linprog(method=’simplex’)¶
-
scipy.optimize.
linprog
(c, method='simplex', callback=None, options={'c0': None, 'A': None, 'b': None, 'maxiter': 1000, 'disp': False, 'tol': 1e-12, 'bland': False, '_T_o': None}, x0=None) Minimize a linear objective function subject to linear equality and non-negativity constraints using the two phase simplex method. Linear programming is intended to solve problems of the following form:
Minimize:
c @ x
Subject to:
A @ x == b x >= 0
- Parameters
- c1D array
Coefficients of the linear objective function to be minimized.
- c0float
Constant term in objective function due to fixed (and eliminated) variables. (Purely for display.)
- A2D array
2D array such that
A @ x
, gives the values of the equality constraints atx
.- b1D array
1D array of values representing the right hand side of each equality constraint (row) in
A
.- callbackcallable, optional
If a callback function is provided, it will be called within each iteration of the algorithm. The callback function must accept a single
scipy.optimize.OptimizeResult
consisting of the following fields:- x1D array
Current solution vector
- funfloat
Current value of the objective function
- successbool
True when an algorithm has completed successfully.
- slack1D array
The values of the slack variables. Each slack variable corresponds to an inequality constraint. If the slack is zero, the corresponding constraint is active.
- con1D array
The (nominally zero) residuals of the equality constraints, that is,
b - A_eq @ x
- phaseint
The phase of the algorithm being executed.
- statusint
An integer representing the status of the optimization:
0 : Algorithm proceeding nominally 1 : Iteration limit reached 2 : Problem appears to be infeasible 3 : Problem appears to be unbounded 4 : Serious numerical difficulties encountered
- nitint
The number of iterations performed.
- messagestr
A string descriptor of the exit status of the optimization.
- Returns
- x1D array
Solution vector.
- statusint
An integer representing the exit status of the optimization:
0 : Optimization terminated successfully 1 : Iteration limit reached 2 : Problem appears to be infeasible 3 : Problem appears to be unbounded 4 : Serious numerical difficulties encountered
- messagestr
A string descriptor of the exit status of the optimization.
- iterationint
The number of iterations taken to solve the problem.
See also
For documentation for the rest of the parameters, see
scipy.optimize.linprog
- Options
- maxiterint
The maximum number of iterations to perform.
- dispbool
If True, print exit status message to sys.stdout
- tolfloat
The tolerance which determines when a solution is “close enough” to zero in Phase 1 to be considered a basic feasible solution or close enough to positive to serve as an optimal solution.
- blandbool
If True, use Bland’s anti-cycling rule [3] to choose pivots to prevent cycling. If False, choose pivots which should lead to a converged solution more quickly. The latter method is subject to cycling (non-convergence) in rare instances.
Notes
The expected problem formulation differs between the top level
linprog
module and the method specific solvers. The method specific solvers expect a problem in standard form:Minimize:
c @ x
Subject to:
A @ x == b x >= 0
Whereas the top level
linprog
module expects a problem of form:Minimize:
c @ x
Subject to:
A_ub @ x <= b_ub A_eq @ x == b_eq lb <= x <= ub
where
lb = 0
andub = None
unless set inbounds
.The original problem contains equality, upper-bound and variable constraints whereas the method specific solver requires equality constraints and variable non-negativity.
linprog
module converts the original problem to standard form by converting the simple bounds to upper bound constraints, introducing non-negative slack variables for inequality constraints, and expressing unbounded variables as the difference between two non-negative variables.References
- 1
Dantzig, George B., Linear programming and extensions. Rand Corporation Research Study Princeton Univ. Press, Princeton, NJ, 1963
- 2
Hillier, S.H. and Lieberman, G.J. (1995), “Introduction to Mathematical Programming”, McGraw-Hill, Chapter 4.
- 3
Bland, Robert G. New finite pivoting rules for the simplex method. Mathematics of Operations Research (2), 1977: pp. 103-107.