Difference between revisions of "RegressionFitProb"
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| − | = RegressionFitProb(Y,B,I,K'',C'') = | + | == RegressionFitProb(Y, B,I, K'', C'') == |
| − | Once you've obtained regression coefficients | + | Once you've obtained regression coefficients «C» (indexed by «K») by calling the [[Regression]] function, this function returns the probability that a fit this poor would occur by chance, given the assumption that the data was generated by a process of the form: |
| − | + | :<code>Y = Sum( C*B, K) + Normal(0, S)</code> | |
If this result is very close to zero, it probably indicates that the assumption of linearity is bad. If it is very close to one, then it validates the assumption of linearity. | If this result is very close to zero, it probably indicates that the assumption of linearity is bad. If it is very close to one, then it validates the assumption of linearity. | ||
| − | = Library = | + | == Library == |
Multivariate Distributions.ana | Multivariate Distributions.ana | ||
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This is not a distribution function - it does not return a sample when evaluated in [[Evaluation Modes|Sample mode]]. However, it does complement the multivariate [[RegressionDist]] function also included in this library. | This is not a distribution function - it does not return a sample when evaluated in [[Evaluation Modes|Sample mode]]. However, it does complement the multivariate [[RegressionDist]] function also included in this library. | ||
| − | = Example = | + | == Example == |
| − | To use, first call the Regression function, then you must either know the measurement knows a priori, or obtain it using the RegressionNoise function. | + | To use, first call the Regression function, then you must either know the measurement knows a priori, or obtain it using the [[RegressionNoise]] function. |
| − | + | :<code>Var E_C := Regression(Y, B, I, K);</code> | |
| − | + | :<code>Var S := RegressionNoise(Y, B, I, K, C);</code> | |
| − | + | :<code>Var PrThisPoor := RegressionFitProb(Y, B, I, K, E_C, S)</code> | |
| − | = See Also = | + | == See Also == |
* [[RegressionDist]] | * [[RegressionDist]] | ||
* [[RegressionNoise]] | * [[RegressionNoise]] | ||
* [[Regression]] | * [[Regression]] | ||
Revision as of 00:32, 14 January 2016
RegressionFitProb(Y, B,I, K, C)
Once you've obtained regression coefficients «C» (indexed by «K») by calling the Regression function, this function returns the probability that a fit this poor would occur by chance, given the assumption that the data was generated by a process of the form:
Y = Sum( C*B, K) + Normal(0, S)
If this result is very close to zero, it probably indicates that the assumption of linearity is bad. If it is very close to one, then it validates the assumption of linearity.
Library
Multivariate Distributions.ana
This is not a distribution function - it does not return a sample when evaluated in Sample mode. However, it does complement the multivariate RegressionDist function also included in this library.
Example
To use, first call the Regression function, then you must either know the measurement knows a priori, or obtain it using the RegressionNoise function.
Var E_C := Regression(Y, B, I, K);Var S := RegressionNoise(Y, B, I, K, C);Var PrThisPoor := RegressionFitProb(Y, B, I, K, E_C, S)
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