NAG Library Routine Document
E02BEF
1 Purpose
E02BEF computes a cubic spline approximation to an arbitrary set of data points. The knots of the spline are located automatically, but a single parameter must be specified to control the trade-off between closeness of fit and smoothness of fit.
2 Specification
SUBROUTINE E02BEF ( |
START, M, X, Y, W, S, NEST, N, LAMDA, C, FP, WRK, LWRK, IWRK, IFAIL) |
INTEGER |
M, NEST, N, LWRK, IWRK(NEST), IFAIL |
REAL (KIND=nag_wp) |
X(M), Y(M), W(M), S, LAMDA(NEST), C(NEST), FP, WRK(LWRK) |
CHARACTER(1) |
START |
|
3 Description
E02BEF determines a smooth cubic spline approximation to the set of data points , with weights , for .
The spline is given in the B-spline representation
where
denotes the normalized cubic B-spline defined upon the knots
.
The total number of these knots and their values are chosen automatically by the routine. The knots are the interior knots; they divide the approximation interval into sub-intervals. The coefficients are then determined as the solution of the following constrained minimization problem:
minimize
subject to the constraint
where |
|
stands for the discontinuity jump in the third order derivative of at the interior knot , |
|
|
denotes the weighted residual , |
and |
|
is a non-negative number to be specified by you. |
The quantity
can be seen as a measure of the (lack of) smoothness of
, while closeness of fit is measured through
. By means of the parameter
, ‘the smoothing factor’, you can then control the balance between these two (usually conflicting) properties. If
is too large, the spline will be too smooth and signal will be lost (underfit); if
is too small, the spline will pick up too much noise (overfit). In the extreme cases the routine will return an interpolating spline
if
is set to zero, and the weighted least squares cubic polynomial
if
is set very large. Experimenting with
values between these two extremes should result in a good compromise. (See
Section 9.2 for advice on choice of
.)
The method employed is outlined in
Section 9.3 and fully described in
Dierckx (1975),
Dierckx (1981) and
Dierckx (1982). It involves an adaptive strategy for locating the knots of the cubic spline (depending on the function underlying the data and on the value of
), and an iterative method for solving the constrained minimization problem once the knots have been determined.
Values of the computed spline, or of its derivatives or definite integral, can subsequently be computed by calling
E02BBF,
E02BCF or
E02BDF, as described in
Section 9.4.
4 References
Dierckx P (1975) An algorithm for smoothing, differentiating and integration of experimental data using spline functions J. Comput. Appl. Math. 1 165–184
Dierckx P (1981) An improved algorithm for curve fitting with spline functions Report TW54 Department of Computer Science, Katholieke Univerciteit Leuven
Dierckx P (1982) A fast algorithm for smoothing data on a rectangular grid while using spline functions SIAM J. Numer. Anal. 19 1286–1304
Reinsch C H (1967) Smoothing by spline functions Numer. Math. 10 177–183
5 Parameters
- 1: – CHARACTER(1)Input
-
On entry: must be set to 'C' or 'W'.
- The routine will build up the knot set starting with no interior knots. No values need be assigned to the parameters N, LAMDA, WRK or IWRK.
- The routine will restart the knot-placing strategy using the knots found in a previous call of the routine. In this case, the parameters N, LAMDA, WRK, and IWRK must be unchanged from that previous call. This warm start can save much time in searching for a satisfactory value of .
Constraint:
or .
- 2: – INTEGERInput
-
On entry: , the number of data points.
Constraint:
.
- 3: – REAL (KIND=nag_wp) arrayInput
-
On entry: the values
of the independent variable (abscissa) , for .
Constraint:
.
- 4: – REAL (KIND=nag_wp) arrayInput
-
On entry: the values
of the dependent variable (ordinate) , for .
- 5: – REAL (KIND=nag_wp) arrayInput
-
On entry: the values
of the weights, for
. For advice on the choice of weights, see
Section 2.1.2 in the E02 Chapter Introduction.
Constraint:
, for .
- 6: – REAL (KIND=nag_wp)Input
-
On entry: the smoothing factor,
.
If , the routine returns an interpolating spline.
If is smaller than machine precision, it is assumed equal to zero.
For advice on the choice of
, see
Sections 3 and
9.2.
