Physics for Science and Engineering II (UMKC) by Jerzy Wrobel

# click the up-left corner to select videos from the playlist

source: UMKC 　　2009年8月27日
Physics 250:Physics for Science and Engineering II (UMKC)
This course is being offered by UMKC's Physics Department. For interested students - The live classroom uses the following textbook - Physics for Scientists and Engineers, 7th edition, by R.A. Serway & J.W. Jewett, Jr.. This course is being taught by Professor Jerzy Wrobel

Lecture 1 - Electrostatic Interaction 50:12
Lecture 2 - Electric Field Vector 48:08
Lecture 3 - Gauss's Law & Coulomb's Law 47:18
Lecture 4 - Charge, density and the electric field of an extended body 42:50
Lecture 5 - Electric Fields 41:35
Lecture 6 - Electric Potential 41:57
Lecture 7 - Calculating Electric Potential 50:49
Lecture 8 - Substance in an electric field 42:59
Lecture 9 - Capacitors 1:00:36
Lecture 10 - Parallel Plate Capacitor 42:10
Lecture 11 - Systems of Capacitors 44:42
Lecture 12 - Electric Current 46:34
Lecture 13 - Resistors 44:09
Lecture 14 - Systems of Resistors 46:40
Lecture 15 -Sources of Electromotive Force 47:12
Lecture 16 - Kirchoff's Rules 46:10
Lecture 17 - Applications of Kirchhoffs Rules 42:24
Lecture 18 - Charging and Discharging a Capacitor 43:46
Lecture 19 - Sinusoidal Alternating Current 45:04
Lecture 20 - Relation between Current and Voltage 51:59
Lecture 21 - Complex Impedance 32:05
Lecture 22 - AC in Resistors, Capacitors and Inductors 45:04
Lecture 23 - Applications of RLC circuits 33:22
Lecture 24 - Applications of RLC circuits 47:49
Lecture 25 - More Applications of RLC circuits 45:17
Lecture 26 - Semiconductor Devices 47:25
Lecture 27 - Transistor Circuits 52:08
Lecture 28 - Magnetic Interaction 44:39
Lecture 29 - Magnetic interaction 46:26
Lecture 30 - Current carrying wire in a magnetic field 45:02
Lecture 31 - Magnetic Torque 48:02
Lecture 32 - Maxwell's Equations 41:27
Lecture 33 - Magnetic Field produced by Electric Currents 45:09
Lecture 34 - Faradays Law of Induction 43:47
Lecture 35 - Self-induction 44:58
Lecture 36 - Wave nature of Electromagnetic Radiation 47:14
Lecture 37 - Law of Refraction and Law of Reflection 40:46
Lecture 38 - Image Formation 42:40
Lecture 39 - Spherical Mirrors 49:43
Lecture 40 - Ray Diagrams and Mirror Equation 31:32
Lecture 41 - Thin Spherical Lenses 43:54
Lecture 42 - The eye 51:01
Lecture 43 - System of Lenses 45:57
Lecture 44 - Optical Instruments 44:17
Lecture 45 - Designing Optical Systems 47:37
Lecture 46 - Light and Vision 48:21
Lecture 47 - Demonstration of Interference 40:00
Lecture 48 - Theory of Interference 44:27
Lecture 49 - Designing Optical Systems 44:41
Lecture 50 51:15
Lecture 51 - Final Lecture for this series 46:22

Physics for Science and Engineering I (UMKC) by Jerzy Wrobel

# click the up-left corner to select videos from the playlist

source: UMKC        2014年6月24日
Physics 240: Physics for Science and Engineering course is being offered by UMKC's Physics Department. The course, lectured by Professor Jerzy Wrobel, is based on the 8th edition of a textbook Physics for Scientists and Engineers authored R.A. Serway & J.W. Jewett, Jr.

Lecture 1 44:11
Lecture 2 - Introduction to Physics 48:28
Lecture 3 - Scalar Quantities 49:09
Lecture 4 - Area, Volume & Density 46:57
Lecture 5 - Vectors 45:03
Lecture 6 - Scalar Product and Cartesian Coordinate System 43:15
Lecture 7 - Vector Quantities 0:52
Lecture 8 - Velocity and Acceleration 48:04
Lecture 9 - Motion with Constant Velocity 37:20
Lecture 10 - Motion with Constant Acceleration 47:22
Lecture 11 - Inverse Relations 46:50
Lecture 12 - Galilean Transformation 48:34
Lecture 13 - Laws of Motion 39:34
Lecture 14 - Laws of Motion 46:23
Lecture 15 - Laws of Motion 40:20
Lecture 16 - Laws of Motion 47:31
Lecture 17 - Uniform Circular Motion 43:06
Lecture 18 - Inertial Forces 52:21
Lecture 19 - Inertial Forces 39:56
Lecture 20 - Newtons Second Law in a non-Inertial Reference Frame 41:24
Lecture 21 - The Work-Energy Theorem (v.1) 50:08
Lecture 22 47:52
Lecture 23 - Mechanical Energy 43:44
Lecture 24 - Applications of the Work-Energy Theorem 41:30
Lecture 25 - Relation between Descriptions of Interaction and Descriptions of Motion 50:54
Lecture 26 - Impulse-Momentum Theorem 41:54
Lecture 27 - Conservation of Total Momentum 46:07
Lecture 28 - Center of Mass 49:35
Lecture 29 45:44
Lecture 30 48:03
Lecture 31 46:55
Lecture 32 - Angular Momentum and Torque 28:43
Lecture 33 - Center of Force and Rigid Body 44:35
Lecture 34 -Total Angular Momentum of a Rigid Body 44:21
Lecture 35 44:51
Lecture 36 - Kinetic Energy of a Rigid Body 48:17
Lecture 37 -Application of Newtons Second Law 37:54
Lecture 38 - - Application of Newtons Second Law for the Analysis 48:13
Lecture 39 - Internal Interactions 48:36
Lecture 40 - Hooks Law 47:49
Lecture 41 - Liquid In Equilibrium 44:51
Lecture 42 - Archimedes Principle and Bernoullis Equation 43:45
Lecture 43 44:07
Lecture 43 - Concept of Heat Transfer 47:46
Lecture 44 - Heat Capacity 41:32
Lecture 45 - Thermodynamic Processes 52:57
Lecture 46 - The First Law of Thermodynamics 42:27
Lecture 47 - Microscopic Model of an Ideal Gas 43:54
Lecture 48 - Entropy 43:14
Lecture 49 - Second Law of Thermodynamics 47:27
Lecture 50 - Consequences of the Second Law of Thermodynamics 46:02
Lecture 51 - Review of Concepts 54:15