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Applications of discrete mathematics
127
Book Announcements
Uniform
Perfectness.
a Solution cedure.
Theory
GAME-THEORETIC RATIONALITY. Payoff
Based Solely on Risk Dominance
The Role of Strategic
J.L. Nazareth, Oxford, 1987)
Net Distance.
Computer
Solution
Possible
timality.
Associating
Method.
The Simplex Method
Multipliers
tion. The Simplex Method: Complexity External
Problem.
on the Canonical
Form.
Algebraic
Program.
Internal
Representation
4: The Basis Matrix:
Numerical
Number
Representation.
Analysis
of Op-
Column-Oriented 3: Problem Program.
of Numerical
of Basic Arithmetic
Descrip-
Convergence
of a Linear
Fundamentals
The Diet Pro2: The Simplex
Simplex Algorithm.
PART II: PRACTICAL ASPECTS. Chaper
Chapter
Pro-
Press,
Characterization Chapter
The Simplex Method:
Details of Implementation. Linear Algebra.
University
and Their Solution.
Interpretation.
The Primal
Would
and the Tracing
(Oxford
Geometry. Their
Description.
Simplex Algorithm. of a Linear
and
Priors
to Our Theory.
1: Linear Programs
a Vertex
Row-Oriented
of the Primal Representation
with
Refinements
The Underlying
and Risk Dominance.
Bicentric
of Linear Programs
PART 1: BASIC THEORY AND METHOD. Chapter blem. The Linear Programming
Dominance
be Preferable?
and Setup.
Practical
Computation
Operations.
and
Analysis
of Sequences of Arithmetic Operations and Attendant Difficulties. Analysis of Algorithms. Theory and Stability of Problems. Summary. Chapter 5: The Basis Matrix: Factorizing
Perturbation and Solving.
Prerequisites.
Interchanges.
Pivoting
The LU Factorization.
Strategies
During
LU Factorization.
Computed
Solution.
Basis Matrix: Golub
to Ensure Variants
Practical
Exiting
Variables.
Choosing
the Exiting
Chapter gramming
Issues. Systems.
Chapter
7: Selection
Update.
Strategies. Chapter
When
Choosing the Basis
the Entering
10: Mathematical
Model Specification
Method.
timality
Conditions
Programming
Systems The Linear
Details
of Implementation.
troduction.
Algorithm.
Chapter
Decomposition
tions. Variants. Chapter
The Diet Problem
Numerical
Behavior
Practical
Details
with Row Partitions. of Decomposition
Principle
binatorial
and
and the Simplex
Ringeisen and Fred (SIAM, Philadelphia,
Results
Geometry
Principle
Method.
of Updates
and
the Entering
and
Details
the Exiting
Variable Finding
of Implementation.
in Practice.
Theory.
Sensitivity
Practical
PART
Principle
Ties to Op-
Analysis.
and the Simplex Method
ImPro-
Optimizer.
11: The Duality
and Duality
Introduction.
Further
Mathematical
Programming
Decomposition
Algorithms.
Sequences Choosing
Practical
Method.
with Column
InParti-
Details of Implementation. The Self-Dual
Simplex
of Implementation.
PART 1: PLENARV SESSIONS. The
Methods
Dual Programs
6: The
The Bartels-
Simplex Algorithm.
Solving the Dual Program.
12: The Decomposifion
Method
13: The Homotopy
Richard D. Mathematics
Revisited.
Chapter
When the Basis Is Infeasible.
Practical
of the Primal
and Interpretation.
and Simplex Algorithms.
of the
Choosing
III: OPTIMIZAXON PRINCIPLE + SIMPLEX METHOD = LP ALGORITHM. Chapter
and the Simplex
Fill-in
The Accuracy
8: Selection Strategies:
Variable
Is Infeasible.
An Implementation
to Control
the LU Factors.
Strategies:
Selection
9: Practical Implementation.
plementation
Updating
Details of Implementation.
Background.
