Threshold and Complexity Results for the Cover Pebbling Game

Godbole, Anant P., Watson, Nathaniel G., Yerger, Carl R.

06 June 2009

Given a configuration of pebbles on the vertices of a graph, a pebbling move is defined by removing two pebbles from some vertex and placing one pebble on an adjacent vertex. The cover pebbling number of a graph, γ (G), is the smallest number of pebbles such that through a sequence of pebbling moves, a pebble can eventually be placed on every vertex simultaneously, no matter how the pebbles are initially distributed. We determine Bose-Einstein and Maxwell-Boltzmann cover pebbling thresholds for the complete graph. Also, we show that the cover pebbling decision problem is NP-complete.

complete graph

cover pebbling

solvable

threshold

Mathematics and Statistics

Cover Pebbling Thresholds for the Complete Graph

Godbole, Anant P., Watson, Nathaniel G., Yerger, Carl R.

15 October 2005

We obtain first-order cover pebbling thresholds of the complete graph for Maxwell Boltzmann and Bose Einstein configurations.

Bose Einstein

complete

cover pebbling

Maxwell Boltzmann

threshold

Mathematics and Statistics

Machine Learning Techniques as Applied to Discrete and Combinatorial Structures

Schwartz, Samuel David

01 August 2019

Machine Learning Techniques have been used on a wide array of input types: images, sound waves, text, and so forth. In articulating these input types to the almighty machine, there have been all sorts of amazing problems that have been solved for many practical purposes. Nevertheless, there are some input types which don’t lend themselves nicely to the standard set of machine learning tools we have. Moreover, there are some provably difficult problems which are abysmally hard to solve within a reasonable time frame. This thesis addresses several of these difficult problems. It frames these problems such that we can then attempt to marry the allegedly powerful utility of existing machine learning techniques to the practical solvability of said problems.

Machine Learning

Graphs

NP Complete

Neural Networks

Random Forests

Mathematics

Multi-Robot Complete Coverage Using Directional Constraints

Malan, Stefanus

01 January 2018

Complete coverage relies on a path planning algorithm that will move one or more robots, including the actuator, sensor, or body of the robot, over the entire environment. Complete coverage of an unknown environment is used in applications like automated vacuum cleaning, carpet cleaning, lawn mowing, chemical or radioactive spill detection and cleanup, and humanitarian de-mining. The environment is typically decomposed into smaller areas and then assigned to individual robots to cover. The robots typically use the Boustrophedon motion to cover the cells. The location and size of obstacles in the environment are unknown beforehand. An online algorithm using sensor-based coverage with unlimited communication is typically used to plan the path for the robots. For certain applications, like robotic lawn mowing, a pattern might be desirable over a random irregular pattern for the coverage operation. Assigning directional constraints to the cells can help achieve the desired pattern if the path planning part of the algorithm takes the directional constraints into account. The goal of this dissertation is to adapt the distributed coverage algorithm with unrestricted communication developed by Rekleitis et al. (2008) so that it can be used to solve the complete coverage problem with directional constraints in unknown environments while minimizing repeat coverage. It is a sensor-based approach that constructs a cellular decomposition while covering the unknown environment. The new algorithm takes directional constraints into account during the path planning phase. An implementation of the algorithm was evaluated in simulation software and the results from these experiments were compared against experiments conducted by Rekleitis et al. (2008) and with an implementation of their distributed coverage algorithm. The results of this study confirm that directional constraints can be added to the complete coverage algorithm using multiple robots without any significant impact on performance. The high-level goals of complete coverage were still achieved. The work was evenly distributed between the robots to reduce the time required to cover the cells.

complete coverage

directional constraints

Computer Sciences

Databases and Information Systems

Prenatal Heart Block Screening in Mothers With SSA/SSB Auto-antibodies: Targeted Screening Protocol is a Cost-Effective Strategy

Evers, Patrick D., M.D.

09 July 2019

No description available.

Surgery

Neonatal Systemic Lupus Erythematosus

complete heart block

cost-utility

Reforming Complete Streets: considering the street as place

Desai, Maitri

22 June 2015

No description available.

Urban Planning

Urban Design

Streets

Complete Streets

Liberty Street, Cincinnati

TREATMENT OF DATA WITH MISSING ELEMENTS IN PROCESS MODELLING

RAPUR, NIHARIKA

02 September 2003

No description available.

Engineering, Industrial

missing data

data

complete

incomplete

data cleansing

A Local Improvement Algorithm for Multiple Sequence Alignment

Zhang, Xiaodong

04 April 2003

No description available.

Multiple Sequence Alignment

Algorithm

Simulated Annealing

NP-Complete

Efficient Generation of Reducts and Discerns for Classification

Graham, James T.

24 August 2007

No description available.

Rough Sets

Reducts

Discerns

Population Sampling

NP complete

A natural history of complete consonantal assimilations

Hutcheson, James Wallace

January 1973

No description available.

COMPLETE ASSIMILATIONS

Phonological

consonants

assimilation rule

morpheme

vowels