| PUBLICATION
NUMBER |
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AAT 3150764
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| TITLE
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Deterministic and stochastic extensions of the Jeep problem
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| AUTHOR
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Giffen,
William J. |
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| DEGREE
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PhD
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| SCHOOL
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PURDUE
UNIVERSITY |
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| DATE
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2004
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| PAGES
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136
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| ADVISER
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Morin,
Thomas L. |
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| ISBN
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978-0-496-10876-3 |
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| SOURCE
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DAI-B
65/10, p. 5333, Apr 2005 |
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| SUBJECT
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ENGINEERING, INDUSTRIAL (0546) |
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| DIGITAL
FORMATS |
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 3.52Mb image-only PDF
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This thesis
represents the extension of the Jeep Problem into two previously
unexplored areas. The Jeep Problem is a well known logistics problem
wherein a jeep must cross a desert wider than it can travel on one
tank of fuel. The first extension solves the problem when depots
must be purchased with fuel. The second extension adds a stochastic
element to the model, in the form of a gamma distributed fuel
consumption function. Adding depot costs to the Jeep Problem led to
four major results. Firstly, it is proven that all optimal solutions
to the modified Jeep Problem require the driver to consume integer
amounts of fuel between depots (i.e. no fractional loads of fuel are
carried into the desert), and that those amounts are no longer
limited to one load of fuel. Secondly, as the number of depots drop,
the inter-depot distances tend to equalize. Thirdly, when depot
costs depend on the distance from the origin, the earlier distances
tend to become smaller, with more fuel “pushed
out” to later depots. Finally, higher depot costs result
in fewer depots, with more loads of fuel between them. The
stochastic extension of the Jeep Problem led to a number of
interesting results. The first is that the most appropriate model
for modeling fuel mileage was found to be the gamma distribution, as
it can model a wide range of mileage functions. However, with the
gamma distribution, as the variance increased (relative to the
mean), the expected distance traveled dropped. In addition, as the
number of loads of fuel are increased, unexpectedly, the number of
depots that are used in the optimal solution drops with increased
variance. Both behaviors are the result of risk aversion, and in the
latter case, a sacrifice of efficiency is made in favor of safety.
It is believed that these extensions allow the Jeep Problem, to
extend into new classes of problems. These include the manned
mission to mars and military supply problems, and other classes of
problems where the basic Jeep Problem is not robust enough to be
applicable.
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