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... straight line if the initial velocity has no component along the electric field but has a component equal to the electromagnetic drift velocity in the direction orthogonal to both the electric and magnetic fields. In the general case of electric and magnetic fields of arbitrary orientation, the moti ...
... straight line if the initial velocity has no component along the electric field but has a component equal to the electromagnetic drift velocity in the direction orthogonal to both the electric and magnetic fields. In the general case of electric and magnetic fields of arbitrary orientation, the moti ...
Section 6.5 – Variation I. Direct Variation II. Inverse Variation
... In solving variation problems it’s good to have a strategy. a. Write a variation equation given a description and creates a table of values. b. Find the constant of proportionality given values of the variables and restate your equation. c. If necessary, find the specified quantity asked for using y ...
... In solving variation problems it’s good to have a strategy. a. Write a variation equation given a description and creates a table of values. b. Find the constant of proportionality given values of the variables and restate your equation. c. If necessary, find the specified quantity asked for using y ...
Mechanics - Modeling Instruction Program
... the center of mass. They determine the conditions necessary to balance a meterstick. The lab takes one class period.) Moment of inertia of a disk (Hands on lab where string is wrapped around a solid disk. Weights are hung on the end of the string and cause the disk to rotate with a constant angular ...
... the center of mass. They determine the conditions necessary to balance a meterstick. The lab takes one class period.) Moment of inertia of a disk (Hands on lab where string is wrapped around a solid disk. Weights are hung on the end of the string and cause the disk to rotate with a constant angular ...
Turntables PPT - Physics of Theatre Home
... td tnet+tf1+tf2=Ia+tf1+tf2 So, to determine the drive torque, we need to find the moment of inertia, the angular acceleration, and the frictional torques. ...
... td tnet+tf1+tf2=Ia+tf1+tf2 So, to determine the drive torque, we need to find the moment of inertia, the angular acceleration, and the frictional torques. ...
The Parallel-Plate Capacitor Electric Potential Energy
... where s is measured from the negative plate and U0 is the potential energy at the negative plate (s = 0). It will often be convenient to choose U0 = 0, but the choice has no physical consequences because it doesn’t affect ΔUelec, the change in the electric potential energy. Only the change is ...
... where s is measured from the negative plate and U0 is the potential energy at the negative plate (s = 0). It will often be convenient to choose U0 = 0, but the choice has no physical consequences because it doesn’t affect ΔUelec, the change in the electric potential energy. Only the change is ...
unit 6: gravity and projectile motion
... (c) Use the inertial mass measurement from the last lab to compare the masses of the steel object and the tennis ball. mrubber = _________ kg msteel = _________ kg (d) Although you only made a casual qualitative observation of the objects you dropped, it turns out that in the absence of air resistan ...
... (c) Use the inertial mass measurement from the last lab to compare the masses of the steel object and the tennis ball. mrubber = _________ kg msteel = _________ kg (d) Although you only made a casual qualitative observation of the objects you dropped, it turns out that in the absence of air resistan ...
Gravitation
... earth’s gravitational force. Therefore, this acceleration is called the acceleration due to the gravitational force of the earth (or acceleration due to gravity). It is denoted by g. The unit of g is the same as that of acceleration, that is, m s–2. We know from the second law of motion that force i ...
... earth’s gravitational force. Therefore, this acceleration is called the acceleration due to the gravitational force of the earth (or acceleration due to gravity). It is denoted by g. The unit of g is the same as that of acceleration, that is, m s–2. We know from the second law of motion that force i ...
W = Fd W = ΔE Ep = mgh (gravitational) Ep = Fd (springs etc) Ek
... Kinetic Energy: 1) How much kinetic energy does a 50.0 g bullet traveling at 365 m/s have? 2) If a 78 kg cheetah is running at a speed of 120 km/h, how much kinetic energy does it have? 3) A 3.91 N baseball has 775 J of kinetic energy. How fast is it moving? 4) A 0.425 kg water balloon is dropped f ...
... Kinetic Energy: 1) How much kinetic energy does a 50.0 g bullet traveling at 365 m/s have? 2) If a 78 kg cheetah is running at a speed of 120 km/h, how much kinetic energy does it have? 3) A 3.91 N baseball has 775 J of kinetic energy. How fast is it moving? 4) A 0.425 kg water balloon is dropped f ...
Lect15
... • Circulation is an important concept in fluid mechanics: it is circulation which (together with onset of flow speed) develops lift (Magnus Force) on a spinning cylinder, spinning cricket ball and an aerofoil section. • In potential flow, line vortex is used to model circulation that occurs in real ...
... • Circulation is an important concept in fluid mechanics: it is circulation which (together with onset of flow speed) develops lift (Magnus Force) on a spinning cylinder, spinning cricket ball and an aerofoil section. • In potential flow, line vortex is used to model circulation that occurs in real ...