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LKH is an implementation of the Lin-Kernighan traveling salesman heuristic. The code is distributed for research use. The author reserves all rights to the code. INSTRUCTIONS FOR INSTALLATION: (Version 2.0.7 - November 2012) ----------------------------- The software is available in gzipped tar format: LKH-2.0.7.tgz (approximately 900 KB) Download the software and execute the following UNIX commands: tar xvfz LKH-2.0.7.tgz cd LKH-2.0.7 make An executable file called LKH will now be available in the directory LKH-2.0.7. To test the installation run the program by typing ./LKH pr2392.par. Then press return. The program should now solve a problem with 2392 cities. For further instructions, see the user guide and the short description of their parameters in the DOC directory. A two-level tree [6] is used as the default tour representation. A three-level tree representation may be used in stead by compiling the source code with the compiler option -DTHREE_LEVEL_TREE Just edit the first line in SRC/Makefile and execute the commands make clean make CHANGES IN VERSION 2.0.7: ------------------------- Added an approximate K-center clustering algorithm for tour partitioning (new keyword: K-CENTER). Improved performance on HCP and HPP instances. CHANGES IN VERSION 2.0.6: ------------------------- The replacement strategy (CD/RW) proposed by Lozano, Herrera and Cano for preserving useful diversity in steady-state genetic algorithms has been added. CHANGES IN VERSION 2.0.5: ------------------------- Guibas and Stolfi's mplementation of Delaunay triangulation has been replaced by a faster implementation made by Geoff Leach. CHANGES IN VERSION 2.0.4: ------------------------- Added hierarchical compression of subproblems in up to 10 levels (Version 2.0.3 allowed only one level). CHANGES IN VERSION 2.0.3: ------------------------- A simple genetic algorithm has been added. New keyword: POPULATION_SIZE. Tours found by the first POPULATION_SIZE runs constitute an initial population of tours. In each of the remaining runs two tours (parents) from the current population is recombined into a new tour (child) using a variant of the Edge Recombination Crossover (ERX). The parents are chosen with random linear bias towards the best members of the population. The child is used as initial tour for the next run. If this run produces a tour better than the worst tour of the population, then the resulting tour replaces the worst tour. Premature convergence is avoided by requiring that all tours in the population have different costs. CHANGES IN VERSION 2.0.2: ------------------------- Minor changes in the code for solving subproblems. CHANGES IN VERSION 2.0.1: ------------------------- Improved distance caching and faster add/delete testing for K-opt moves. This speeds up the execution by 5-10 percent. CHANGES IN VERSION 2.0: ----------------------- The new version extends the previous one by data structures and algorithms for solving very large instances, and by facilities for obtaining solutions of even higher quality. Many changes have been made. Below is given a short description of the main features. 1. General K-opt moves One of the most important means in LKH-2 for obtaining high-quality solutions is its use of general K-opt moves. In the original version of the Lin-Kernighan algorithm moves are restricted to those that can be decomposed into a 2- or 3-opt move followed by a (possible empty) sequence of 2-opt moves. This restriction simplifies implementation but it needs not be the best design choice if high-quality solutions are sought. This has been demonstrated with LKH-1, which uses a 5-opt sequential move as the basic move component. LKH-2 takes this idea a step further. Now K-opt moves can be used as sub-moves, where K is any chosen integer greater than or equal to 2 and less than the number of cities. Each sub-move is sequential. However, during the search for such moves, non-sequential moves may also be examined. Thus, in contrast to the original version of the Lin-Kernighan algorithm, non-sequential moves are not just tried as last resort but are integrated into the ordinary search. 