Notice: In general it is not advisable to use the Auto Aperture feature when making Top Hat measurements.

6.18.1Top Hat Mean and Standard Deviation

The computation of the Mean and Standard Deviation are described in the equations below: for the Mean,

Z = nZ

Where:

Z= Mean intensity

n= Number of summed pixels

Σ Z =

Sum of the pixel intensities above the clip level,

 

or in the area, or on the line being evaluated.

for the Deviation,

 

 

 

 

 

(Z

 

)2

σ =

Z

n − 1

 

Where:

σ= std. deviation.

n= Number of pixels summed.

Σ(Z - Z )² = Sum of the square of the differences between the mean intensity and the pixel intensity values

above the clip level, or in the area, or on the line being evaluated.

6.18.2Top Hat Minimum and Maximum intensities

The values appearing here represent the highest and lowest energy intensities that are found within the Top Hat area, as defined by the Data, Area or Line Aperture selection.

Note: In Data mode, the Minimum will often be the clip level value determined by the Beam Width Method.

6.19 Top Hat Factor

The Top Hat Factor provides a numerical measure of quality for a Top Hat beam profile. It is a normalized value that compares your beam profile against a perfect Top Hat--a perfect Top Hat being a beam with vertical sides and an absolutely uniform intensity on the top. A Factor value of 1.0 describes a perfect Top Hat.

Examining a plot of a beam’s energy fraction versus its normalized fluence derives the Top Hat Factor. The energy fraction is defined as the fraction of total energy above a particular fluence value. See figure below. If we calculate the area under the energy fraction curve, we will have a single normalized

Operator’s Manual

139

LBA-PC

Doc. No. 10654-001, Rev 4.10

 

 

Page 139
Image 139
Sigma LBA-712, LBA-710 manual Top Hat Factor, Top Hat Mean and Standard Deviation, Top Hat Minimum and Maximum intensities