Copyright | (c) Matthew Peddie 2015 |
---|---|
License | GPL |
Maintainer | Alberto Ruiz |
Stability | provisional |
Safe Haskell | None |
Language | Haskell98 |
Interpolation routines.
https://www.gnu.org/software/gsl/manual/html_node/Interpolation.html#Interpolation
The GSL routines gsl_spline_eval
and friends are used, but in spite
of the names, they are not restricted to spline interpolation. The
functions in this module will work for any InterpolationMethod
.
- data InterpolationMethod
- evaluate :: InterpolationMethod -> [(Double, Double)] -> Double -> Double
- evaluateV :: InterpolationMethod -> Vector Double -> Vector Double -> Double -> Double
- evaluateDerivative :: InterpolationMethod -> [(Double, Double)] -> Double -> Double
- evaluateDerivative2 :: InterpolationMethod -> [(Double, Double)] -> Double -> Double
- evaluateDerivativeV :: InterpolationMethod -> Vector Double -> Vector Double -> Double -> Double
- evaluateDerivative2V :: InterpolationMethod -> Vector Double -> Vector Double -> Double -> Double
- evaluateIntegral :: InterpolationMethod -> [(Double, Double)] -> (Double, Double) -> Double
- evaluateIntegralV :: InterpolationMethod -> Vector Double -> Vector Double -> Double -> Double -> Double
Interpolation methods
data InterpolationMethod Source #
Evaluation of interpolated functions
:: InterpolationMethod | What method to use to interpolate |
-> [(Double, Double)] | (domain, range) values sampling the function |
-> Double | Point at which to evaluate the function |
-> Double | Interpolated result |
Evaluate a function by interpolating within the given dataset. For example:
>>>
let xs = [1..10]
>>>
let ys map (**2) [1..10]
>>>
evaluate Akima (zip xs ys) 2.2
4.840000000000001
To successfully evaluate points x
, the domain (x
) values in
points
must be monotonically increasing. The evaluation point x
must lie between the smallest and largest values in the sampled
domain.
:: InterpolationMethod | What method to use to interpolate |
-> Vector Double | Data points sampling the domain of the function |
-> Vector Double | Data points sampling the range of the function |
-> Double | Point at which to evaluate the function |
-> Double | Interpolated result |
Evaluate a function by interpolating within the given dataset. For example:
>>>
let xs = vector [1..10]
>>>
let ys = vector $ map (**2) [1..10]
>>>
evaluateV CSpline xs ys 2.2
4.818867924528303
To successfully evaluateV xs ys x
, the vectors of corresponding
domain-range values xs
and ys
must have identical lengths, and
xs
must be monotonically increasing. The evaluation point x
must
lie between the smallest and largest values in xs
.
Evaluation of derivatives of interpolated functions
:: InterpolationMethod | What method to use to interpolate |
-> [(Double, Double)] | (domain, range) points sampling the function |
-> Double | Point |
-> Double | Interpolated result |
Evaluate the derivative of a function by interpolating within the given dataset. For example:
>>>
let xs = [1..10]
>>>
let ys map (**2) [1..10]
>>>
evaluateDerivative Akima (zip xs ys) 2.2
4.4
To successfully evaluateDerivative points x
, the domain (x
) values
in points
must be monotonically increasing. The evaluation point
x
must lie between the smallest and largest values in the sampled
domain.
:: InterpolationMethod | What method to use to interpolate |
-> [(Double, Double)] | (domain, range) points sampling the function |
-> Double | Point |
-> Double | Interpolated result |
Evaluate the second derivative of a function by interpolating within the given dataset. For example:
>>>
let xs = [1..10]
>>>
let ys map (**2) [1..10]
>>>
evaluateDerivative2 Akima (zip xs ys) 2.2
2.0
To successfully evaluateDerivative2 points x
, the domain (x
)
values in points
must be monotonically increasing. The evaluation
point x
must lie between the smallest and largest values in the
sampled domain.
:: InterpolationMethod | What method to use to interpolate |
-> Vector Double | Data points |
-> Vector Double | Data points |
-> Double | Point |
-> Double | Interpolated result |
Evaluate the derivative of a function by interpolating within the given dataset. For example:
>>>
let xs = vector [1..10]
>>>
let ys = vector $ map (**2) [1..10]
>>>
evaluateDerivativeV CSpline xs ys 2.2
4.338867924528302
To successfully evaluateDerivativeV xs ys x
, the vectors of
corresponding domain-range values xs
and ys
must have identical
lengths, and xs
must be monotonically increasing. The interpolation
point x
must lie between the smallest and largest values in xs
.
:: InterpolationMethod | What method to use to interpolate |
-> Vector Double | Data points |
-> Vector Double | Data points |
-> Double | Point |
-> Double | Interpolated result |
Evaluate the second derivative of a function by interpolating within the given dataset. For example:
>>>
let xs = vector [1..10]
>>>
let ys = vector $ map (**2) [1..10]
>>>
evaluateDerivative2V CSpline xs ys 2.2
2.4
To successfully evaluateDerivative2V xs ys x
, the vectors xs
and
ys
must have identical lengths, and xs
must be monotonically
increasing. The evaluation point x
must lie between the smallest
and largest values in xs
.
Evaluation of integrals of interpolated functions
:: InterpolationMethod | What method to use to interpolate |
-> [(Double, Double)] | (domain, range) points sampling the function |
-> (Double, Double) | Integration bounds ( |
-> Double | Resulting area |
Evaluate the definite integral of a function by interpolating within the given dataset. For example:
>>>
let xs = [1..10]
>>>
let ys = map (**2) [1..10]
>>>
evaluateIntegralV CSpline (zip xs ys) (2.2, 5.5)
51.909
To successfully evaluateIntegral points (a, b)
, the domain (x
)
values of points
must be monotonically increasing. The integration
bounds a
and b
must lie between the smallest and largest values in
the sampled domain..
:: InterpolationMethod | What method to use to interpolate |
-> Vector Double | Data points |
-> Vector Double | Data points |
-> Double | Lower integration bound |
-> Double | Upper integration bound |
-> Double | Resulting area |
Evaluate the definite integral of a function by interpolating within the given dataset. For example:
>>>
let xs = vector [1..10]
>>>
let ys = vector $ map (**2) [1..10]
>>>
evaluateIntegralV CSpline xs ys 2.2 5.5
51.89853207547169
To successfully evaluateIntegralV xs ys a b
, the vectors xs
and
ys
must have identical lengths, and xs
must be monotonically
increasing. The integration bounds a
and b
must lie between the
smallest and largest values in xs
.