Difference between revisions of "Extreme Spread"

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(Experimental Summary)
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== Outlier Tests ==
 
== Outlier Tests ==
  
= Theoretical <math>h_{Range}</math> or <math>v_{Range}</math> Distributions =
+
= Theoretical <math>FOM</math> Distribution =
  
= Theoretical <math>FOM</math> Distribution =
+
Assuming that the shots are Rayleigh distributed allows us to make some theoretical estimates. 
yada yada
 
  
 
{| class="wikitable"  
 
{| class="wikitable"  
|+ Theoretical <math>FOM</math> Distribution
+
|+ Theoretical <math>ES</math> Distribution
 
|-
 
|-
 
| Parameters Needed
 
| Parameters Needed
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|-
 
|-
 
| <math>PDF(r; \sigma)</math>
 
| <math>PDF(r; \sigma)</math>
|  
+
| no direct evaluation, must be simulated via Monte Carlo
 
|-
 
|-
 
| <math>CDF(r; \sigma)</math>
 
| <math>CDF(r; \sigma)</math>
|  
+
| no direct evaluation, must be simulated via Monte Carlo
 
|-
 
|-
 
| Mode of PDF)
 
| Mode of PDF)
|  
+
| depends on <math>n</math>, in general
 
|-
 
|-
 
| Median of PDF
 
| Median of PDF
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|-
 
|-
 
| Variance
 
| Variance
|  
+
| no direct evaluation, must be simulated via Monte Carlo
 
|-
 
|-
 
| Variance Distribution
 
| Variance Distribution

Revision as of 19:09, 5 June 2015

Experimental Summary

Given
  • set of n shots {\( (h_1, v_1), (h_2, v_2), ..., (h_n, v_n) \)}

All of the (h,v) positions do not need to be known so a ragged hole will suffice.

Assumptions
  • Ideally the shot would follow a Rayleigh Distribution
    • \(\bar{h} \sim \mathcal{N}(\bar{h},\sigma_h^2), \bar{v} \sim \mathcal{N}(\bar{v},\sigma_v^2)\)
    • Horizontal and vertical dispersion are independent.
    • \(\sigma_h = \sigma_v\) (realistically \(\sigma_h \approx \sigma_v\))
    • \(\rho = 0\)
    • \(PDF_{r_i}(r) = \frac{r}{\sigma^2}e^{-r^2/2\sigma^2}\)
Note: It is not necessary to fit \(\sigma\) to calculate the Figure of Merit.
  • No Fliers
Data transformation Identify two holes, \(i, j\) which are the farthest apart.
Experimental Measure \(ES = \sqrt{(x_i - x_j)^2 - (y_i - y_j)^2)}\),

Given

Assumptions

Data transformation

Experimental Measure

Outlier Tests

Theoretical \(FOM\) Distribution

Assuming that the shots are Rayleigh distributed allows us to make some theoretical estimates.

Theoretical \(ES\) Distribution
Parameters Needed
\(PDF(r; \sigma)\) no direct evaluation, must be simulated via Monte Carlo
\(CDF(r; \sigma)\) no direct evaluation, must be simulated via Monte Carlo
Mode of PDF) depends on \(n\), in general
Median of PDF
Mean of PDF
Variance no direct evaluation, must be simulated via Monte Carlo
Variance Distribution
(h,v) for all points? Yes
Symmetric about Mean? No, skewed to larger values.

More symmetric as number of shots increases.

Parameters Needed

Variance and Its distribution

PDF

CDF

Mode, Median, Mean

Outlier Tests

See Also

Dispersion Assumptions - A discussion of the different cases for shot dispersion

Diagonal - A different way of combing horizontal and vertical measurement

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