Utilisateur:Benji547/Bspline

In the mathematical subfield of numerical analysis, a B-spline is a spline function that has minimal support with respect to a given degree, smoothness, and domain partition. A fundamental theorem states that every spline function of a given degree, smoothness, and domain partition, can be represented as a linear combination of B-splines of that same degree and smoothness, and over that same partition.^[1] The term B-spline was coined by Isaac Jacob Schoenberg and is short for basis spline.^[2] B-splines can be evaluated in a numerically stable way by the de Boor algorithm. Simplified, potentially faster variants of the de Boor algorithm have been created but they suffer from comparatively lower stability.^[3][4]

In the computer science subfields of computer-aided design and computer graphics the term B-spline frequently refers to a spline curve parametrized by spline functions that are expressed as linear combinations of B-splines (in the mathematical sense above). A B-spline is simply a generalisation of a Bézier curve, and it can avoid the Runge phenomenon without increasing the degree of the B-spline.

Definition

Given m real valued t_i, called knots, with

${\displaystyle t_{0}\leq t_{1}\leq \cdots \leq t_{m-1}}$ 

a B-spline of degree n is a parametric curve

${\displaystyle \mathbf {S} :[t_{0},t_{m-1}]\to \mathbb {R} ^{2}}$ 

composed of a linear combination of basis B-splines b_i,n of degree n

${\displaystyle \mathbf {S} (t)=\sum _{i=0}^{m-n}\mathbf {P} _{i}b_{i,n}(t){\mbox{ , }}t\in [t_{n-1},t_{m-n}]}$ .

The P_i are called control points or de Boor points. There are m−n+1 control points and they form a convex hull.

The m-n+1 basis B-splines of degree n can be defined using the Cox-de Boor recursion formula

${\displaystyle b_{j,0}(t):=\left\{{\begin{matrix}1&\mathrm {if} \quad t_{j}\leq t<t_{j+1}\\0&\mathrm {otherwise} \end{matrix}}\right.}$ 

${\displaystyle b_{j,n}(t):={\frac {t-t_{j}}{t_{j+n}-t_{j}}}b_{j,n-1}(t)+{\frac {t_{j+n+1}-t}{t_{j+n+1}-t_{j+1}}}b_{j+1,n-1}(t).}$ 

When the knots are equidistant the B-spline is said to be uniform, otherwise non-uniform. If two knots t_j are identical, any resulting indeterminate forms 0/0 are deemed to be 0.

Note that j+n+1 can not exceed m-1, which limits both j and n.

Uniform B-spline

When the B-spline is uniform, the basis B-splines for a given degree n are just shifted copies of each other. An alternative non-recursive definition for the m−n+1 basis B-splines is

${\displaystyle b_{j,n}(t)=b_{n}(t-t_{j}),\qquad \;j=0,\ldots ,m-n-1}$ 

with

${\displaystyle b_{n}(t):={\frac {n+1}{n}}\sum _{i=0}^{n+1}\omega _{i,n}(t-t_{i})_{+}^{n}\,\;}$ 

and

${\displaystyle \omega _{i,n}:=\prod _{j=0,j\neq i}^{n+1}{\frac {1}{t_{j}-t_{i}}}\,\;}$ 

where

${\displaystyle (t-t_{i})_{+}^{n}\,\;}$ 

is the truncated power function.

Cardinal B-spline

Define B₀ as the characteristic function of ${\displaystyle [-{\tfrac {1}{2}},{\tfrac {1}{2}}]}$ , and B_k recursively as the convolution product

${\displaystyle B_{k}:=B_{k-1}*B_{0},~k=1,2,\dots }$ 

then B_k are called (centered) cardinal B-splines. This definition goes back to Schoenberg.

B_k has compact support ${\displaystyle [-{\tfrac {k+1}{2}},{\tfrac {k+1}{2}}]}$  and is an even function. As ${\displaystyle k\rightarrow \infty }$  the normalized cardinal B-splines tend to the Gaussian function.^[5]

Notes

When the number of de Boor control points is the same as the degree, the B-Spline degenerates into a Bézier curve. The shape of the basis functions is determined by the position of the knots. Scaling or translating the knot vector does not alter the basis functions.

The spline is contained in the convex hull of its control points.

A basis B-spline of degree n

${\displaystyle b_{i,n}(t)\,\;}$ 

is non-zero only in the interval [t_i, t_i+n+1] that is

${\displaystyle b_{i,n}(t)=\left\{{\begin{matrix}>0&\mathrm {if} \quad t_{i}\leq t<t_{i+n+1}\\0&\mathrm {otherwise} \end{matrix}}\right.}$ 

In other words if we manipulate one control point we only change the local behaviour of the curve and not the global behaviour as with Bézier curves.

The basis function can be derived from the Bernstein polynomial.

Examples

Constant B-spline

The constant B-spline is the simplest spline. It is defined on only one knot span and is not even continuous on the knots. It is just the indicator function for the different knot spans.

${\displaystyle b_{j,0}(t)=1_{[t_{j},t_{j+1})}=\left\{{\begin{matrix}1&\mathrm {if} \quad t_{j}\leq t<t_{j+1}\\0&\mathrm {otherwise} \end{matrix}}\right.}$ 

Linear B-spline

The linear B-spline is defined on two consecutive knot spans and is continuous on the knots, but not differentiable.

