A standing wave’s function is y(x,t) = Asin(kx)cos(?t). Prove that this equation is indeed a solution...

Show that E(x,t) = Emax. Cos (kx – wt)      And B(x,t) = Bmax. Cos (kx...

Show that E(x,t) = Emax. Cos (kx – wt)      And B(x,t) = Bmax. Cos (kx – wt)      Are solutions to the Wave Equations

A common solution to the wave equation is E(x,t) = A ei(kx+wt). On paper take the...

A common solution to the wave equation is E(x,t) = A ei(kx+wt). On paper take the needed derivatives and show that it actually is a solution. Note that i is the square-root of -1. Upload a photograph of your work.

A standing wave on a string fixed at both ends is described by y(x,t)=2 sin((π/3)x)cos((π/3)t), where...

A standing wave on a string fixed at both ends is described by y(x,t)=2 sin((π/3)x)cos((π/3)t), where x and y are given in cm and time t is given in s. Answer the following questions a) Find the two simplest travelling waves which form the above standing wave b) Find the amplitude, wave number, frequency, period and speed of each wave(Include unit in the answer) c) When the length of the string is 12 cm, calculate the distance between the nodes...

Consider a monochromatic wave on a sting described by an equation Y(x,t) = cos (x -...

Consider a monochromatic wave on a sting described by an equation Y(x,t) = cos (x - t). Assume everything is expressed in SI units. a) Find wave amplitude b) Find wave velocity c) Find wave frequency d) Find wavelength

4 Schr¨odinger Equation and Classical Wave Equation Show that the wave function Ψ(x, t) = Ae^(i(kx−ωt))...

4 Schr¨odinger Equation and Classical Wave Equation Show that the wave function Ψ(x, t) = Ae^(i(kx−ωt)) satisfies both the time-dependent Schr¨odinger equation and the classical wave equation. One of these cases corresponds to massive particles, such as an electron, and one corresponds to massless particles, such as a photon. Which is which? How do you know?

A wave on a string is described by the equation y(x, t) = 2*cos(2 π(x/4m- t...

A wave on a string is described by the equation y(x, t) = 2*cos(2 π(x/4m- t /.1 s)) where x is in meters and t is in seconds. a. Is the wave travelling to the right or to the left? _________ b. What is the wave frequency? __________ c. What is the wavelength? ___________ d. What is the wave speed? _________ e. At t=0.50 seconds what is the displacement of the string at x=0.20 meters. _________

A wave on a string is described by the equation y(x,t)=3.0 cm*〖cos(〗⁡〖2π*(x/2.4m+t/(0.2 s)))〗 . X is...

A wave on a string is described by the equation y(x,t)=3.0 cm*〖cos(〗⁡〖2π*(x/2.4m+t/(0.2 s)))〗 . X is in meters and t is in seconds. Is the wave travelling to the right or to the left? _________ What is the wave speed? _________ What is the wave frequency? __________ What is the wavelength? ___________ At t=0.50 seconds what is the displacement of the string at x=0.20 meters. _________

What is the wavelength of a wave described by the following function: y(x,t) = (2.00 m)cos[(3.00...

What is the wavelength of a wave described by the following function: y(x,t) = (2.00 m)cos[(3.00 m-1)x + (5.00 s-1)t]

a)Prove that the function u(x, y) = x -y÷x+y is harmonic and obtain a conjugate function...

a)Prove that the function u(x, y) = x -y÷x+y is harmonic and obtain a conjugate function v(x, y) such that f(z) = u + iv is analytic. b)Convert the integral from 0 to 5 of (25-t²)^3/2 dt into a Beta Function and evaluate the resulting function. c)Solve the first order PDE sin(x) sin(y) ∂u ∂x + cos(x) cos(y) ∂u ∂y = 0 such that u(x, y) = cos(2x), on x + y = π 2

Consider the differential equation: F = ma where F = -kx + ? cos (?? )...

Consider the differential equation: F = ma where F = -kx + ? cos (?? ) and ?=√(k/m). If x = Acos(?t), solve for A in terms of ?, m, ?, and ?. Make a sketch of A versus ? graph