Constraint:
.
- 7: – INTEGERInput
-
On entry: an overestimate for the number, , of knots required.
Constraint:
. In most practical situations,
is sufficient.
NEST never needs to be larger than
, the number of knots needed for interpolation
.
- 8: – INTEGERInput/Output
-
On entry: if the warm start option is used, the value of
N must be left unchanged from the previous call.
On exit: the total number, , of knots of the computed spline.
- 9: – REAL (KIND=nag_wp) arrayInput/Output
-
On entry: if the warm start option is used, the values must be left unchanged from the previous call.
On exit: the knots of the spline, i.e., the positions of the interior knots
as well as the positions of the additional knots
and
needed for the B-spline representation.
- 10: – REAL (KIND=nag_wp) arrayOutput
-
On exit: the coefficient
of the B-spline in the spline approximation , for .
- 11: – REAL (KIND=nag_wp)Output
-
On exit: the sum of the squared weighted residuals,
, of the computed spline approximation. If
, this is an interpolating spline.
FP should equal
within a relative tolerance of
unless
when the spline has no interior knots and so is simply a cubic polynomial. For knots to be inserted,
must be set to a value below the value of
FP produced in this case.
- 12: – REAL (KIND=nag_wp) arrayCommunication Array
-
If the warm start option is used on entry, the values must be left unchanged from the previous call.
- 13: – INTEGERInput
-
On entry: the dimension of the array
WRK as declared in the (sub)program from which E02BEF is called.
Constraint:
.
- 14: – INTEGER arrayCommunication Array
-
If the warm start option is used, on entry, the values must be left unchanged from the previous call.
This array is used as workspace.
- 15: – INTEGERInput/Output
-
On entry:
IFAIL must be set to
,
. If you are unfamiliar with this parameter you should refer to
Section 3.3 in the Essential Introduction for details.
For environments where it might be inappropriate to halt program execution when an error is detected, the value
is recommended. If the output of error messages is undesirable, then the value
is recommended. Otherwise, if you are not familiar with this parameter, the recommended value is
.
When the value is used it is essential to test the value of IFAIL on exit.
On exit:
unless the routine detects an error or a warning has been flagged (see
Section 6).
6 Error Indicators and Warnings
If on entry
or
, explanatory error messages are output on the current error message unit (as defined by
X04AAF).
Errors or warnings detected by the routine:
-
On entry, | or , |
or | , |
or | , |
or | and , |
or | , |
or | . |
-
The weights are not all strictly positive.
-
The values of , for , are not in strictly increasing order.
-
The number of knots required is greater than
NEST. Try increasing
NEST and, if necessary, supplying larger arrays for the parameters
LAMDA,
C,
WRK and
IWRK. However, if
NEST is already large, say
, then this error exit may indicate that
S is too small.
-
The iterative process used to compute the coefficients of the approximating spline has failed to converge. This error exit may occur if
S has been set very small. If the error persists with increased
S, contact
NAG.
An unexpected error has been triggered by this routine. Please
contact
NAG.
See
Section 3.8 in the Essential Introduction for further information.
Your licence key may have expired or may not have been installed correctly.
See
Section 3.7 in the Essential Introduction for further information.
Dynamic memory allocation failed.
See
Section 3.6 in the Essential Introduction for further information.
If
or
, a spline approximation is returned, but it fails to satisfy the fitting criterion (see
(2) and
(3)) – perhaps by only a small amount, however.
7 Accuracy
On successful exit, the approximation returned is such that its weighted sum of squared residuals
(as in
(3)) is equal to the smoothing factor
, up to a specified relative tolerance of
– except that if
,
may be significantly less than
: in this case the computed spline is simply a weighted least squares polynomial approximation of degree
, i.e., a spline with no interior knots.
8 Parallelism and Performance
E02BEF is not threaded by NAG in any implementation.
E02BEF makes calls to BLAS and/or LAPACK routines, which may be threaded within the vendor library used by this implementation. Consult the documentation for the vendor library for further information.
Please consult the
X06 Chapter Introduction for information on how to control and interrogate the OpenMP environment used within this routine. Please also consult the
Users' Note for your implementation for any additional implementation-specific information.