2. Partitioning In order to reduce the complexity of solving large-scale problem instances, LKH-2 makes it possible to partition a problem into smaller subproblems. Each subproblem is solved separately and its solution is used (if possible) to improve a given overall tour. Even the solution of small problem instances may sometimes benefit from partitioning as it helps in focusing in the search process. Currently, LKH-2 implements the following six partitioning schemes: Tour segment partitioning, Karp partitioning, Delaunay partitioning, K-means partitioning, Rohe partitioning, and Sierpinski partitioning. 3. Tour merging LKH-2 provides a tour merging procedure that attempts to produce the best possible tour from two or more given tours using local optimization of an instance that includes all tour edges, and where edges common to the tours are fixed. Tours that are close to optimal typically share many common edges. Thus, the input graph for this instance is usually very sparse, which makes it practicable to use K-opt moves for rather large values of K. 4. Iterative partial transcription Iterative artial description is a general procedure for improving the performance of a local search based heuristic algorithms. It attempts to improve two individual solutions by replacing certain parts of either solution by the related parts of the other solution. The procedure may be applied to the TSP by searching for subchains of two tours, which contains the same cities in a different order and have the same initial and final cities. LKH-2 uses the procedure on each locallyoptimal tour and the up to now best tour. The implemented algorithm is a simplified version of the algorithm described by Moebius, Freisleben, Merz and Schreiber. 5. Backbone-guided search The edges of the tours produced by a fixed number of initial trials may be used as candidate edges in the succeeding trials. This algorithm, which is a simplified version of the algorithm given by Zhang and Looks, has turned out to be particularly effective for VLSI instances. 6. Data structures and algorithms for solving very large instances Delaunay triangulation may be used to speed up the determination of alpha- nearest candidate edges, and tours may be represented internally by three- level trees. New keywords: BACKTRACKING = { YES | NO } CANDIDATE_SET_TYPE = { ALPHA | DELAUNAY [PURE ] | NEAREST-NEIGHBOR | QUADRANT | REINELT } EXTRA_CANDIDATES = <integer> [ SYMMETRIC ] EXTRA_CANDIDATE_SET_TYPE = { NEAREST-NEIGHBOR | QUADRANT | REINELT } GAIN_CRITERION = { YES | NO } INITIAL_TOUR_ALGORITHM = { BORUVKA | GREEDY | NEAREST-NEIGHBOR | QUICK-BORUVKA | SIERPINSKI | WALK } INITIAL_TOUR_FRACTION = <real in [0;1]> KICKS = <integer> KICK_TYPE = <integer> MAX_BACKBONE_TRIALS = <integer> MAX_BREADTH = <integer> MERGE_TOUR_FILE = <string> NONSEQUENTIAL_MOVE_TYPE = <integer> PATCHING_A = <integer> [ RESTRICTED | EXTENDED ] PATCHING_C = <integer> [ RESTRICTED | EXTENDED ] SUBPROBLEM_SIZE = <integer> [ DELAUNAY | KARP | K-MEANS | ROHE | MOORE | SIERPINSKI ] [ COMPRESSED ] [ BORDERS ] SUBPROBLEM_TOUR_FILE = <string> SUBSEQUENT_MOVE_TYPE = <integer> SUBSEQUENT_PATCHING = { YES | NO } # <string> Removed keywords: BACKTRACK_MOVE_TYPE MERGE_TOUR_FILE_1 MERGE_TOUR_FILE_2 CHANGES IN VERSION 1.3: ---------------------- The distance type GEOM has been added (see www.math.princeton.edu/tsp/world). Additional control information may now be given in the parameter file by means of the following keywords: BACKTRACK_MOVE_TYPE CANDIDATE_FILE INITIAL_TOUR_FILE MAX_SWAPS MERGE_TOUR_FILE_1 ERGE_TOUR_FILE_2 RESTRICTED_SEARCH CHANGES IN VERSION 1.2: ---------------------- Execution times may be measured more accurately, if the getrusage function is supported by the system. See the GetTime.c file for instructions. CHANGES IN VERSION 1.1: ---------------------- The code has been made more robust regarding the solution of asymmetric problems. The old code (LKH-1.0, February 1999) could loose its way in some cases due to integer overflow.
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