Variable
of Equations.
The Fletcher-Matthews
Variable.
Column
Strategies
Details of Implementation.
Form Update.
Chapter
the Entering Practical
an Initial Feasible Solution. Choosing
Update.
Pivoting
Systems
Practical
The Product
Details of Implementation.
When the Basis Is Feasible.
Solving
on LU Factorization.
The Forrest-Tomlin
Solving.
Strategies.
and Solving.
with Row and/or
of the LU Factorization.
Combined
Updating
Update.
The LU Factorization
Stability
in Cryptography (Paul Erd6s).
S. Roberts, eds., Applications PA, 1988) 230 pages
of
Cryptanalysis of Knapsack Cryptosystems (Ernest F. (Don Coppersmith). Some Old and New Problems
A Survey
of Applications
of Operations
Research
Discrete
Brickell). in Com-
in the Airline
In-
dustry Jr.).
(Kevin K. Gillette). Recent
Results
“Locator’s”
Interval
Graphs,
in the Theory
Dilemma
(Christoph
Interval
of Random
J. Witzgall
Orders, Orders
and Patsy
Bienstock).
McCullers Provan
Probabilistic
Analysis
and R. Kevin Wood).
and Michael
of Fault
Efficient
0. Ball). Algebraic
Aspects
Chemical Graph Theory. Facile Calculation Grahps
in
Dynamic
TcpalagicaI in Graphs
Systems.
&dices (Dennis
(R.
of Computing
King).
(W.T.
Electronic
Pivotal
Network
Reliability
(Jerry
Characterization
(D.W. Bange, A.E. Barkauskas
and P.J. Slater).
&he
(Douglas
Ray Dias).
Recent Problems
T.
(J. Scott R. Shier).
Signed
of Molecular
Graphs
(William
Systems
Directed
Branching
Top&s on Domirtaf
H. Rauvray).
and
of Halin
Decomposition
and 2-Monotonic
Eigenvalues
Trotter,
Mail
PART II: MINISYMPOSIA. Com-
of Generalizations
Using
of Matroid
of Graph
Bruce
Analysis
Trees
Recognition
Winkler).
B. Saunders).
binatorial Aspects of Network Reliability. On Reliability (Daniel
and Their Generalizations (Peter
Using
Daminating
and Results about
Sets Kernels
in Directed Graphs (C. Berge and P. Duchet). Recent Results and Open Problems in Domination Theory (S.T. Hedetniemi and R. Laskar). PART Ill: OPEN PROBLEMS. Problem Session (D.J. Kleitman). PART IV: LIST OF PRESENTEDPAPERS.
Gerard Hegron,
Image Synthesis:
Elementary
Algorithms
(MIT Press, Cambridge,
MA, 1988) 216 pages Chapter 1: General Problems of Elementary Processing in Image Synthesis. Algorithms processing.
Image information.
Codifying
the image.
Gtener ation on n Surf ace r$ Dots. \nQo&&cn. of straight G~x?&xI,
line segments. -Z 4cq-fi&1&.
C(olouim_e. polygaual
Zone zaues.
Classifying segment
Generation
cutout
Generation
of ellipses.
<~Qx^J&, 4& -ir,%vc*i?~+.alar+&+??,
Co nc&ia
Comparison
contour.
window.
03 po>ysonal
methohs.
Generation
Generailon
of parabolas.
. ,3l&iYZ7 I;. Z-&%5~,%ii~. ~~r~Y??~~X!?YI,.
zones
‘m’lo sjmple
of a point and a polygonal
Using a polygonal
Cutting
and elementary
Chapter 2: Curve
&emems.
Cross-hatc%jns
4: CU?OUCAlgariTkrns and Geometric Processing. Introduction.
ct. Ck@er
problems.
in image synthesis.
GeneTti c~a~~~~~~a~%sn. IntTementa\
of circles.
‘ill’n_e. Decompo3~on
with a polygonal
using a polygonal c~oncsuslDJI.
