Clustering, Randomness, and Regularity: Spatial Distributions and Human Performance on the Traveling Salesperson Problem and Minimum Spanning Tree Problem

We investigated human performance on the Euclidean Traveling Salesperson Problem (TSP) and Euclidean Minimum Spanning Tree Problem (MST-P) in regards to a factor that has previously received little attention within the literature: the spatial distributions of TSP and MST-P stimuli. First, we describe a method for quantifying the relative degree of clustering, randomness or regularity within point distributions. We then review evidence suggesting this factor might influence human performance on the two problem types. Following this we report an experiment in which the participants were asked to solve TSP and MST-P test stimuli that had been generated to be either highly clustered, random, or highly regular. The results indicate that for both the TSP and MST-P the participants tended to produce better quality solutions when the stimuli were highly clustered compared to random, and similarly, better quality solutions for random compared to highly regular stimuli. It is suggested that these results provide support for the ideas that human solv- ers attend to salient clusters of nodes when solving these problems, and that a similar process (or series of processes) may underlie human performance on these two tasks.

[1]  Douglas Vickers,et al.  Are Individual Differences in Performance on Perceptual and Cognitive Optimization Problems Determined by General Intelligence? , 2006, J. Probl. Solving.

[2]  M. Lee,et al.  Intelligence and individual differences in performance on three types of visually presented optimisation problems , 2004 .

[3]  A. Joshi,et al.  The traveling salesman problem: A hierarchical model , 2000, Memory & cognition.

[4]  Godfried T. Toussaint,et al.  The relative neighbourhood graph of a finite planar set , 1980, Pattern Recognit..

[5]  Sang Joon Kim,et al.  A Mathematical Theory of Communication , 2006 .

[6]  P. J. Clark,et al.  Distance to Nearest Neighbor as a Measure of Spatial Relationships in Populations , 1954 .

[7]  R. Sokal,et al.  A New Statistical Approach to Geographic Variation Analysis , 1969 .

[8]  N Ginsburg,et al.  Measurement of visual cluster. , 1987, The American journal of psychology.

[9]  Yll Haxhimusa,et al.  2D and 3D Traveling Salesman Problem , 2011, J. Probl. Solving.

[10]  Susanne Tak,et al.  Some Tours are More Equal than Others: The Convex-Hull Model Revisited with Lessons for Testing Models of the Traveling Salesperson Problem , 2008, J. Probl. Solving.

[11]  M. Lee,et al.  The roles of the convex hull and the number of potential intersections in performance on visually presented traveling salesperson problems , 2003, Memory & cognition.

[12]  Yll Haxhimusa,et al.  Approximative graph pyramid solution of the E-TSP , 2009, Image Vis. Comput..

[13]  W. Press,et al.  Numerical Recipes in Fortran: The Art of Scientific Computing.@@@Numerical Recipes in C: The Art of Scientific Computing. , 1994 .

[14]  T. Ormerod,et al.  A model of human performance on the traveling salesperson problem , 2000, Memory & cognition.

[15]  Tommy Gärling,et al.  Heuristic rules for sequential spatial decisions , 1992 .

[16]  Zhe Jiang,et al.  Spatial Statistics , 2013 .

[17]  Douglas Vickers,et al.  Human Performance on Visually Presented Traveling Salesperson Problems with Varying Numbers of Nodes , 2006, J. Probl. Solving.

[18]  Narendra Ahuja,et al.  Dot Pattern Processing Using Voronoi Neighborhoods , 1982, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[19]  Christian D. Schunn,et al.  Global vs. local information processing in visual/spatial problem solving: The case of traveling salesman problem , 2007, Cognitive Systems Research.

[20]  Franz Aurenhammer,et al.  Voronoi diagrams—a survey of a fundamental geometric data structure , 1991, CSUR.

[21]  William H. Press,et al.  Numerical Recipes in FORTRAN - The Art of Scientific Computing, 2nd Edition , 1987 .

[22]  Yll Haxhimusa,et al.  Traveling Salesman Problem: A Foveating Pyramid Model , 2006, J. Probl. Solving.

[23]  T. Tuulmets,et al.  Occupancy model of perceived numerosity , 1991, Perception & psychophysics.

[24]  T. Ormerod,et al.  Convex hull or crossing avoidance? Solution heuristics in the traveling salesperson problem , 2004, Memory & cognition.

[25]  T. Ormerod,et al.  Human performance on the traveling salesman problem , 1996, Perception & psychophysics.

[26]  A. Volgenant,et al.  The travelling salesman, computational solutions for TSP applications , 1996 .

[27]  T. Ormerod,et al.  Spatial and Contextual Factors in Human Performance on the Travelling Salesperson Problem , 1999, Perception.

[28]  P. Hertz,et al.  Über den gegenseitigen durchschnittlichen Abstand von Punkten, die mit bekannter mittlerer Dichte im Raume angeordnet sind , 1909 .

[29]  Nicos Christofides Worst-Case Analysis of a New Heuristic for the Travelling Salesman Problem , 1976, Operations Research Forum.

[30]  Adrian K Preiss,et al.  A theoretical and computational investigation into aspects of human visual perception : proximity and transformations in pattern detection and discrimination , 2006 .

[31]  Giovanni Gallo,et al.  Geographical data analysis via mountain function , 1999, Int. J. Intell. Syst..

[32]  David Marshall Smith Patterns in human geography: An introduction to numerical methods , 1975 .

[33]  T. Ormerod,et al.  Global perceptual processing in problem solving: The case of the traveling salesperson , 1999, Perception & psychophysics.

[34]  J. Kruskal On the shortest spanning subtree of a graph and the traveling salesman problem , 1956 .

[35]  James N. MacGregor,et al.  Human Performance on the Traveling Salesman and Related Problems: A Review , 2011, J. Probl. Solving.