# Difference between revisions of "Package glpk/GLPK.MIPMax"

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<item>@return List of linear polynomials, the zeros of the polynomials are the points where the optimal value of the objective function is achieved</item> | <item>@return List of linear polynomials, the zeros of the polynomials are the points where the optimal value of the objective function is achieved</item> | ||

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+ | <see>Package glpk/GLPK.LPMax</see> | ||

+ | <see>Package glpk/GLPK.BPMax</see> | ||

+ | <see>Package glpk/GLPK.MIPMin</see> | ||

+ | </seealso> | ||

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## Latest revision as of 15:34, 1 November 2020

This article is about a function from ApCoCoA-2. If you are looking for the ApCoCoA-1 version of it, see ApCoCoA-1:GLPK.MIPMax. |

## GLPK.LPMax

Solving mixed integer linear programmes by maximizing the objective function.

### Syntax

GLPK.MIPMax(Objective_f:POLY, Inequations:LIST, Bounds:LIST, Integral:LIST, Binary:LIST) :LIST

### Description

*Please note:* The function(s) explained on this page is/are using the *ApCoCoAServer*. You will have to start the ApCoCoAServer in order to use it/them.

@param

*Objective_f*: A linear polynomial which is equivalent to the linear objective function.@param

*Inequations*: List of linear polynomials, which are equivalent to the conditions of the linear program of the form A <= 0.@param

*Bounds*: List of lists with two elements. Each List contains the lower and upper bounds for each variable. You can choose between INT or RAT for the type of each bound, if you type in a (empty) string, then it means minus infinity (first place) or plus infinity (second place).@param

*Integral*: List of variables, which should be integer.*Note*: For each variable in this list, the borders get rounded (lower bound: up and upper bound: down). In the case that the lower rounded bound becomes greater then the upper rounded bound, glpk returns: Solution Status: INTEGER UNDEFINED - Value of objective function: 0.@param

*Binary*: List of variables, which should be binaries (0 or 1).@return List of linear polynomials, the zeros of the polynomials are the points where the optimal value of the objective function is achieved

### See also