Find the Hamiltonian for a mass m confined to the x axis and subject to a...

In Hamiltonian Mechanics in the phase space specifically, why is it not possible for two orbits...

In Hamiltonian Mechanics in the phase space specifically, why is it not possible for two orbits to intersect? Does the theorem state that the two orbits can't intersect at the same time or at all times ? one way I imagine that is if I have 2 1D objects subject to a net force = 0, if both have the exact same momenta and different positions, as the two systems evolve with time, wouldn't the two orbits at some point...

An object on a spring is subject to a drag force that is linear with velocity....

An object on a spring is subject to a drag force that is linear with velocity. The mass is 0.5 kg, the drag force constant is 3 kg/s, and the spring constant is 2.5 N/m. a. Find the equation of motion x(t). b. Sketch a graph of x(t). c. Describe the motion in words.

An object on a spring is subject to a drag force that is linear with velocity....

An object on a spring is subject to a drag force that is linear with velocity. The mass is 2 kg, the drag force constant is 4 kg/s, and the spring constant is 2.5 N/m. a. Find the equation of motion x(t). b. Sketch a graph of x(t). c. Describe the motion in words.

classical Mechanics problem: Suppose some particle of mass m is confined to move, without friction, in...

classical Mechanics problem: Suppose some particle of mass m is confined to move, without friction, in a vertical plane, with axes x horizontal and y vertically up. The plane is forced to rotate with angular velocity of magnitude Ω about the y axis. Find the equation of motion for x and y, solve them, and describe the possible motions. This is not meant to be a lagrangian problem.

analytical mechanics seventh edition p.141 3.24 let a particle of unit mass be subject to a...

analytical mechanics seventh edition p.141 3.24 let a particle of unit mass be subject to a force x-x^3 where x is its displacement from the coordinate origin (a) Find the equilibrium points, and tell whether they are stable or unstable (b) Calculate the total energy of the particle, and show that it is a conserved quantity (c) Calculate the trajectories of the particle in phase space

I have a bar of length L and mass M. It lies on the x-axis with...

I have a bar of length L and mass M. It lies on the x-axis with the left end at the origin. Find the gravitational force on a point mass m at a position x = a (a > L). Show your work. Set up the integral but do not evaluate it.

A point charge of +10 μC is at (+3 m, 0 m) on the x-axis and...

A point charge of +10 μC is at (+3 m, 0 m) on the x-axis and a point charge of +10 μC is at (-3 m,0 m). a. Determine the work required to assemble this charge distribution. W = ________ J b. Find the magnitude of the electric field at a point (0,+3 m) on the y-axis. E = __________ x103 N/C A charge q = +1 μC is placed at this point. Find the magnitude of the force on...

mass of 2kg moves horizontally along x axis under the action of a force in terms...

mass of 2kg moves horizontally along x axis under the action of a force in terms of time, given as following: F(t) = b sin wt , where t time in seconds , b and w are constants 1) find the impulse during t1=0 to t2=2 if the mass starts motion from rest at x=0 (Show in integration IN DETAIL) 2) find its velocity as function of time (IN DETAIL) 3) find its position as function of time (IN DETAIL)

Particles of mass m are incident from the positive x axis (moving to the left) onto...

Particles of mass m are incident from the positive x axis (moving to the left) onto a potential energy step at x=0. At the step the potential energy drops from the positive value U_0 for all x>0 to the value 0 for all x<0. The energy of the particles is greater than U_0. A) Sketch the potential energy U(x) for this system. B) How would the wavelength of a particle change in the x<0 region compared to the x>0 region?...

The position of a particle confined to move on an axis varies according to the equation...

The position of a particle confined to move on an axis varies according to the equation x(t)=at3 -bt-c where a=2m/s3 , b=4m/s, c=10 m. Draw the graph of the motion, then find the following: a) the average velocity between t1=0 and t2=2s. b) the instantaneous velocity and acceleration functions, c) the instantaneous velocity and acceleration at t=4 sec. d) the time when the partite stops momentarily,