Controlling the Branch-and-Bound Algorithm
There are numerous strategies that can be used to control the branch-and-bound search (see Linderoth and Savelsbergh 1998, Achterberg, Koch, and Martin 2005).
PROC OPTMILP implements the most widely used strategies and provides several options
that enable you to direct the choice of the next active node and of the branching variable.
In the discussion that follows, let () be the linear programming
relaxation of subproblem (). Also, let
where
is the optimal solution to the relaxation problem (
)
solved at node
.
The NODESEL= option specifies the strategy used to select the next
active node. The valid keywords for this option are AUTOMATIC, BESTBOUND, BESTESTIMATE,
and DEPTH. The following list describes the strategy associated with each keyword.
- AUTOMATIC
- allows PROC OPTMILP to choose the best node selection
strategy based on problem characteristics and search progress.
This is the default setting.
- BESTBOUND
- chooses the node with the smallest (or largest, in the
case of a maximization problem) relaxed objective value.
The best-bound strategy tends to reduce the number of nodes to be
processed and can improve lower bounds quickly. If there is no
good upper bound, however, the number of active nodes can be
large. This can result in the solver running out of memory.
- BESTESTIMATE
- chooses the node with the smallest (or largest, in the
case of a maximization problem) objective
value of the estimated integer solution. Besides improving
lower bounds, the best-estimate strategy also attempts to process nodes that can
yield good feasible solutions.
- DEPTH
- chooses the node that is deepest in the search tree.
Depth-first search is effective in locating feasible
solutions, since such solutions are usually deep in the search tree.
Compared to the costs of the best-bound and best-estimate strategies, the
cost of solving LP relaxations is less in the depth-first strategy.
The number of active nodes is generally small, but it is possible that
the depth-first search will remain in a portion of the search tree with no
good integer solutions. This occurrence is computationally expensive.
The VARSEL= option specifies the strategy used to select the
next branching variable. The valid keywords for this option are
AUTOMATIC, MAXINFEAS, MININFEAS, PSEUDO, and STRONG.
The following list describes the action taken in each case when
, a relaxed optimal solution
of (), is used to define two active
subproblems. In the following list, "INTTOL" refers to the value
assigned using the INTTOL= option. For details about the
INTTOL= option, see the section "Control Options".
- AUTOMATIC
- enables PROC OPTMILP to choose the best variable selection
strategy based on problem characteristics and search progress. This is the
default setting.
- MAXINFEAS
- chooses as the branching variable the variable
such that maximizes
- MININFEAS
- chooses as the branching variable
the variable such that minimizes
- PSEUDO
- chooses as the branching variable the variable
such that maximizes the weighted
up and down pseudocosts.
Pseudocost branching attempts to branch on significant variables
first, quickly improving lower bounds.
Pseudocost branching estimates significance based on
historical information; however, this approach might not be accurate
for future search.
- STRONG
- chooses as the branching variable the variable
such that maximizes the estimated improvement
in the objective value. Strong branching first generates a list of
candidates, then branches on each candidate and records the improvement
in the objective value. The candidate with the largest improvement is chosen as
the branching variable. Strong branching can be effective for combinatorial
problems, but it is usually computationally expensive.
In some cases, it is possible to speed up the branch-and-bound algorithm by branching on
variables in a specific order. You can accomplish this in PROC OPTMILP by attaching
branching priorities to the integer variables in your model.
There are two ways in which you can set branching priorities for use by PROC OPTMILP.
You can specify the branching priorities directly in the input MPS-format data set; see
the section "BRANCH Section (Optional)" for details. If you are constructing a model in PROC OPTMODEL,
you can set branching priorities for integer variables by using the .priority suffix.
More information about this suffix is available in the section "Integer Variable Suffixes"
in Chapter 6. For an example in which branching priorities are used, see Example 9.3.
Copyright © 2008 by SAS Institute Inc., Cary, NC, USA. All rights reserved.