Introduction to Circular Motion
... in a straight line. If you are sitting on the passenger side of the car, then eventually the outside door of the car will hit you as the car turns inward. In reality, you are continuing in your straight-line inertial path tangent to the circle while the car is accelerating out from under you. It is ...
... in a straight line. If you are sitting on the passenger side of the car, then eventually the outside door of the car will hit you as the car turns inward. In reality, you are continuing in your straight-line inertial path tangent to the circle while the car is accelerating out from under you. It is ...
Mechanics II - Thierry Karsenti
... Furthermore the learner will be able to calculate the kinetic energy of rotation of a rotating rigid body and use this as an additional form of kinetic energy in solving problems using the conservation of energy. ...
... Furthermore the learner will be able to calculate the kinetic energy of rotation of a rotating rigid body and use this as an additional form of kinetic energy in solving problems using the conservation of energy. ...
ch4Fieldwithdipole
... a. How far apart of the two charges? b. What is the maximum torque that the external field can exert? c. How much work must the field do to turn the dipole end to end (0 to 180)? 2. An electric dipole with charges of +/- 1.5E-9C is separated by 6.2E-6m and placed in an electric field of strength 1 ...
... a. How far apart of the two charges? b. What is the maximum torque that the external field can exert? c. How much work must the field do to turn the dipole end to end (0 to 180)? 2. An electric dipole with charges of +/- 1.5E-9C is separated by 6.2E-6m and placed in an electric field of strength 1 ...
Centripetal Force
... acceleration and tangential velocity. compare and contrast the directions of the centripetal force, centripetal acceleration, and tangential velocity. calculate centripetal force and centripetal acceleration. compare universal gravitational force between objects with different distances using the ...
... acceleration and tangential velocity. compare and contrast the directions of the centripetal force, centripetal acceleration, and tangential velocity. calculate centripetal force and centripetal acceleration. compare universal gravitational force between objects with different distances using the ...
ME 101: Engineering Mechanics
... Change in any of the three specifications will alter the effect on the bracket. Force is a Fixed Vector In case of rigid bodies, line of action of force is important (not its point of application if we are interested in only the resultant external effects of the force), we will treat most forces as ...
... Change in any of the three specifications will alter the effect on the bracket. Force is a Fixed Vector In case of rigid bodies, line of action of force is important (not its point of application if we are interested in only the resultant external effects of the force), we will treat most forces as ...
SOLID MECHANICS BALANCING TUTORIAL
... simply involves moving the centre of gravity to the centre of rotation but as we shall see, for longer and more complex bodies, there is more to it. For a body to be completely balanced it must have two things. 1. Static Balance. This occurs when there is no resultant centrifugal force and the centr ...
... simply involves moving the centre of gravity to the centre of rotation but as we shall see, for longer and more complex bodies, there is more to it. For a body to be completely balanced it must have two things. 1. Static Balance. This occurs when there is no resultant centrifugal force and the centr ...
2008 Quarter-Final Exam Solutions
... (a) Consider an axis perpendicular to the initial impulse and coplanar with the table. (Throughout this solution we consider only torques and angular momenta with respect to this axis.) After the initial impulse, the torque about this axis is always zero, so angular momentum is conserved. The initia ...
... (a) Consider an axis perpendicular to the initial impulse and coplanar with the table. (Throughout this solution we consider only torques and angular momenta with respect to this axis.) After the initial impulse, the torque about this axis is always zero, so angular momentum is conserved. The initia ...
Physics - Units and Dimensions
... LIMITATIONS OF DIMENSIONAL ANALYSIS (i) Dimension does not depend on the magnitude. Due to this reason the equation x = ut + at 2 is also dimensionally correct. Thus, a dimensionally correct equation need not be actually correct. (ii) The numerical constants having no dimensions connot be deduced by ...
... LIMITATIONS OF DIMENSIONAL ANALYSIS (i) Dimension does not depend on the magnitude. Due to this reason the equation x = ut + at 2 is also dimensionally correct. Thus, a dimensionally correct equation need not be actually correct. (ii) The numerical constants having no dimensions connot be deduced by ...
1 Work, Power, and Machines
... jacks to lift cars off the ground. A person applies a light, downward input force to the handle of the jack. The jack changes the input force into a stronger, upward force, the output force. The output force lifts the car. In this way, a person can lift a very heavy car. It may seem that changing a ...
... jacks to lift cars off the ground. A person applies a light, downward input force to the handle of the jack. The jack changes the input force into a stronger, upward force, the output force. The output force lifts the car. In this way, a person can lift a very heavy car. It may seem that changing a ...
Thursday, Sept. 8, 2011
... speed v0 near the negative plate and passes through a tiny hole in the positive plate. – Derive the formula for the electric field E to accelerate the charged particle to fraction f of the speed of light c. Express E in terms of M, Q, D, f, c and v0. – (a) Using the Coulomb force and kinematic equat ...
... speed v0 near the negative plate and passes through a tiny hole in the positive plate. – Derive the formula for the electric field E to accelerate the charged particle to fraction f of the speed of light c. Express E in terms of M, Q, D, f, c and v0. – (a) Using the Coulomb force and kinematic equat ...
Lecture Notes for College Physics I
... The tendency of a body to maintain its state of rest or of uniform linear motion (i.e., constant velocity) is called inertia. The physical measurement of inertia is called mass. • Newton’s Second Law of Motion ...
... The tendency of a body to maintain its state of rest or of uniform linear motion (i.e., constant velocity) is called inertia. The physical measurement of inertia is called mass. • Newton’s Second Law of Motion ...