Processing
window
contour.
Cutting
to cut out a polygon.
out of one zone by another.
Generalization
out a straight Cutting
to non-polygonal
zones.
Anthony L. Peressini, Francis E. Sullivan and J.J. Uhl Jr, The Mathematics Nonlinear Programming (Springer, Berlin, 1988) 273 pages Chapter 1: Unconstrained Optimization via Calculus. Functions variables.
Positive
minimizers. Convex functions.
and
Eigenvalues
sets.
Some
negative
and positive
illustrations
Convexity
definite
and
matrices
definite
of convex
and
of one variable.
optimization.
Coercive
of
of several and
global
Chapter 2: Convex Sets and Convex Functions.
matrices.
sets in economics-Linear
the arithmetic-geometric
Functions functions
line
out a zone
mean
production
inequality-An
models.
introduction
Convex
to geometric
programming. Unconstrained geometric programming. Convexity and other inequalities. Chapter 3: Iterative Methods for Unconstrained Optimization. Newton’s method. The method of steepest descent. Beyond steepest descent. Broyden’s method. Secant methods for minimization. Chnpler 4: Leasf Squares Optimization. Least squares fit. Subspaces and projections. Minimum norm solutions of underde&s&r&
9ic-u. ‘~~%%xz.
‘,-VA&Trrcr~pxGi-m% %im!~‘mm~-; &I%~mak Gkmrakzc-,
Convex Programming and the Karush-Kuhn-Tucker Convex .Drogramtij,n2.:
canvex
sns.
theorem
and constrajned
geometrjc
Conditions. Separation
%he Xarush-X-in-7 programmjng.
Dual
ucker convex
$9x&m.. c%&‘q*- I :
and support
theorems
for
%heoTem. The Xarush-Xuhn-Tucker programs.
Trust re.gions.
CYzapfer 6:
Penalty Methods. Penalty functions. The penalty method. Applications of the penalty function method to convex programs. Chapter 7: Optimization with Equality Constraints. Surfaces and their tangent
Book Announcements
Uniform
Perfectness.
a Solution cedure.
Theory
GAME-THEORETIC RATIONALITY. Payoff
Based Solely on Risk Dominance
The Role of Strategic
J.L. Nazareth, Oxford, 1987)
Net Distance.
Computer
Solution
Possible
timality.
Associating
Method.
The Simplex Method
Multipliers
tion. The Simplex Method: Complexity External
Problem.
on the Canonical
Form.
Algebraic
Program.
Internal
Representation
4: The Basis Matrix:
Numerical
Number
Representation.
Analysis
of Op-
Column-Oriented 3: Problem Program.
of Numerical
of Basic Arithmetic
Descrip-
Convergence
of a Linear
Fundamentals
The Diet Pro2: The Simplex
Simplex Algorithm.
PART II: PRACTICAL ASPECTS. Chaper
Chapter
Pro-
Press,
Characterization Chapter
The Simplex Method:
Details of Implementation. Linear Algebra.
University
and Their Solution.
Interpretation.
The Primal
Would
and the Tracing
(Oxford
Geometry. Their
Description.
Simplex Algorithm. of a Linear
and
Priors
to Our Theory.
1: Linear Programs
a Vertex
Row-Oriented
of the Primal Representation
with
Refinements
The Underlying
and Risk Dominance.
Bicentric
of Linear Programs
PART 1: BASIC THEORY AND METHOD. Chapter blem. The Linear Programming
Dominance
be Preferable?
and Setup.
Practical
Computation
Operations.
and
Analysis
of Sequences of Arithmetic Operations and Attendant Difficulties. Analysis of Algorithms. Theory and Stability of Problems. Summary. Chapter 5: The Basis Matrix: Factorizing
Perturbation and Solving.
Prerequisites.
Interchanges.
Pivoting
The LU Factorization.
Strategies
During
LU Factorization.
Computed
Solution.
Basis Matrix: Golub
to Ensure Variants
Practical
Exiting
Variables.
