sepa_eccuts.h
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21 * We call \f$ f \f$ an edge-concave function on a polyhedron \f$P\f$ iff it is concave in all edge directions of
22 * \f$P\f$. For the special case \f$ P = [\ell,u]\f$ this is equivalent to \f$f\f$ being concave componentwise.
24 * Since the convex envelope of an edge-concave function is a polytope, the value of the convex envelope for a
37 * where \f$ \{ v_i \} \f$ are the vertices of the domain \f$ [\ell,u] \f$. Let \f$ (\alpha, \alpha_0) \f$ be the dual
38 * solution of this LP. It can be shown that \f$ \alpha' x + \alpha_0 \f$ is a facet of the convex envelope of \f$ f \f$
41 * We use this as follows: We transform the problem to the unit box \f$ [0,1]^n \f$ by using an linear affine
43 * This has the advantage that we do not have to update the matrix of the LP for different edge-concave functions.
45 * For a given quadratic constraint \f$ g(x) := x'Qx + b'x + c \le 0 \f$ we decompose \f$ g \f$ into several
52 * where each \f$ f_i \f$ is edge-concave. To separate a given solution \f$ x \f$, we compute a facet of the convex
53 * envelope \f$ \tilde f \f$ for each edge-concave function \f$ f_i \f$ and an underestimator \f$ \tilde r \f$
60 * We solve auxiliary MIP problems to identify good edge-concave aggregations. From the literature it is known that the
61 * convex envelope of an bilinear edge-concave function \f$ f_i \f$ differs from McCormick iff in the graph
62 * representation of \f$ f_i \f$ there exist a cycle with an odd number of positive weighted edges. We look for a
63 * subgraph of the graph representation of the quadratic function \f$ g(x) \f$ with the previous property using a model
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Definition: struct_scip.h:58
type definitions for return codes for SCIP methods
type definitions for SCIP's main datastructure
common defines and data types used in all packages of SCIP
Definition: objbenders.h:33