| MATLAB Function Reference | |
x = lsqnonneg(C,d)
x = lsqnonneg(C,d,x0)
x = lsqnonneg(C,d,x0,options)
[x,resnorm] = lsqnonneg(...)
[x,resnorm,residual] = lsqnonneg(...)
[x,resnorm,residual,exitflag] = lsqnonneg(...)
[x,resnorm,residual,exitflag,output] = lsqnonneg(...)
[x,resnorm,residual,exitflag,output,lambda]
= lsqnonneg(...)
x = lsqnonneg(C,d) returns the vector x that minimizes norm(C*x-d) subject to x >= 0. C and d must be real.
x = lsqnonneg(C,d,x0) uses x0 as the starting point if all x0 >= 0; otherwise, the default is used. The default start point is the origin (the default is used when x0==[ ] or when only two input arguments are provided).
x = lsqnonneg(C,d,x0,options) minimizes with the optimization parameters specified in the structure options. You can define these parameters using the optimset function. lsqnonneg uses these options structure fields:
Display | Level of display. 'off' displays no output; 'final' displays just the final output; 'notify' (default) displays output only if the function does not converge. |
TolX | Termination tolerance on x. |
OutputFcn | User-defined function that is called at each iteration. See Output Function in the Optimization Toolbox for more information. |
PlotFcns | User-defined plot function that is called at each iteration. See Plot Functions in the Optimization Toolbox for more information. |
[x,resnorm] = lsqnonneg(...) returns the value of the squared 2-norm of the residual: norm(C*x-d)^2.
[x,resnorm,residual] = lsqnonneg(...) returns the residual, d-C*x.
[x,resnorm,residual,exitflag] = lsqnonneg(...) returns a value exitflag that describes the exit condition of lsqnonneg:
>0 | Indicates that the function converged to a solution x. |
0 | Indicates that the iteration count was exceeded. Increasing the tolerance (TolX parameter in options) may lead to a solution. |
[x,resnorm,residual,exitflag,output] = lsqnonneg(...) returns a structure output that contains information about the operation:
output.algorithm | The algorithm used |
output.iterations | The number of iterations taken |
[x,resnorm,residual,exitflag,output,lambda] = lsqnonneg(...) returns the dual vector (Lagrange multipliers) lambda, where lambda(i)<=0 when x(i) is (approximately) 0, and lambda(i) is (approximately) 0 when x(i)>0.
Compare the unconstrained least squares solution to the lsqnonneg solution for a 4-by-2 problem:
C = [
0.0372 0.2869
0.6861 0.7071
0.6233 0.6245
0.6344 0.6170];
d = [
0.8587
0.1781
0.0747
0.8405];
[C\d lsqnonneg(C,d)] =
-2.5627 0
3.1108 0.6929
[norm(C*(C\d)-d) norm(C*lsqnonneg(C,d)-d)] =
0.6674 0.9118The solution from lsqnonneg does not fit as well (has a larger residual), as the least squares solution. However, the nonnegative least squares solution has no negative components.
lsqnonneg uses the algorithm described in [1]. The algorithm starts with a set of possible basis vectors and computes the associated dual vector lambda. It then selects the basis vector corresponding to the maximum value in lambda in order to swap out of the basis in exchange for another possible candidate. This continues until lambda <= 0.
The arithmetic operator \, optimset
[1] Lawson, C.L. and R.J. Hanson, Solving Least Squares Problems, Prentice-Hall, 1974, Chapter 23, p. 161.
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