${\displaystyle b_{j,1}(t)=\left\{{\begin{matrix}{\frac {t-t_{j}}{t_{j+1}-t_{j}}}&\mathrm {if} \quad t_{j}\leq t<t_{j+1}\\{\frac {t_{j+2}-t}{t_{j+2}-t_{j+1}}}&\mathrm {if} \quad t_{j+1}\leq t<t_{j+2}\\0&\mathrm {otherwise} \end{matrix}}\right.}$ 

Uniform quadratic B-spline

Quadratic B-splines with uniform knot-vector is a commonly used form of B-spline. The blending function can easily be precalculated, and is equal for each segment in this case.

${\displaystyle b_{j,2}(t)={\begin{cases}{\frac {1}{2}}t^{2}\\-t^{2}+t+{\frac {1}{2}}\\{\frac {1}{2}}(1-t)^{2}\end{cases}}}$ 

Put in matrix-form, it is:[1]

${\displaystyle \mathbf {S} _{i}(t)={\begin{bmatrix}t^{2}&t&1\end{bmatrix}}{\frac {1}{2}}{\begin{bmatrix}1&-2&1\\-2&2&0\\1&1&0\end{bmatrix}}{\begin{bmatrix}\mathbf {p} _{i-1}\\\mathbf {p} _{i}\\\mathbf {p} _{i+1}\end{bmatrix}}}$  for ${\displaystyle t\in [0,1],i=1,2\ldots m-1}$ 

Cubic B-Spline

A B-spline formulation for a single segment can be written as:

${\displaystyle \mathbf {S} _{i}(t)=\sum _{k=0}^{3}\mathbf {P} _{i-3+k}b_{i-3+k,3}(t){\mbox{ ; }}\ t\in [0,1]}$ 

where S_i is the ith B-spline segment and P is the set of control points, segment i and k is the local control point index. A set of control points would be ${\displaystyle P_{i}^{w}=(w_{i}x_{i},w_{i}y_{i},w_{i}z_{i},w_{i})}$  where the ${\displaystyle w_{i}}$  is weight, pulling the curve towards control point ${\displaystyle P_{i}}$  as it increases or moving the curve away as it decreases.

An entire set of segments, m-2 curves (${\displaystyle S_{3},S_{4},...,S_{m}}$ ) defined by m+1 control points (${\displaystyle P_{0},P_{1},...,P_{m},m\geq 3}$ ), as one B-spline in t would be defined as:

${\displaystyle \mathbf {S} (t)=\sum _{i=0}^{m-1}\mathbf {P} _{i}b_{i,3}(t)}$ 

where i is the control point number and t is a global parameter giving knot values. This formulation expresses a B-spline curve as a linear combination of B-spline basis functions, hence the name.

There are two types of B-spline - uniform and non-uniform. A non-uniform B-spline is a curve where the intervals between successive control points is not, or not necessarily, equal (the knot vector of interior knot spans are not equal). A common form is where intervals are successively reduced to zero, interpolating control points.

Uniform cubic B-splines

Cubic B-splines with uniform knot-vector is the most commonly used form of B-spline. The blending function can easily be precalculated, and is equal for each segment in this case. Put in matrix-form, it is:

${\displaystyle \mathbf {S} _{i}(t)={\begin{bmatrix}t^{3}&t^{2}&t&1\end{bmatrix}}{\frac {1}{6}}{\begin{bmatrix}-1&3&-3&1\\3&-6&3&0\\-3&0&3&0\\1&4&1&0\end{bmatrix}}{\begin{bmatrix}\mathbf {p} _{i-1}\\\mathbf {p} _{i}\\\mathbf {p} _{i+1}\\\mathbf {p} _{i+2}\end{bmatrix}}}$  for ${\displaystyle t\in [0,1].}$ 

See also

• Spline (mathematics)
• Nonuniform rational B-splines (NURBS)
• De Boor algorithm
• M-spline
• I-spline

References

1. (en) Carl de Boor, A Practical Guide to Splines, Springer-Verlag, 1978, 113–114 p.
2. (en) Carl de Boor, A Practical Guide to Splines, Springer-Verlag, 1978, 114–115 p.
3. E. T. Y. Lee, « A Simplified B-Spline Computation Routine », Computing, Springer-Verlag, vol. 29, n^o 4,‎ décembre 1982, p. 365-371 (DOI 10.1007/BF02246763)
4. Lee, E. T. Y., « Comments on some B-spline algorithms », Computing, Springer-Verlag, vol. 36, n^o 3,‎ 1986, p. 229-238 (DOI 10.1007/BF02240069)
5. Brinks R: On the convergence of derivatives of B-splines to derivatives of the Gaussian function, Comp. Appl. Math., 27, 1, 2008

External links

• Interactive java applets for B-splines
• B-spline on MathWorld
• Module B-Splines by John H. Mathews
• B-splines of third order on a non-uniform grid by Johannes Ruf
• FORTRAN code for interpolation using B-splines

Catégorie:Spline Catégorie:Interpolation numérique