This semester in lab we analyzed the trajectory of a basketball as it flew to the...

Finding the Spring Constant We can describe an oscillating mass in terms of its position, velocity,...

Finding the Spring Constant We can describe an oscillating mass in terms of its position, velocity, and acceleration as a function of time. We can also describe the system from an energy perspective. In this experiment, you will measure the position and velocity as a function of time for an oscillating mass and spring system, and from those data, plot the kinetic and potential energies of the system. Energy is present in three forms for the mass and spring system....

Revisiting the ballistic pendulum. In lab we used both conservation of momentum and conservation of energy...

Revisiting the ballistic pendulum. In lab we used both conservation of momentum and conservation of energy to relate the launch speed of a projectile to the maximum height of the swing of a pendulum. Here we will study the parts of this problem in a bit more detail. (a) Briefly explain why momentum is conserved during the collision of the projectile and the pendulum, but mechanical energy is not conserved. (b) Briefly explain why mechanical energy (kinetic plus potential energy)...

We did a lab where we leveled a horizontal track and used a massless frictionless pulley...

We did a lab where we leveled a horizontal track and used a massless frictionless pulley system with a weight to pull a cart and measured the potential vs kinetic energy of the closed system to find a slope of -1 when graphed. Why is leveling the track so important? How and why would your results be affected if the track were not level? If we did the experiment again and at the time that the cart is being pulled...

You hang a 300 g mass on a spring. a. If the spring initially stretches 6.20...

You hang a 300 g mass on a spring. a. If the spring initially stretches 6.20 cm when you hang the mass on it, what is the spring constant? b. How long will one oscillation take? The spring is now oriented horizontally and attached to a glider on a frictionless air track. The glider also has a mass of 300g. You want to observe the oscillations of this spring-mass system in the lab with a motion detector. You stretch the...

Consider the bead on a rotating circular hoop system that we saw in lecture. Recall that...

Consider the bead on a rotating circular hoop system that we saw in lecture. Recall that R is the radius of the hoop, ω is the angular velocity of rotation, and m is the mass of the bead that is constrained to be on the hoop as it rotates about the z-axis. We found that we could solve the constraints in terms of a single coordinate θ and that the Cartesian coordinates were given by x = −R sin(ωt)sinθ, y...

A quarterback is set up to throw the football to a receiver who is running with...

A quarterback is set up to throw the football to a receiver who is running with a constant velocity ~vr directly away from the quarterback and is now a distance D away from the quarterback. The quarterback estimates that the ball must be thrown at an angle θ to the horizontal and the receiver must catch the ball a time interval tc after it is thrown. Assume the ball is thrown and caught at the same height y = 0...

* i need part E , F, G , H You attach a 150 g mass...

* i need part E , F, G , H You attach a 150 g mass on a spring hung vertically. a. If the spring initially stretches 16 cm w... You attach a 150 g mass on a spring hung vertically. a. If the spring initially stretches 16 cm when you hang the mass on it, what is the spring constant? b. How long will one oscillation take? The spring is now oriented horizontally and attached to a glider on...

Learning Goal: To understand how to apply the law of conservation of energy to situations with...

Learning Goal: To understand how to apply the law of conservation of energy to situations with and without nonconservative forces acting. The law of conservation of energy states the following: In an isolated system the total energy remains constant. If the objects within the system interact through gravitational and elastic forces only, then the total mechanical energy is conserved. The mechanical energy of a system is defined as the sum of kinetic energy K and potential energy U. For such...

A particle with mass 2.61 kg oscillates horizontally at the end of a horizontal spring. A...

A particle with mass 2.61 kg oscillates horizontally at the end of a horizontal spring. A student measures an amplitude of 0.923 m and a duration of 129 s for 65 cycles of oscillation. Find the frequency, ?, the speed at the equilibrium position, ?max, the spring constant, ?, the potential energy at an endpoint, ?max, the potential energy when the particle is located 68.5% of the amplitude away from the equiliibrium position, ?, and the kinetic energy, ?, and...

do all five questions Question 1 20 pts Ignoring the effects of air resistance, if a...

do all five questions Question 1 20 pts Ignoring the effects of air resistance, if a ball falls freely toward the ground, its total mechanical energy Group of answer choices increases remains the same not enough information decreases Flag this Question Question 2 20 pts A child jumps off a wall from an initial height of 16.4 m and lands on a trampoline. Before the child springs back up into the air the trampoline compresses 1.8 meters. The spring constant...