For a particle in a central field, apply Hamilton canonical equation, in polar coordinates, to prove...

A particle moves in a potential field,let V(z)be the potential energy function,V(z)=kz, use the cylindrical coordinates...

A particle moves in a potential field,let V(z)be the potential energy function,V(z)=kz, use the cylindrical coordinates as general coordinates. (1)Determine the Lagrangian for this particle. (2)Calculate the generalized impulse for this particle. (3)Determine the Hamiltonian and the equation of motions for this particle. (4)Determine the conserved quantity of this system.

To write Laplace’s equation, Uxx + Uyy = 0, in polar coordinates, we begin with Ux...

To write Laplace’s equation, Uxx + Uyy = 0, in polar coordinates, we begin with Ux = (∂U/∂r)(∂r/∂x) + (∂U/∂θ)(∂θ/∂x) where r = √(x2+y2), θ = arctan (y/x), x = r cos θ, y = r sin θ. We get Ux = (cos θ) Ur – (1/r)(sin θ) Uθ , Uxx = [∂(Ux)/∂r] (∂r/∂x) + [∂(Ux)/∂θ](∂θ/∂x) Carry out this computation, as well as that for Uyy. Since Uxx and Uyy are both expressed in polar coordinates, their sum gives Laplace...

For a non-relativistic particle of mass m and charge q in an electromagnetic field, the Lagrangian...

For a non-relativistic particle of mass m and charge q in an electromagnetic field, the Lagrangian function is given by L = (m /2) v · v − q(φ − v · A). Show that the Hamiltonian can be written as H = (1 /2) (p − qA) · (p − qA) + qφ, where p is the canonical momentum.For a non-relativistic particle of mass m and charge q in an electromagnetic field, the Lagrangian function is given by L...

A particle of mass m is projected with an initial velocity v0 in a direction making...

A particle of mass m is projected with an initial velocity v0 in a direction making an angle α with the horizontal level ground as shown in the figure. The motion of the particle occurs under a uniform gravitational field g pointing downward. (a) Write down the Lagrangian of the system by using the Cartesian coordinates (x, y). (b) Is there any cyclic coordinate(s). If so, interpret it (them) physically. (c) Find the Euler-Lagrange equations. Find at least one constant...

verify that the polar coordinates (-4, pi/2) satisfies the equation r=4sin3theta and sketch a graph of...

verify that the polar coordinates (-4, pi/2) satisfies the equation r=4sin3theta and sketch a graph of the equation r=4sin3theta and locate the point from above and approximate the location of any vertical tangent lines

A particle moves in a potential field V(r,z)=az/r, a is constant. Use the cylindrical coordinates as...

A particle moves in a potential field V(r,z)=az/r, a is constant. Use the cylindrical coordinates as the general coordinates. 1)Determine the Lagrangian of this particle. 2)Calculate the generalized impulse. 3)Determine the Hamiltonian of this particle and the Hamiltonian’s equations of motion. 4)Determine the conserved quatities of this system.

Write each equation in polar coordinates. Then isolate the variable r when possible 3x+5y-2=0

Write each equation in polar coordinates. Then isolate the variable r when possible 3x+5y-2=0

Let us consider a particle of mass M moving in one dimension q in a potential...

Let us consider a particle of mass M moving in one dimension q in a potential energy field, V(q), and being retarded by a damping force −2???̇ proportional to its velocity (?̇). - Show that the equation of motion can be obtained from the Lagrangian: ?=?^2?? [ (1/2) ??̇² − ?(?) ] - show that the Hamiltonian is ?= (?² ?^−2??) / 2? +?(?)?^2?? Where ? = ??̇?^−2?? is the momentum conjugate to q. Because of the explicit dependence of...