Mathematics in Industrial Problems

1 Mass flow sensing with heat waves.- 1.1 Air flow sensor.- 1.2 Steady-state heat transfer.- 1.3 Heat waves.- 1.4 Automotive air flow sensor model.- 1.5 Mathematical results.- 1.6 References.- 2 Mass transport in colloidal dispersions.- 2.1 Physical motivation.- 2.2 Modeling equilibrium.- 2.3 Kinetics: single component.- 2.4 Kinetics: multiple components.- 2.5 References.- 3 Crack propagation modeling.- 3.1 Crack propagation in a conductor.- 3.2 The hypersingular integrals.- 3.3 Open problems.- 3.4 References.- 4 Modeling of electrostatic bell sprayers.- 4.1 The coating process.- 4.2 Mathematical modeling.- 4.3 Numerical results.- 4.4 Future directions.- 4.5 References.- 5 Neural networks as controllers.- 5.1 Neural networks.- 5.2 Control of dynamical systems.- 5.3 Gradient methods for controller training.- 5.4 An example.- 5.5 The idle-speed control problem.- 5.6 Unresolved questions.- 5.7 References.- 6 Head-media interaction in magnetic recording.- 6.1 Head-tape interaction.- 6.2 The mathematical model.- 6.3 Test case.- 6.4 Open problems.- 6.5 References.- 7 Geometric path planning in rapid prototyping.- 7.1 Layered manufacturing.- 7.2 Offset curve representation.- 7.3 Pythagorean—hodograph (PH) curves.- 7.4 Bézier representation.- 7.5 References.- 8 Feature detection and tracking in three dimensional image analysis.- 8.1 Applications.- 8.2 Edge detection.- 8.3 Topographic classification.- 8.4 Image registration.- 8.5 Future research issues.- 8.6 References.- 9 Robot localization using landmarks.- 9.1 The position estimation problem.- 9.2 Linear position estimation.- 9.3 Open problems.- 9.4 References.- 10 Coordinates for mechanisms configuration spaces.- 10.1 Kinematics of closed-loop mechanisms.- 10.2 Mechanism coordinates; an example.- 10.3 Mechanismcomplexity.- 10.4 Mathematical modeling.- 10.5 Open problems.- 10.6 References.- 11 Pulse optimization for multi-user data communications.- 11.1 Multiple access.- 11.2 The single user case.- 11.3 The multiple user case.- 11.4 Coupled base stations.- 11.5 Open problems.- 11.6 References.- 12 Propagation of highly scattered radiation in tissue.- 12.1 Maxwell’s equations.- 12.2 Radiation transport theory.- 12.3 Diffusion approximation.- 12.4 Imaging.- 12.5 References.- 13 Doping profiling by inverse device methods.- 13.1 Semiconductor devices.- 13.2 Measuring doping profile by direct measurements.- 13.3 PN junction.- 13.4 The inverse problem.- 13.5 References.- 14 Mathematical modeling in diffractive optics.- 14.1 The direct problem.- 14.2 Solution of the direct problem.- 14.3 Optimal design problem.- 14.4 Inverse problem.- 14.5 Diffractive optics in nonlinear media.- 14.6 Truncated periodic structure.- 14.7 References.- 15 Coping with complex boundaries.- 15.1 Capacity and translational friction.- 15.2 Flow through duct having arbitrary cross-section.- 15.3 Effective properties of inhomogeneous media.- 15.4 References.- 16 A short random walk through polymer material behavior.- 16.1 Strain-stress relations.- 16.2 Molecular modeling.- 16.3 Open problems.- 16.4 References.- 17 Finite set statistics with applications to data fusion.- 17.1 Random sets.- 17.2 Single-sensor, single-target estimation.- 17.3 Multi-sensor, multi-target estimation.- 17.4 An example.- 17.5 References.- 18 Electromigration modeling for smart power applications.- 18.1 Universal Power Output Driver (UPOD).- 18.2 Previous work.- 18.3 Electromigration.- 18.4 References.- 19 Maxwell’s equations and the analysis of electromagnetic devices.- 19.1 Electromagnetic actuators.- 19.2 The Maxwell equations.-19.3 The numerical scheme.- 19.4 References.- 20 Engineering modeling of batteries.- 20.1 Description of the battery cell.- 20.2 Mathematical modeling.- 20.3 Numerical results and open problems.- 20.4 References.- 21 Solutions to problems from previous parts.- 21.1 Part 6.- 21.2 Part 5.- 21.3 Part 3.- 21.4 Part 1.- 21.5 References.