9.1 Timing
The time taken for a call of E02BEF depends on the complexity of the shape of the data, the value of the smoothing factor , and the number of data points. If E02BEF is to be called for different values of , much time can be saved by setting after the first call.
9.2 Choice of S
If the weights have been correctly chosen (see
Section 2.1.2 in the E02 Chapter Introduction), the standard deviation of
would be the same for all
, equal to
, say. In this case, choosing the smoothing factor
in the range
, as suggested by
Reinsch (1967), is likely to give a good start in the search for a satisfactory value. Otherwise, experimenting with different values of
will be required from the start, taking account of the remarks in
Section 3.
In that case, in view of computation time and memory requirements, it is recommended to start with a very large value for
and so determine the least squares cubic polynomial; the value returned in
FP, call it
, gives an upper bound for
. Then progressively decrease the value of
to obtain closer fits – say by a factor of
in the beginning, i.e.,
,
, and so on, and more carefully as the approximation shows more details.
The number of knots of the spline returned, and their location, generally depend on the value of and on the behaviour of the function underlying the data. However, if E02BEF is called with , the knots returned may also depend on the smoothing factors of the previous calls. Therefore if, after a number of trials with different values of and , a fit can finally be accepted as satisfactory, it may be worthwhile to call E02BEF once more with the selected value for but now using . Often, E02BEF then returns an approximation with the same quality of fit but with fewer knots, which is therefore better if data reduction is also important.
9.3 Outline of Method Used
If
, the requisite number of knots is known in advance, i.e.,
; the interior knots are located immediately as
, for
. The corresponding least squares spline (see
E02BAF) is then an interpolating spline and therefore a solution of the problem.
If
, a suitable knot set is built up in stages (starting with no interior knots in the case of a cold start but with the knot set found in a previous call if a warm start is chosen). At each stage, a spline is fitted to the data by least squares (see
E02BAF) and
, the weighted sum of squares of residuals, is computed. If
, new knots are added to the knot set to reduce
at the next stage. The new knots are located in intervals where the fit is particularly poor, their number depending on the value of
and on the progress made so far in reducing
. Sooner or later, we find that
and at that point the knot set is accepted. The routine then goes on to compute the (unique) spline which has this knot set and which satisfies the full fitting criterion specified by
(2) and
(3). The theoretical solution has
. The routine computes the spline by an iterative scheme which is ended when
within a relative tolerance of
. The main part of each iteration consists of a linear least squares computation of special form, done in a similarly stable and efficient manner as in
E02BAF.
An exception occurs when the routine finds at the start that, even with no interior knots , the least squares spline already has its weighted sum of squares of residuals . In this case, since this spline (which is simply a cubic polynomial) also has an optimal value for the smoothness measure , namely zero, it is returned at once as the (trivial) solution. It will usually mean that has been chosen too large.
For further details of the algorithm and its use, see
Dierckx (1981).
9.4 Evaluation of Computed Spline
The value of the computed spline at a given value
X may be obtained in the real variable
S by the call:
CALL E02BBF(N,LAMDA,C,X,S,IFAIL)
where
N,
LAMDA and
C are the output parameters of E02BEF.
The values of the spline and its first three derivatives at a given value
X may be obtained in the real array
S of dimension at least
by the call:
CALL E02BCF(N,LAMDA,C,X,LEFT,S,IFAIL)
where if
, left-hand derivatives are computed and if
, right-hand derivatives are calculated. The value of
LEFT is only relevant if
X is an interior knot (see
E02BCF).
The value of the definite integral of the spline over the interval
to
can be obtained in the real variable
DINT by the call:
CALL E02BDF(N,LAMDA,C,DINT,IFAIL)
(see
E02BDF).
10 Example
This example reads in a set of data values, followed by a set of values of . For each value of it calls E02BEF to compute a spline approximation, and prints the values of the knots and the B-spline coefficients .
The program includes code to evaluate the computed splines, by calls to
E02BBF, at the points
and at points mid-way between them. These values are not printed out, however; instead the results are illustrated by plots of the computed splines, together with the data points (indicated by
) and the positions of the knots (indicated by vertical lines): the effect of decreasing
can be clearly seen.
10.1 Program Text
Program Text (e02befe.f90)
10.2 Program Data
Program Data (e02befe.d)
10.3 Program Results
Program Results (e02befe.r)