DataInterpolations.jl is a library for performing interpolations of one-dimensional data. By "data interpolations" we mean techniques for interpolating possibly noisy data, and thus some methods are mixtures of regressions with interpolations (i.e. do not hit the data points exactly, smoothing out the lines). This library can be used to fill in intermediate data points in applications like timeseries data.
All interpolation objects act as functions. Thus for example, using an interpolation looks like:
u = rand(5)
t = 0:4
interp = LinearInterpolation(u, t)
interp(3.5) # Gives the linear interpolation value at t=3.5
We can efficiently interpolate onto a vector of new t
values:
t′ = 0.5:1.0:3.5
interp(t′)
In-place interpolation also works:
u′ = similar(u, length(t′))
interp(u′, t′)
In all cases, u
an AbstractVector
of values and t
is an AbstractVector
of timepoints
corresponding to (u,t)
pairs.
-
ConstantInterpolation(u,t)
- A piecewise constant interpolation. -
LinearInterpolation(u,t)
- A linear interpolation. -
QuadraticInterpolation(u,t)
- A quadratic interpolation. -
LagrangeInterpolation(u,t,n)
- A Lagrange interpolation of ordern
. -
QuadraticSpline(u,t)
- A quadratic spline interpolation. -
CubicSpline(u,t)
- A cubic spline interpolation. -
AkimaInterpolation(u, t)
- Akima spline interpolation provides a smoothing effect and is computationally efficient. -
BSplineInterpolation(u,t,d,pVec,knotVec)
- An interpolation B-spline. This is a B-spline which hits each of the data points. The argument choices are:d
- degree of B-splinepVec
- Symbol to Parameters Vector,pVec = :Uniform
for uniform spaced parameters andpVec = :ArcLen
for parameters generated by chord length method.knotVec
- Symbol to Knot Vector,knotVec = :Uniform
for uniform knot vector,knotVec = :Average
for average spaced knot vector.
-
BSplineApprox(u,t,d,h,pVec,knotVec)
- A regression B-spline which smooths the fitting curve. The argument choices are the same as theBSplineInterpolation
, with the additional parameterh<length(t)
which is the number of control points to use, with smallerh
indicating more smoothing. -
CubicHermiteSpline(du, u, t)
- A third order Hermite interpolation, which matches the values and first (du
) order derivatives in the data points exactly. -
PCHIPInterpolation(u, t)
- a type ofCubicHermiteSpline
where the derivative valuesdu
are derived from the input data in such a way that the interpolation never overshoots the data. -
QuinticHermiteSpline(ddu, du, u, t)
- A fifth order Hermite interpolation, which matches the values and first (du
) and second (ddu
) order derivatives in the data points exactly.
The follow methods require extra dependencies and will be loaded as package extensions.
Curvefit(u,t,m,p,alg)
- An interpolation which is done by fitting a user-given functional formm(t,p)
wherep
is the vector of parameters. The user's inputp
is a an initial value for a least-square fitting,alg
is the algorithm choice to use for optimize the cost function (sum of squared deviations) viaOptim.jl
and optimalp
s are used in the interpolation. Requiresusing Optim
.RegularizationSmooth(u,t,d;λ,alg)
- A regularization algorithm (ridge regression) which is done by minimizing an objective function (l2 loss + derivatives of orderd
) integrated in the time span. It is a global method and creates a smooth curve. Requiresusing RegularizationTools
.
DataInterpolations.jl is tied into the Plots.jl ecosystem, by way of RecipesBase.
Any interpolation can be plotted using the plot
command (or any other), since they have type recipes associated with them.
For convenience, and to allow keyword arguments to propagate properly, DataInterpolations.jl also defines several series types, corresponding to different interpolations.
The series types defined are:
:linear_interp
:quadratic_interp
:lagrange_interp
:quadratic_spline
:cubic_spline
:akima_interp
:bspline_interp
:bspline_approx
:cubic_hermite_spline
:pchip_interp
:quintic_hermite_spline
By and large, these accept the same keywords as their function counterparts.
If you use this software in your work, please cite:
@article{Bhagavan2024,
doi = {10.21105/joss.06917},
url = {https://doi.org/10.21105/joss.06917},
year = {2024},
publisher = {The Open Journal},
volume = {9},
number = {101},
pages = {6917},
author = {Sathvik Bhagavan and Bart de Koning and Shubham Maddhashiya and Christopher Rackauckas},
title = {DataInterpolations.jl: Fast Interpolations of 1D data},
journal = {Journal of Open Source Software}
}