B3spline: Difference between revisions
Jump to navigation
Jump to search
imported>Jeremy (Importing text file) |
imported>Jeremy (Importing text file) |
||
| Line 9: | Line 9: | ||
yi = f(xi) for i=1,...,M. | yi = f(xi) for i=1,...,M. | ||
See (options.algorithm) for more information. | See (options.algorithm) for more information. | ||
INPUTS | ====INPUTS==== | ||
* x = Mx1 vector of independent variable values. | * '''x''' = Mx1 vector of independent variable values. | ||
* y = Mx1 vector of corresponding dependendent variable values. | * '''y''' = Mx1 vector of corresponding dependendent variable values. | ||
* t = defines the number of knots or knot positions. | * '''t''' = defines the number of knots or knot positions. | ||
* = 1x1 scalar integer defining the number of uniformly distributed INTERIOR knots. There will be t+2 knots positioned at: | * ''''''= 1x1 scalar integer defining the number of uniformly distributed INTERIOR knots. There will be t+2 knots positioned at: | ||
* modl.t = linspace(min(x),max(x),t+2)'; | * '''modl.t''' = linspace(min(x),max(x),t+2)'; | ||
* = Kx1 vector defining manually placed knot positions, | * ''''''= Kx1 vector defining manually placed knot positions, | ||
* where modl.t = sort(t); | * '''where''' modl.t = sort(t); | ||
* Note that knot positions need not be uniform, and that t(1) can be <min(x) and t(K) can be >max(x). | * '''Note''' that knot positions need not be uniform, and that t(1) can be <min(x) and t(K) can be >max(x). | ||
Note that knot positions must be such that there are at least 3 unique data points between each knot: tk,tk+1 for k=1,...,K. | Note that knot positions must be such that there are at least 3 unique data points between each knot: tk,tk+1 for k=1,...,K. | ||
OUTPUTS | ====OUTPUTS==== | ||
* modl = standard model structure containing the spline model (See MODELSTRUCT). | * '''modl''' = standard model structure containing the spline model (See MODELSTRUCT). | ||
* pred = structure array with predictions. | * '''pred''' = structure array with predictions. | ||
* valid = structure array with predictions. | * '''valid''' = structure array with predictions. | ||
===Options=== | ===Options=== | ||
* ''options'' = a structure array with the following fields: | * '''''options''''' = a structure array with the following fields: | ||
* display: [ {'on'} | 'off' ] level of display to command window. | * '''display''': [ {'on'} | 'off' ] level of display to command window. | ||
* plots: [ {'final'} | 'none' ] governs level of plotting. If 'final' and calibrating a model, the plot shows plot(xi,yi) and plot(xi,f(xi),'-') with knots. | * '''plots''': [ {'final'} | 'none' ] governs level of plotting. If 'final' and calibrating a model, the plot shows plot(xi,yi) and plot(xi,f(xi),'-') with knots. | ||
* algorithm: [ {'b3spline'} | 'b3_0' | 'b3_01' ] fitting algorithm | * '''algorithm''': [ {'b3spline'} | 'b3_0' | 'b3_01' ] fitting algorithm | ||
''' 'b3spline'''': fits quadradic polynomials f{k,k+1} to the data between knots tk, k=1,...,K, subject to: | |||
f{k,k+1}(tk+1) = f{k+1,k+2}(tk+1) and | |||
f'{k,k+1}(tk+1) = f'{k+1,k+2}(tk+1) for k=1,...,K-1. | |||
''''b3_0'''': is the same as 'b3spline' but also constrains the ends to 0: f{1,2}(t1) = 0 and f{K-1,K}(tK) = 0. | |||
''''b3_01':''' is 'b3_0' but also constrains the derivatives at the ends to 0: f'{1,2}(t1) = 0 and f'{K-1,K}(tK) = 0. | |||
* '''order''': positive integer for polynomial order {default = 1}. | |||
* order: positive integer for polynomial order {default = 1}. | |||
The default options can be retreived using: options = baseline('options');. | The default options can be retreived using: options = baseline('options');. | ||
===See Also=== | ===See Also=== | ||
Revision as of 19:55, 2 September 2008
Purpose
Univariate spline fit and prediction.
Synopsis
- modl = b3spline(x,y,t,options);
- pred = b3spline(x,modl,options);
- valid = b3spline(x,y,modl,options);
Description
Curve fitting using second order splines where yi = f(xi) for i=1,...,M. See (options.algorithm) for more information.
INPUTS
- x = Mx1 vector of independent variable values.
- y = Mx1 vector of corresponding dependendent variable values.
- t = defines the number of knots or knot positions.
- '= 1x1 scalar integer defining the number of uniformly distributed INTERIOR knots. There will be t+2 knots positioned at:
- modl.t = linspace(min(x),max(x),t+2)';
- '= Kx1 vector defining manually placed knot positions,
- where modl.t = sort(t);
- Note that knot positions need not be uniform, and that t(1) can be <min(x) and t(K) can be >max(x).
Note that knot positions must be such that there are at least 3 unique data points between each knot: tk,tk+1 for k=1,...,K.
OUTPUTS
- modl = standard model structure containing the spline model (See MODELSTRUCT).
- pred = structure array with predictions.
- valid = structure array with predictions.
Options
- options = a structure array with the following fields:
- display: [ {'on'} | 'off' ] level of display to command window.
- plots: [ {'final'} | 'none' ] governs level of plotting. If 'final' and calibrating a model, the plot shows plot(xi,yi) and plot(xi,f(xi),'-') with knots.
- algorithm: [ {'b3spline'} | 'b3_0' | 'b3_01' ] fitting algorithm
'b3spline': fits quadradic polynomials f{k,k+1} to the data between knots tk, k=1,...,K, subject to:
f{k,k+1}(tk+1) = f{k+1,k+2}(tk+1) and
f'{k,k+1}(tk+1) = f'{k+1,k+2}(tk+1) for k=1,...,K-1.
'b3_0': is the same as 'b3spline' but also constrains the ends to 0: f{1,2}(t1) = 0 and f{K-1,K}(tK) = 0. 'b3_01': is 'b3_0' but also constrains the derivatives at the ends to 0: f'{1,2}(t1) = 0 and f'{K-1,K}(tK) = 0.
- order: positive integer for polynomial order {default = 1}.
The default options can be retreived using: options = baseline('options');.