Choosing
the Exiting
Chapter gramming
Issues. Systems.
Chapter
7: Selection
Update.
Strategies. Chapter
When
Choosing the Basis
the Entering
10: Mathematical
Model Specification
Method.
timality
Conditions
Programming
Systems The Linear
Details
of Implementation.
troduction.
Algorithm.
Chapter
Decomposition
tions. Variants. Chapter
The Diet Problem
Numerical
Behavior
Practical
Details
with Row Partitions. of Decomposition
Principle
binatorial
and
and the Simplex
Ringeisen and Fred (SIAM, Philadelphia,
Results
Geometry
Principle
Method.
of Updates
and
the Entering
and
Details
the Exiting
Variable Finding
of Implementation.
in Practice.
Theory.
Sensitivity
Practical
PART
Principle
Ties to Op-
Analysis.
and the Simplex Method
ImPro-
Optimizer.
11: The Duality
and Duality
Introduction.
Further
Mathematical
Programming
Decomposition
Algorithms.
Sequences Choosing
Practical
Method.
with Column
InParti-
Details of Implementation. The Self-Dual
Simplex
of Implementation.
PART 1: PLENARV SESSIONS. The
Methods
Dual Programs
6: The
The Bartels-
Simplex Algorithm.
Solving the Dual Program.
12: The Decomposifion
Method
13: The Homotopy
Richard D. Mathematics
Revisited.
Chapter
When the Basis Is Infeasible.
Practical
of the Primal
and Interpretation.
and Simplex Algorithms.
of the
Choosing
III: OPTIMIZAXON PRINCIPLE + SIMPLEX METHOD = LP ALGORITHM. Chapter
and the Simplex
Fill-in
The Accuracy
8: Selection Strategies:
Variable
Is Infeasible.
An Implementation
to Control
the LU Factors.
Strategies:
Selection
9: Practical Implementation.
plementation
Updating
Details of Implementation.
Background.
Variable
of Equations.
The Fletcher-Matthews
Variable.
Column
Strategies
Details of Implementation.
Form Update.
Chapter
the Entering Practical
an Initial Feasible Solution. Choosing
Update.
Pivoting
Systems
Practical
The Product
Details of Implementation.
When the Basis Is Feasible.
Solving
on LU Factorization.
The Forrest-Tomlin
Solving.
Strategies.
and Solving.
with Row and/or
of the LU Factorization.
Combined
Updating
Update.
The LU Factorization
Stability
in Cryptography (Paul Erd6s).
S. Roberts, eds., Applications PA, 1988) 230 pages
of
Cryptanalysis of Knapsack Cryptosystems (Ernest F. (Don Coppersmith). Some Old and New Problems
A Survey
of Applications
of Operations
Research
Discrete
Brickell). in Com-
in the Airline
In-
dustry Jr.).
(Kevin K. Gillette). Recent
Results
“Locator’s”
Interval
Graphs,
in the Theory
Dilemma
(Christoph
Interval
of Random
J. Witzgall
Orders, Orders
and Patsy
Bienstock).
McCullers Provan
Probabilistic
Analysis
and R. Kevin Wood).
and Michael
of Fault
Efficient
0. Ball). Algebraic
Aspects
Chemical Graph Theory. Facile Calculation Grahps
in
Dynamic
TcpalagicaI in Graphs
Systems.
&dices (Dennis
(R.
of Computing
King).
(W.T.
Electronic
Pivotal
Network
Reliability
(Jerry
Characterization
(D.W. Bange, A.E. Barkauskas
and P.J. Slater).
&he
(Douglas
Ray Dias).
Recent Problems
T.
(J. Scott R. Shier).
Signed
of Molecular
Graphs
(William
Systems
Directed
Branching
Top&s on Domirtaf
H. Rauvray).
and
of Halin
Decomposition
and 2-Monotonic
Eigenvalues
Trotter,
PART II: MINISYMPOSIA. Com-
of Generalizations
Using
of Matroid
of Graph
Bruce
Analysis
Trees
Recognition
Winkler).
