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- Training, Tutorials, & References
- admin
- A Guide to MATLAB for ME 160 (Bray and Montazami)
- Front Matter
- 1: Introduction
- 2: Basic Commands in MATLAB
- 3: MATRIX Operations
- 4: Writing Scripts
- 5: Commands
- 6: Graphing in MATLAB
- 7: Graphical User Interface
- 8: Functions and Function Handles
- 9: Inputting and Outputting Data
- 10: Projects
- 11: Appendix A- Additional MATLAB Resources
- 12: Appendix B- A commentary on this work
- Back Matter
- Python for Everybody: Exploring Data Using Python 3 (Severance)
- Front Matter
- 1: Why should you learn to write programs?
- 2: Variables, expressions, and statements
- 3: Conditional execution
- 4: Functions
- 5: Iteration
- 6: Strings
- 7: Files
- 8: Lists
- 9: Dictionaries
- 10: Tuples
- 11: Regular expressions
- 12: Networked programs
- 13: Using Web Services
- 14: Object-oriented programming
- 15: Visualizing data
- Back Matter
- A Guide to MATLAB for ME 160 (Bray and Montazami)
- CareySmith@vcccd.edu
- MATLAB
- MATLAB Commands and Functions
- Front Matter
- 1: General Purpose Commands
- 2: Input/Output and Formatting Commands
- 3: Vector, Matrix and Array Commands
- 4: Plotting Commands
- 5: Programming
- 6: Mathematical Functions
- 7: Numerical Records
- 8: Symbolic Math Toolbox
- 8.1: Functions for Creating and Evaluating Symbolic Expressions
- 8.2: Functions for Manipulating Symbolic Expressions
- 8.3: Symbolic Calculus Functions
- 8.4: Symbolic Solution of Algebraic and Transcendental Equations
- 8.5: Symbolic Solution of Differential Equations
- 8.6: Laplace Transform Functions
- 8.7: Symbolic Linear Algebra Functions
- Back Matter
- Matlab/Octave, Pieces
- eaturner@ucdavis.edu
- jhalpern
- Energy Alternatives
- Front Matter
- 1: Energy Alternatives { what's the meaning?
- 2: General Remarks
- 3: Fossil Fuels and Thermal Engines
- 4: Nuclear Power
- 4.1: A Note from the Author
- 4.2: Nuclear Physics- Brief Review of Fundamental Facts
- 4.3: Radioactive Decay
- 4.4: Nuclear Cross Sections
- 4.5: Nuclear Fission
- 4.6: Controlling the Fission Chain Reaction- Nuclear Reactors
- 4.7: NuScale’s Small Modular Reactors – an Oregon-born Project
- 4.8: The Pros and Cons of Nuclear Power
- 5: Hydropower
- 6: Windpower
- 7: Direct Solar Power
- 7.1: Introduction
- 7.2: Harnessing Solar Power
- 7.3: The Concentrated Solar Power (CSP) Technology
- 7.4: Photovoltaic Conversion of Solar Power
- 7.4.1: Theoretical Background the Nature of Light and the Photoelectric Effect
- 7.4.2: Semiconductors and Doped Semiconductors
- 7.4.3: The p-n Junction
- 7.4.4: Internal Photoelectric Effect in Semiconductors
- 7.4.5: PV Cells
- 7.4.6: Solar Cell Efficiency
- 7.4.7: Inverters
- 7.4.8: Pros and Cons of PV Solar Power Harnessing
- 8: Harnessing Power from Oceans and Seas
- 9: Geothermal Power
- 10: Biofuels
- 11: Energy Storage
- 11.1: Introduction
- 11.2: Overcoming the Challenges of Wind Power
- 11.3: Problems with Solar Power- the \Duck Curve"
- 11.4: Energy Storage Technologies
- 11.4.1: Battery Storage
- 11.4.2: Electricity → potential energy → back to electricity (gravitational energy storage and compressed air energy storage).
