Chapter 06 Test B
... 5. The law of conservation of energy can be used to predict motion of interacting objects after they collide. _________________________ ...
... 5. The law of conservation of energy can be used to predict motion of interacting objects after they collide. _________________________ ...
magnetic field.
... The south pole of the small bar magnet is attracted towards the north pole of the big magnet. Also, the small bar magnet (a magnetic dipole) wants to align with the B-field. The field attracts and exerts a torque on the small magnet. ...
... The south pole of the small bar magnet is attracted towards the north pole of the big magnet. Also, the small bar magnet (a magnetic dipole) wants to align with the B-field. The field attracts and exerts a torque on the small magnet. ...
momentum is conserved
... A 2.0 kg ball, A, is moving at a velocity of 5.0 m/s. It collides with a stationary ball, B, also of mass 2.0 kg. After the collision, ball A moves off in a direction 300 to the left of its original direction. Ball B moves off in a direction 900 to the right of ball A’s final direction. a. Draw a v ...
... A 2.0 kg ball, A, is moving at a velocity of 5.0 m/s. It collides with a stationary ball, B, also of mass 2.0 kg. After the collision, ball A moves off in a direction 300 to the left of its original direction. Ball B moves off in a direction 900 to the right of ball A’s final direction. a. Draw a v ...
Kinetic Friction Experiment
... 3. Place the wood side of the block against the track and add 500 g of mass on top of the friction block. (What is the mass that will now slide along the track?) The block should be at least 30 cm in front of the motion sensor. 4. Attach a pulley as shown in Figure 2. Place the larger area wood sur ...
... 3. Place the wood side of the block against the track and add 500 g of mass on top of the friction block. (What is the mass that will now slide along the track?) The block should be at least 30 cm in front of the motion sensor. 4. Attach a pulley as shown in Figure 2. Place the larger area wood sur ...
charged geosynchronous debris perturbation
... and Eddy current effects on the orbit. As a result, the charged objects’ orbit is shown to differ relative to the uncharged one by nearly a tenth of a degree in inclination and 0.002 in eccentricity after only 12 hours. However, electrostatic torques were not modeled in this earlier work, as the Myl ...
... and Eddy current effects on the orbit. As a result, the charged objects’ orbit is shown to differ relative to the uncharged one by nearly a tenth of a degree in inclination and 0.002 in eccentricity after only 12 hours. However, electrostatic torques were not modeled in this earlier work, as the Myl ...
ECE 3300 Portfolio 1..
... For each point in 2-D or 3-D space vectors as they are defined, will have a magnitude and direction. For example, if we have an equation for E , it will be a vector that acts a s a function of x, y and z or whatever coordinate system applies. As we “plug-in” different values of x, y, and z, a vector ...
... For each point in 2-D or 3-D space vectors as they are defined, will have a magnitude and direction. For example, if we have an equation for E , it will be a vector that acts a s a function of x, y and z or whatever coordinate system applies. As we “plug-in” different values of x, y, and z, a vector ...
Stacey Carpenter - University of Hawaii
... The constant of proportionality was later determined experimentally. It is called G. G = 6.710-11 m3/(kgs2) You can use G to calculate the gravitational force between two objects if you know their masses and the distance between their centers of mass. F = Gm1m2/d2 The units for G work with m1m2 ...
... The constant of proportionality was later determined experimentally. It is called G. G = 6.710-11 m3/(kgs2) You can use G to calculate the gravitational force between two objects if you know their masses and the distance between their centers of mass. F = Gm1m2/d2 The units for G work with m1m2 ...
Exercises – Chapter 3
... E.18 During a head-on collision, the relative velocity is enormous--the sum of the two individual velocities--and the forces, accelerations, and momentum transfers are enormous as well. 19. When two trains are traveling side by side at breakneck speed, it’s still possible for people to jump from one ...
... E.18 During a head-on collision, the relative velocity is enormous--the sum of the two individual velocities--and the forces, accelerations, and momentum transfers are enormous as well. 19. When two trains are traveling side by side at breakneck speed, it’s still possible for people to jump from one ...
chapter13
... • The force and acceleration start to increase in the opposite direction and velocity decreases • The motion momentarily comes to a stop at x=-A • It then accelerates back toward the equilibrium position • The motion continues indefinitely ...
... • The force and acceleration start to increase in the opposite direction and velocity decreases • The motion momentarily comes to a stop at x=-A • It then accelerates back toward the equilibrium position • The motion continues indefinitely ...
