Hi all,
A slightly longwinded approach to potentially solving this problem would be first obtaining the coefficient values and coefficient names using coeffvalues and coeffnames. For the example below the following curve cfit object was created for demonstration but it should also work for sfit with the appropriate modifications.
ft =
General model:
ft(a,b,x) = a*x+b
curve =
General model:
curve(x) = a*x+b
Coefficients:
a = 2
b = 1
ans =
2×1 cell array
{'a'}
{'b'}
ans =
2 1
Once the coefficient names and values are known the next step is to define the Starting Points and the fitoptions.
fo = fitoptions(ft)
fo =
Normalize: 'off'
Exclude: []
Weights: []
Method: 'NonlinearLeastSquares'
Robust: 'Off'
StartPoint: [1×0 double]
Lower: [1×0 double]
Upper: [1×0 double]
Algorithm: 'Trust-Region'
DiffMinChange: 1.0000e-08
DiffMaxChange: 0.1000
Display: 'Notify'
MaxFunEvals: 600
MaxIter: 400
TolFun: 1.0000e-06
TolX: 1.0000e-06
By changing the StartPoint of the optimisation process to the coefficient values found previously and forcing both the Maximum Number of Function Evaluations and Maximum Number of Iterations to be equal to 1.
fo.StartPoint = [2,1];
fo.MaxFunEvals = 1;
fo.MaxIter = 1;
This forces the algorithm to only evaluate the fit at the Start Point and therefore the coefficient values from the original cfit object and the cfit object obtained through the fit command below.
[fitobject,gof,output] = fit(x,y,ft,fo)
For example using the example data below results in...
x = [1:1:10];
y = curve(x);
fitobject =
General model:
fitobject(x) = a*x+b
Coefficients (with 95% confidence bounds):
a = 2 (2, 2)
b = 1 (1, 1)
gof =
struct with fields:
sse: 0
rsquare: 1
dfe: 8
adjrsquare: 1
rmse: 0
output =
struct with fields:
numobs: 10
numparam: 2
residuals: [10×1 double]
Jacobian: [10×2 double]
exitflag: 1
firstorderopt: 0
iterations: 0
funcCount: 3
cgiterations: 0
algorithm: 'trust-region-reflective'
stepsize: 1
message: 'Success. Fitting converged to a solution.'
Bear in mind that this method only works on general and nonlinear models as it makes use of the NonlinearLeastSquares fitoptions.
Using the following alternative values for the y data gives...
fitobject =
General model:
fitobject(x) = a*x+b
Coefficients (with 95% confidence bounds):
a = 2 (0.1118, 3.888)
b = 1 (-10.72, 12.72)
gof =
struct with fields:
sse: 442.5000
rsquare: -4.3636
dfe: 8
adjrsquare: -5.0341
rmse: 7.4372
output =
struct with fields:
numobs: 10
numparam: 2
residuals: [10×1 double]
Jacobian: [10×2 double]
exitflag: 0
firstorderopt: 412.5000
iterations: 0
funcCount: 3
cgiterations: 0
algorithm: 'trust-region-reflective'
stepsize: 1
message: 'Fitting stopped because the number of iterations or function evaluations exceeded the specified maximum.'
This approach may not work for all cases so I would appreciate it if others could verify this method works for other cases. For example using other more complex models.
