Determining the Drag Coefficient for a Ping Pong Ball
Determining the Drag Coefficient for a Ping Pong Ball

... Typically, the reference area A for simple shapes, such as a sphere, is exactly the same as a cross sectional area. For other objects (for instance, a rolling tube or the body of a cyclist), A may be significantly larger than the area of any cross section along any plane perpendicular to the directi ...
Physics C: Mechanics - Piscataway High School
Physics C: Mechanics - Piscataway High School

... (c) Relate the work done by a force to the area under a graph of force as a function of position, and calculate this work in the case where the force is a linear function of position. 2. Understand the work-energy theorem so they can: (a) Calculate the change in kinetic energy or speed that results ...
Linear momentum - Gymnázium Slovanské náměstí
Linear momentum - Gymnázium Slovanské náměstí

... III/2 – Inovace a zkvalitnění výuky prostřednictvím ICT ...
L5N - University of Iowa Physics
L5N - University of Iowa Physics

Motion in one and two dimensions
Motion in one and two dimensions

lg-ch6-2-kw
lg-ch6-2-kw

... why the red and blue hexagons are not similar. The red hexagon has all sides congruent, but the blue hexagon has 3 shorter sides and 3 longer sides, so ratios of corresponding side lengths are not constant. ...
PPTX
PPTX

Vectors
Vectors

Solutions Guide - Blue Valley Schools
Solutions Guide - Blue Valley Schools

Coriolis Force
Coriolis Force

... Conservation of absolute angular momentum. Consider a parcel of air or water with constant mass, m, moving with constant speed, v, in a circular orbit. According to Newton’s second law, the parcel must conserve absolute angular momentum (i.e., angular momentum in the absolute frame of reference). Th ...
Stress, Strain, Virtual Power and Conservation Principles
Stress, Strain, Virtual Power and Conservation Principles

... Scalars, vectors and tensors are mathematical entities that are used in applications to represent meaningful physical quantities. Consider two systems of coordinates ui and ui which are related by the coordinate transformation rules described above. Physical quantities of interest can be represente ...
Pre-Calculus
Pre-Calculus

MENU_2016--Valery_Lyuboshitz
MENU_2016--Valery_Lyuboshitz

ÿþK i n e m a t i c s S o l u t i o n s
ÿþK i n e m a t i c s S o l u t i o n s

AST1100 Lecture Notes
AST1100 Lecture Notes

FACULTY OF SCIENCE SAMPLE FINAL EXAMINATION PHYSICS 198-101A (2000) MECHANICS AND WAVES
FACULTY OF SCIENCE SAMPLE FINAL EXAMINATION PHYSICS 198-101A (2000) MECHANICS AND WAVES

Conservation Of Momentum
Conservation Of Momentum

Levers Information
Levers Information

Answers to Practice Problems for Exam #1
Answers to Practice Problems for Exam #1

Projectile and Circular Motion Review Packet
Projectile and Circular Motion Review Packet

Chapter5-Matter in Motion
Chapter5-Matter in Motion

... with a reference point Reference point: ____________________________________________ Place that appears to stay in place when compared _______________________________________________ to an object in motion. Common Reference Points: The Earth’s surface 1. _____________________________ 2. ____________ ...
Classical Field Theory - Uwe
Classical Field Theory - Uwe

the Note
the Note

( ) 13.0m / s ( ( ) 8.0m / s ( ( ) 8m / s ( ( ) 7.2m / s (
( ) 13.0m / s ( ( ) 8.0m / s ( ( ) 8m / s ( ( ) 7.2m / s (

1st Semester Review
1st Semester Review

... 1. What is the difference between distance and displacement. Explain difference between average and instantaneous velocities and speeds 2. Provide a scenario in which the average speed of a runner is greater than its instantaneous speed. Define in words, and equation: average and instantaneous, velo ...

Derivations of the Lorentz transformations

There are many ways to derive the Lorentz transformations utilizing a variety of mathematical tools, spanning from elementary algebra and hyperbolic functions, to linear algebra and group theory.This article provides a few of the easier ones to follow in the context of special relativity, for the simplest case of a Lorentz boost in standard configuration, i.e. two inertial frames moving relative to each other at constant (uniform) relative velocity less than the speed of light, and using Cartesian coordinates so that the x and x′ axes are collinear.