B. Saunders).
binatorial Aspects of Network Reliability. On Reliability (Daniel
and Their Generalizations (Peter
Using
Daminating
and Results about
Sets Kernels
in Directed Graphs (C. Berge and P. Duchet). Recent Results and Open Problems in Domination Theory (S.T. Hedetniemi and R. Laskar). PART Ill: OPEN PROBLEMS. Problem Session (D.J. Kleitman). PART IV: LIST OF PRESENTEDPAPERS.
Gerard Hegron,
Image Synthesis:
Elementary
Algorithms
(MIT Press, Cambridge,
MA, 1988) 216 pages Chapter 1: General Problems of Elementary Processing in Image Synthesis. Algorithms processing.
Image information.
Codifying
the image.
Gtener ation on n Surf ace r$ Dots. \nQo&&cn. of straight G~x?&xI,
line segments. -Z 4cq-fi&1&.
C(olouim_e. polygaual
Zone zaues.
Classifying segment
Generation
cutout
Generation
of ellipses.
<~Qx^J&, 4& -ir,%vc*i?~+.alar+&+??,
Co nc&ia
Comparison
contour.
window.
03 po>ysonal
methohs.
Generation
Generailon
of parabolas.
. ,3l&iYZ7 I;. Z-&%5~,%ii~. ~~r~Y??~~X!?YI,.
zones
‘m’lo sjmple
of a point and a polygonal
Using a polygonal
Cutting
and elementary
Chapter 2: Curve
&emems.
Cross-hatc%jns
4: CU?OUCAlgariTkrns and Geometric Processing. Introduction.
ct. Ck@er
problems.
in image synthesis.
GeneTti c~a~~~~~~a~%sn. IntTementa\
of circles.
‘ill’n_e. Decompo3~on
with a polygonal
using a polygonal c~oncsuslDJI.
Processing
window
contour.
Cutting
to cut out a polygon.
out of one zone by another.
Generalization
out a straight Cutting
to non-polygonal
zones.
Anthony L. Peressini, Francis E. Sullivan and J.J. Uhl Jr, The Mathematics Nonlinear Programming (Springer, Berlin, 1988) 273 pages Chapter 1: Unconstrained Optimization via Calculus. Functions variables.
Positive
minimizers. Convex functions.
and
Eigenvalues
sets.
Some
negative
and positive
illustrations
Convexity
definite
and
matrices
definite
of convex
and
of one variable.
optimization.
Coercive
of
of several and
global
Chapter 2: Convex Sets and Convex Functions.
matrices.
sets in economics-Linear
the arithmetic-geometric
Functions functions
line
out a zone
mean
production
inequality-An
models.
introduction
Convex
to geometric
programming. Unconstrained geometric programming. Convexity and other inequalities. Chapter 3: Iterative Methods for Unconstrained Optimization. Newton’s method. The method of steepest descent. Beyond steepest descent. Broyden’s method. Secant methods for minimization. Chnpler 4: Leasf Squares Optimization. Least squares fit. Subspaces and projections. Minimum norm solutions of underde&s&r&
9ic-u. ‘~~%%xz.
‘,-VA&Trrcr~pxGi-m% %im!~‘mm~-; &I%~mak Gkmrakzc-,
Convex Programming and the Karush-Kuhn-Tucker Convex .Drogramtij,n2.:
canvex
sns.
theorem
and constrajned
geometrjc
Conditions. Separation
%he Xarush-X-in-7 programmjng.
Dual
ucker convex
$9x&m.. c%&‘q*- I :
and support
theorems
for
%heoTem. The Xarush-Xuhn-Tucker programs.
Trust re.gions.
CYzapfer 6:
Penalty Methods. Penalty functions. The penalty method. Applications of the penalty function method to convex programs. Chapter 7: Optimization with Equality Constraints. Surfaces and their tangent