- 11.4.3: Electricity → Kinetic Energy → Electricity Storage Scheme
- 11.4.4: Electricity → Thermal Energy → Electricity Storage Scheme
- 11.4.5: Electricity → Chemical Energy
- 11.4.5.1: The evolution of the hydrogen economy policy in the 21st century
- 11.4.5.2: Methods of Green Hydrogen Production
- 11.4.5.3: The recovery of energy stored in the form of hydrogen
- 11.4.5.4: Hydrogen storage and transportation issues
- 11.4.5.5: Hydrogen as a “green” fuel suitable for sea- sonal storage
- Back Matter
- Energy Alternatives
- jlindsey@uccs.edu
- Materials Science for Electrical Engineering
- Front Matter
- 1: Atomic Introduction
- 1.1: Pseudoscience
- 1.2: Essential Background
- 1.3: The Basics of Chemistry
- 1.4: Atoms and the Periodic Table
- 1.5: Properties of Gases
- 1.6: Chemical Bonding and Molecular Structure
- 1.7: Crystallography
- 1.7.1: Introduction to Crystals
- 1.7.2: Cubic Lattices and Close Packing
- 1.7.3: Ionic and Ion-Derived Solids
- 1.7.4: Introduction
- 1.7.5: Lattices
- 1.7.6: Unit Cell
- 1.7.7: Lattice Geometry
- 1.7.8: Crystal Structure
- 1.7.9: Close Packing and Packing Efficiency
- 1.7.10: Symmetry
- 1.7.11: Combining symmetry
- 1.7.12: Crystal Systems
- 1.7.13: Summary
- 1.7.14: Questions
- 1.8: Lattice Planes and Miller Indices
- 2: Solids
- 2.1: Anisotropy
- 2.2: Diffusion
- 2.3: Dislocation Energetics and Mobility
- 2.3.1: Introduction
- 2.3.2: Making a Dislocation
- 2.3.3: Join the Crystals to Form the Dislocation
- 2.3.4: Dislocation Width
- 2.3.5: Form of the Displacement
- 2.3.6: Change in the Misfit Energy of a Dislocation as it Moves
- 2.3.7: Lattice Resistance
- 2.3.8: Uses and Limitations of the Atomistic Model
- 2.3.9: Summary
- 2.3.10: Questions
- 2.4: Introduction to Dislocations
- 2.5: Plasticity
- 2.6: Solid solutions
- 3: Electrical Properties
- 3.1: Bonding in Metals
- 3.2: Bonding in Semiconductors
- 3.3: Conductors, Semiconductors and Diodes
- 3.4: FETs
- 3.5: Bipolar Transistors
- 3.6: Electronic Properties
- 3.7: Dielectric materials
- 3.7.1: Introduction
- 3.7.2: Electric Dipole
- 3.7.3: Polarisation Mechanisms
- 3.7.4: Capacitors
- 3.7.5: The Dielectric Constant
- 3.7.6: Variation of the Dielectric Constant in Alternating Fields
- 3.7.7: Effect of Structure on the Dielectric Constant
- 3.7.8: Loss in Dielectrics
- 3.7.9: Dielectric Breakdown
- 3.7.10: Applications of Dielectrics
- 3.7.11: Summary
- 3.7.12: Questions
- 4: Phases
- 5: Magnetism
- 6: Thermal Optical
- 7: Ethical use of Engineering Materials
- 8: Mechanical Properties
- 8.1: Bending and Torsion of Beams
- 8.2: Brittle Fracture
- 8.2.1: Introduction
- 8.2.2: When do atomic bonds break?
- 8.2.3: Why do cracks weaken a material?
- 8.2.4: Inglis and the crack tip stress idea
- 8.2.5: Can we calculate the energy changes?
- 8.2.6: What about tension?
- 8.2.7: Another way of expressing the energies
- 8.2.8: Another way of calculating the energies
- 8.2.9: Why bother if they are the same?
- 8.2.10: Coping with a scatter in strength
- 8.2.11: When does the sample fail completely?
- 8.2.12: Sub-critical crack growth and R-curves
- 8.2.13: Summary
- 8.2.14: Questions
- 8.3: Introduction to Deformation Processes
- 8.4: Mechanical Testing of Metals
- 8.5: Microstructural Examination
- 9: Electronics properties extended
- 9.1: Ferroelectric Materials
- 9.2: Piezoelectric Materials
- 9.3: Batteries
- 9.4: Fuel Cells
- 9.5: IC Manufacturing
- 9.5.1: Introduction to IC Manufacturing Technology
- 9.5.2: Silicon Growth
- 9.5.3: Doping
- 9.5.4: Fick's First Law
- 9.5.5: Fick's Second Law
- 9.5.6: Photolithography
- 9.5.7: Integrated Circuit Well and Gate Creation
- 9.5.8: Applying Metal/Sputtering
- 9.5.9: Integrated Circuit Manufacturing - A Bird's-Eye View
- 9.5.10: Diffused Resistor
- 9.5.11: Yield
- 10: Polymer Properties
- 10.1: Polymer Basics
- 10.1.1: Introduction
- 10.1.2: Naming Polymers
- 10.1.3: Shape, Size and Structure I
- 10.1.4: Polymer Chain Morphology
- 10.1.5: Shape, Size and Structure II
- 10.1.6: Stereoregularity
- 10.1.7: Copolymers
- 10.1.8: Crystallinity
- 10.1.9: Synthesis
- 10.1.10: Molecular Weight
- 10.1.11: Polymer Identification
- 10.1.12: Summary
- 10.1.13: Questions
- 10.2: Polymers and Plastics
- 10.3: Avoidance of Crystallization in Biological Systems
- 10.4: Polymer Chemistry
- 10.4.1: Polymer Chemistry- Chemical Composition
- 10.4.2: Polymer Chemistry- Experimental Methods
- 10.4.3: Polymer Chemistry- Isomerism
- 10.4.4: Polymer Chemistry- Mechanical Properties
- 10.4.5: Polymer Chemistry- Molecular Weight Averages
- 10.4.6: Polymer Chemistry- Morphology
- 10.4.7: Polymer Chemistry- Topology
- 10.4.8: Polymer Chemistry- Transitions
- 10.4.9: References
- 10.5: Crystallinity in polymers
- 10.6: The Glass Transition in Polymers
- 10.1: Polymer Basics
- 11: Advanced Mechanical Properties
- 12: New Page
- Back Matter
- Materials Science for Electrical Engineering
- pbmac
- Information Systems for Business
- Front Matter
- 1: Introduction to Information Systems?
- 2: Hardware
- 3: Software
- 4: Data and Databases
- 5: Networking and Communication
- 6: Information Systems Security
- 7: Does IT Matter?
- 8: Business Processes
- 9: The People in Information Systems
- 10: Information Systems Development
- 11: Globalization and the Digital Divide
- 12: The Ethical and Legal Implications of Information Systems
- 13: Future Trends in Information Systems
- Back Matter
- Information Systems for Business
- radwana@wwu.edu