MINLPLib

A Library of Mixed-Integer and Continuous Nonlinear Programming Instances

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Instance st_bsj3

Formats^ⓘ	ams gms lp mod nl osil pip py
Primal Bounds (infeas ≤ 1e-08)^ⓘ	0.00000000 p1 ( gdx sol ) (infeas: 0) -86768.55000000 p2 ( gdx sol ) (infeas: 0)
Other points (infeas > 1e-08)^ⓘ
Dual Bounds^ⓘ	-86768.55009000 (ANTIGONE) -86768.55009000 (BARON) -86768.55000000 (COUENNE) -86768.55000000 (CPLEX) -86768.55000000 (LINDO) -86768.55000000 (SCIP)
References^ⓘ	Tawarmalani, M and Sahinidis, N V, Convexification and Global Optimization in Continuous and Mixed-Integer Nonlinear Programming: Theory, Algorithms, Software, and Applications, Kluwer, 2002. Shectman, J P and Sahinidis, N V, A finite algorithm for global minimization of separable concave programs, Journal of Global Optimization, 12:1, 1998, 1-36. Shectman, J P, Finite Algorithms for Global Optimization of Concave Programs and General Quadratic Programs, PhD thesis, Department of Mechanical and Industrial Engineering, University of Illinois, Urbana Champagne, 1999.
Added to library^ⓘ	03 Sep 2002
Problem type^ⓘ	QP
#Variables^ⓘ	6
#Binary Variables^ⓘ	0
#Integer Variables^ⓘ	0
#Nonlinear Variables^ⓘ	6
#Nonlinear Binary Variables^ⓘ	0
#Nonlinear Integer Variables^ⓘ	0
Objective Sense^ⓘ	min
Objective type^ⓘ	quadratic
Objective curvature^ⓘ	concave
#Nonzeros in Objective^ⓘ	6
#Nonlinear Nonzeros in Objective^ⓘ	6
#Constraints^ⓘ	1
#Linear Constraints^ⓘ	1
#Quadratic Constraints^ⓘ	0
#Polynomial Constraints^ⓘ	0
#Signomial Constraints^ⓘ	0
#General Nonlinear Constraints^ⓘ	0
Operands in Gen. Nonlin. Functions^ⓘ
Constraints curvature^ⓘ	linear
#Nonzeros in Jacobian^ⓘ	6
#Nonlinear Nonzeros in Jacobian^ⓘ	0
#Nonzeros in (Upper-Left) Hessian of Lagrangian^ⓘ	6
#Nonzeros in Diagonal of Hessian of Lagrangian^ⓘ	6
#Blocks in Hessian of Lagrangian^ⓘ	6
Minimal blocksize in Hessian of Lagrangian^ⓘ	1
Maximal blocksize in Hessian of Lagrangian^ⓘ	1
Average blocksize in Hessian of Lagrangian^ⓘ	1.0
#Semicontinuities^ⓘ	0
#Nonlinear Semicontinuities^ⓘ	0
#SOS type 1^ⓘ	0
#SOS type 2^ⓘ	0
Minimal coefficient^ⓘ	1.0000e+00
Maximal coefficient^ⓘ	1.0500e+01
Infeasibility of initial point^ⓘ	0
Sparsity Jacobian^ⓘ
Sparsity Hessian of Lagrangian^ⓘ

$offlisting
*  
*  Equation counts
*      Total        E        G        L        N        X        C        B
*          2        1        0        1        0        0        0        0
*  
*  Variable counts
*                   x        b        i      s1s      s2s       sc       si
*      Total     cont   binary  integer     sos1     sos2    scont     sint
*          7        7        0        0        0        0        0        0
*  FX      0
*  
*  Nonzero counts
*      Total    const       NL      DLL
*         13        7        6        0
*
*  Solve m using NLP minimizing objvar;


Variables  x1,x2,x3,x4,x5,x6,objvar;

Positive Variables  x1,x2,x3,x4,x5,x6;

Equations  e1,e2;


e1..    x1 + x2 + x3 + x4 + x5 + x6 =L= 10000000000;

e2.. -(10.5*x1 - 1.5*sqr(x1) - sqr(x2) - 3.95*x2 - sqr(x3) + 3*x3 - 2*sqr(x4)
      + 5*x4 - sqr(x5) + 1.5*x5 - 2.5*sqr(x6) - 1.5*x6) + objvar =E= 0;

* set non-default bounds
x1.up = 99;
x2.up = 99;
x3.up = 99;
x4.up = 99;
x5.up = 99;
x6.up = 99;

Model m / all /;

m.limrow=0; m.limcol=0;
m.tolproj=0.0;

$if NOT '%gams.u1%' == '' $include '%gams.u1%'

$if not set NLP $set NLP NLP
Solve m using %NLP% minimizing objvar;

Last updated: 2025-08-07 Git hash: e62cedfc

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