Lesson 1 – Stationary Point Charges and Their Forces
Lesson 1 – Stationary Point Charges and Their Forces

Dynamics of the Elastic Pendulum
Dynamics of the Elastic Pendulum

clicking here
clicking here

... 20. One similarity of DNA and RNA is that they both contain a) Nucleotide b) ATP c) Thymine d) Deoxyribose sugar 21. One of the characteristics of all living things is that they a) Require oxygen for respiration b) Originate from preexisting life c) Carry on heterotrophic nutrition d) Carry on autot ...
PF1.5: WORK, ENERGY AND POWER
PF1.5: WORK, ENERGY AND POWER

... Objects may obey Hooke’s Law initially (the straight line section of the graph), but will reach a point where they becomes non linear (no longer proportional). This point is called the elastic limit of the spring and is shown by the X on the graph above. The object may start to stiffen, it could wea ...
Unit 6 Curvilinear Motion Particle Models
Unit 6 Curvilinear Motion Particle Models

Newton`s law universal gravitational
Newton`s law universal gravitational

... as the planet or satellite moves closer to the sun, the speed of its orbit increases, but when it is located farther away from the sun, the speed in which the planet or satellite revolves around the sun is slower. Free Powerpoint Templates ...
Fall 2005 MC Final Review
Fall 2005 MC Final Review

... E) The tension is greater than the weight of the rock. 50. A crate rests on the flatbed of a truck that is initially traveling at 15 m/s on a level road. The driver applies the brakes and the truck is brought to a halt in a distance of 38 m. If the deceleration of the truck is constant, what is the ...
Solutions to practice Exam II solved on the blackboard in class. 1
Solutions to practice Exam II solved on the blackboard in class. 1

...  ax=(mgSin15°-­‐  FCos30°+  μkN)/m=-­‐1.36m/s2=  1.  36m/s2  upwards.   ...
Electric Potential - McMaster Physics and Astronomy
Electric Potential - McMaster Physics and Astronomy

Linear Momentum and Collisions
Linear Momentum and Collisions

... This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their courses and assessing student learning. Dissemination or sale of any part of this work (including on the World Wide Web) will destroy the integrity of the work and is not permit ...
Lagrangian View of Control Volume
Lagrangian View of Control Volume

6 National Science Talent Contest (NSTC-6): Sample Paper 2008-2010
6 National Science Talent Contest (NSTC-6): Sample Paper 2008-2010

... 20. One similarity of DNA and RNA is that they both contain a) Nucleotide b) ATP c) Thymine d) Deoxyribose sugar 21. One of the characteristics of all living things is that they a) Require oxygen for respiration b) Originate from preexisting life c) Carry on heterotrophic nutrition d) Carry on autot ...
section file package!
section file package!

Sect. 8.2 - TTU Physics
Sect. 8.2 - TTU Physics

... • This statement includes the connections between the invariance or symmetry properties of the system & the conserved generalized momenta.  If the system is invariant (symmetrical) under uniform translation  A Linear momentum is conserved.  System is invariant (symmetrical) under uniform rotation ...
Lecture11-10
Lecture11-10

... ball with less mass has the greater speed, and thus the greater KE. In order to remove that KE, work must be done, where W = Fd. Because the force is the same in both cases, the distance needed to stop the less massive ball must be bigger. ...
221syllabusSum13 - Oakton Community College
221syllabusSum13 - Oakton Community College

... Friction, Dynamics of Uniform Circular Motion, Nonuniform Circular Motion, Velocity-Dependent Forces Newton’s Law of Universal Gravitation, Kepler’s Laws, The Gravitational Field Work, Work Done by a Constant Force, The Scalar (Dot) Product, Work Done by a Varying Force, Work-Kinetic Energy Theorem ...
Static Electricity
Static Electricity

... and q2 are of like charge - either both "+" or both "-". • The force value is negative (attractive) when q1 and q2 are of opposite charge - one is "+" and the other is "-". ...
CHAPTER 4 NEWTON`S LAWS • Little bit of history • Forces
CHAPTER 4 NEWTON`S LAWS • Little bit of history • Forces

... (downward) is balanced by the force of your hand on the cone (upward). No net force. 3 The total weight of you, the ice cream cone and the chair (downward) is balanced by the force of the ground on the chair legs (upward). No net force. ...
Linear momentum / Collisions
Linear momentum / Collisions

... - The center of mass lies somewhere between the two particles. - Choice of the reference origin is arbitrary  Shift of the coordinate system but center of mass is still at the same relative distance from each particle. ...
Physics Notes Class 11 CHAPTER 6 WORK, ENERGY
Physics Notes Class 11 CHAPTER 6 WORK, ENERGY

Uniform Circular Motion-1
Uniform Circular Motion-1

... Using words and a mathematical expression, describe the relationship between force and mass in uniform circular motion. Using words and a mathematical expression, describe the relationship between force and velocity in uniform circular motion. Using words and a mathematical expression, describe the ...
Chapter 6: Momentum and Collisions!
Chapter 6: Momentum and Collisions!

... Conservation of Momentum says that velocity has to come from somewhere. So…the moon ...
1. Newton`s first law of motion Any system in mechanical equilibrium
1. Newton`s first law of motion Any system in mechanical equilibrium

Microsoft Word - 12.800 Chapter 10 `06
Microsoft Word - 12.800 Chapter 10 `06

... exhausted its kinetic energy in climbing the pressure hill between θ = π/2 and θ =0. The pressure has acted as a potential field for the fluid motion and with the conservation of this potential and kinetic energy the fluid element is just able to traverse the rim of the cylinder. Although we have a ...
Section 1 Powerpoint
Section 1 Powerpoint

... the direction and strength of a force. The direction of the arrow represents the direction of the force. The length of the arrow represents the strength, or magnitude, of the force. ...

Classical central-force problem



In classical mechanics, the central-force problem is to determine the motion of a particle under the influence of a single central force. A central force is a force that points from the particle directly towards (or directly away from) a fixed point in space, the center, and whose magnitude only depends on the distance of the object to the center. In many important cases, the problem can be solved analytically, i.e., in terms of well-studied functions such as trigonometric functions.The solution of this problem is important to classical physics, since many naturally occurring forces are central. Examples include gravity and electromagnetism as described by Newton's law of universal gravitation and Coulomb's law, respectively. The problem is also important because some more complicated problems in classical physics (such as the two-body problem with forces along the line connecting the two bodies) can be reduced to a central-force problem. Finally, the solution to the central-force problem often makes a good initial approximation of the true motion, as in calculating the motion of the planets in the Solar System.