated portion of the image (Signal region).
  • ${\displaystyle Y\,}$ = an arbitrarily defined area in the non-illuminated portion of the image (Backround region).

A second order polynomial is calculated using a double summation: ${\displaystyle f(X)_{i}=\sum _{j=0}^{m}\sum _{i=0}^{n}a_{j}X_{i}^{j}\qquad \qquad f(Y)_{i}=\sum _{j=0}^{m}\sum _{i=0}^{n}a_{j}Y_{i}^{j}}$

• • ${\displaystyle f\,}$ = the output sequence best fit
  • ${\displaystyle X\,}$ = the input sequence (Signal Region)
  • ${\displaystyle Y\,}$ = the input sequence (Backround Region)
  • ${\displaystyle a\,}$ = the polynomial fit coefficient
  • ${\displaystyle m\,}$ = the polynomial order

The second order polynomial is subtracted from the original data and the mean is taken:

${\displaystyle \mu \,Sig=\mu \,Sig_{ave}-f(X)_{i}\qquad \qquad \mu \,Backround=\mu \,Backround_{ave}-f(Y)_{i}}$

The red line is the SiTF.. As can be seen an line is fitted to the linear slope of the signal output versus signal input of an infrared sensor.

Then, the net signal is calculated:

${\displaystyle Signal=\mu \,Sig-\mu \,Backround}$

SiTF curve

The SiTF curve is then given by the signal ouput data, (net signal data), plotted against the signal input data (see graph of SiTF to the right). All the data points in the linear region of the SiTF curve are used in the method of least squares to approximate a line.

Least squares fit calculation

Given ${\displaystyle n\,}$ data points ${\displaystyle (x_{i}\,,y_{i}\,)}$ a best fit line can be approximated by ${\displaystyle y=mx+b\,}$^[2]

${\displaystyle {\begin{bmatrix}1&x_{1}\\1&x_{2}\\\vdots &\vdots \\1&x_{n}\end{bmatrix}}{\begin{bmatrix}b\\m\end{bmatrix}}={\begin{bmatrix}y_{1}\\y_{2}\\\vdots \\y_{n}\end{bmatrix}}}$

Which can be rewritten:

${\displaystyle {\begin{bmatrix}n&\sum x_{i}\\\sum x_{i}&\sum x_{i}^{2}\end{bmatrix}}{\begin{bmatrix}b\\m\end{bmatrix}}={\begin{bmatrix}\sum y_{i}\\\sum x_{i}y_{i}\end{bmatrix}}}$

Augmenting the matrix and performing simple row operations yields:

${\displaystyle {\begin{bmatrix}1&{\frac {\sum x_{i}}{n}}&{\frac {\sum y_{i}}{n}}\\{\frac {\sum x_{i}}{n}}&{\frac {\sum x_{i}^{2}}{n}}&{\frac {\sum x_{i}y_{i}}{n}}\end{bmatrix}}}$

Therefore:

${\displaystyle m={\frac {{\frac {\sum x_{i}y_{i}}{n}}-{\frac {\sum x_{i}}{n}}{\frac {\sum y_{i}}{n}}}{{\frac {\sum x_{i}^{2}}{n}}-({\frac {\sum x_{i}}{n}})^{2}}}\qquad \qquad b={\frac {\sum y_{i}}{n}}-m{\frac {\sum x_{i}}{n}}}$

See also

• • Modulation Transfer Function
  • Optical Transfer Function
  • Signal to Noise Ratio
  • Distortion
  • Minimum Resolvable Temperature Difference
  • Noise Equivalent Temperature Difference
  • Noise Power Spectral Density
  • Minimum Resolvable Contrast

References

1. Electro Optical Industries, Inc.(2005). EO TestLab Methadology. In Education/Ref. http://www.electro-optical.com/html/toplevel/educationref.asp.
2. Aboufadel, E.F., Goldberg, J.L., Potter, M.C. (2005).Advanced Engineering Mathematics (3rd ed.).New York, New York: Oxford University Press

External Links

http://www.electro-optical.com/html/