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JMSLTM Numerical Library 6.1 | |||||||
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java.lang.Object com.imsl.math.MinUncon
public class MinUncon
Unconstrained minimization.
MinUncon
uses two separate algorithms to compute the
minimum depending on what the user supplies as the function f
.
If f
defines the function whose minimum is to be found
MinUncon
uses a safeguarded quadratic interpolation method to
find a minimum point of a univariate function. Both the code and the
underlying algorithm are based on the routine ZXLSF
written by
M.J.D. Powell at the University of Cambridge.
MinUncon
finds the least value of a univariate function,
f, where f
implements
MinUnconFunction f
.
Optional data include an initial estimate of the solution, and a positive
number bound
, specified by the setBound
method.
Let where xguess
is specified
by the setGuess
method and b = bound, then
x is restricted to the interval
. Usually, the algorithm begins the
search by moving from to ,
where s = step. step
is set by the
setStep
method. If setStep
is not called then
step
is set to 0.1. step
may be positive or negative. The first two function evaluations indicate the
direction to the minimum point, and the search strides out along this
direction until a bracket on a minimum point is found or until
x reaches one of the bounds .
During this stage, the step length increases by a factor of between two and
nine per function evaluation; the factor depends on the position of the
minimum point that is predicted by quadratic interpolation of the three most
recent function values.
When an interval containing a solution has been found, we will have three points, , , and , with and and . There are three main ingredients in the technique for choosing the new x from these three points. They are (i) the estimate of the minimum point that is given by quadratic interpolation of the three function values, (ii) a tolerance parameter , that depends on the closeness of f to a quadratic, and (iii) whether is near the center of the range between and or is relatively close to an end of this range. In outline, the new value of x is as near as possible to the predicted minimum point, subject to being at least from , and subject to being in the longer interval between and or and when is particularly close to or . There is some elaboration, however, when the distance between these points is close to the required accuracy; when the distance is close to the machine precision; or when is relatively large.
The algorithm is intended to provide fast convergence when f has a positive and continuous second derivative at the minimum and to avoid gross inefficiencies in pathological cases, such as
The algorithm can make large automatically
in the pathological cases. In this case, it is usual for a new value of
x to be at the midpoint of the longer interval that is
adjacent to the least calculated function value. The midpoint strategy is used
frequently when changes to f are dominated by
computer rounding errors, which will
almost certainly happen if the user requests an accuracy that is less than
the square root of the machine precision. In such cases, the routine claims
to have achieved the required accuracy if it knows that there is a local
minimum point within distance of
x, where , specified
by the setAccuracy
method even though the rounding errors in
f may cause the existence of other local minimum points
nearby. This difficulty is inevitable in minimization routines that use only
function values, so high precision arithmetic is recommended.
If f
implements MinUnconDerivative
then
MinUncon
uses a descent method with either the secant method or
cubic interpolation to find a minimum point of a univariate function. It
starts with an initial guess and two endpoints. If any of the three points
is a local minimum point and has least function value, the routine
terminates with a solution. Otherwise, the point with least function value
will be used as the starting point.
From the starting point, say , the function value , the derivative value , and a new point defined by are computed. The function , and the derivative are then evaluated. If either or has the opposite sign of , then there exists a minimum point between and ; and an initial interval is obtained. Otherwise, since is kept as the point that has lowest function value, an interchange between and is performed. The secant method is then used to get a new point
Let and repeat this process until an interval containing a minimum is found or one of the convergence criteria is satisfied. The convergence criteria are as follows: Criterion 1:
Criterion 2:
where , is a relative error tolerance and is a gradient tolerance.
When convergence is not achieved, a cubic interpolation is performed to obtain a new point. Function and derivative are then evaluated at that point; and accordingly, a smaller interval that contains a minimum point is chosen. A safeguarded method is used to ensure that the interval reduces by at least a fraction of the previous interval. Another cubic interpolation is then performed, and this procedure is repeated until one of the stopping criteria is met.
Nested Class Summary | |
---|---|
static interface |
MinUncon.Derivative
Public interface for the user supplied function to the MinUncon object. |
static interface |
MinUncon.Function
Public interface for the user supplied function to the MinUncon object. |
Constructor Summary | |
---|---|
MinUncon()
Unconstrained minimum constructor for a smooth function of a single variable of type double . |
Method Summary | |
---|---|
double |
computeMin(MinUncon.Function F)
Return the minimum of a smooth function of a single variable of type double
using function values only or using function values and derivatives. |
void |
setAccuracy(double xacc)
Set the required absolute accuracy in the final value returned by member function computeMin . |
void |
setBound(double bound)
Set the amount by which X may be changed from its initial value, xguess. |
void |
setDerivtol(double gtol)
Set the derivative tolerance used by member function computeMin to decide
if the current point is a local minimum. |
void |
setGuess(double xguess)
Set the initial guess of the minimum point of the input function. |
void |
setStep(double step)
Set the stepsize to use when changing x. |
Methods inherited from class java.lang.Object |
---|
clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait |
Constructor Detail |
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public MinUncon()
double
.
Method Detail |
---|
public double computeMin(MinUncon.Function F)
double
using function values only or using function values and derivatives.
F
- defines the function whose minimum is to be found. If F
implements
Derivative
then derivatives are used. Otherwise, an attempt
to find the minimum is made using function values only.
double
scalar value containing the minimum of the input functionpublic void setAccuracy(double xacc)
computeMin
. If this member function is not called, the required accuracy is set
to 1.0e-8.
xacc
- a double
scalar value specifying the required absolute accuracy
in the final value returned by member function computeMin
.public void setBound(double bound)
bound
- a double
scalar value specifying the amount by which X
may be changed from its initial value. In other words, X is
restricted to the interval
[xguess-bound
, xguess+bound
].public void setDerivtol(double gtol)
computeMin
to decide
if the current point is a local minimum. This is the second stopping
criterion. x is returned as a solution when G(x) is less than or equal to
gtol
. gtol
should be nonnegative, otherwise zero will be used. If this
member function is not called, the derivative tolerance is set to 1.0e-8.
gtol
- a double
scalar value specifying the derivative
tolerance used by member function computeMin
.public void setGuess(double xguess)
xguess
- a double
scalar value specifying the initial guess of the
minimum point of the input functionpublic void setStep(double step)
step
- a double
scalar value specifying the order of magnitude estimate
of the required change in x when stepping towards the minimum
|
JMSLTM Numerical Library 6.1 | |||||||
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