How to Prove ∫ ψ1(x)*ψ2(x) dx = ∫φ1(k)*φ2(k) dk?

MrPhoton
Messages
2
Reaction score
0

Homework Statement


Show that ∫ ψ1(x)*ψ2(x) dx = ∫φ1(k)*φ2(k) dk

(Where the integrations are going from -∞ to ∞)

Homework Equations


1. Plancherel Theorem: ψ(x) = 1/√2π∫φ(k)eikx dk ⇔ φ(k) = 1/√2π∫ψ(x)e-ikx dx

The Attempt at a Solution


It is clear that Plancherel's theorem must be used to solve this.

We also know by the properties of a wavefunction, that the inner product is orthogonal therefore equal to 0.

Since I know the inner product on the right hand will be 0, I am not quite sure how to show that the left hand side is also equal to the right hand side. (I assume the 1/√2π factors will be removed by the inner product being 0?)
 
Physics news on Phys.org
MrPhoton said:
ψ(x) = 1/√2π∫φ(k)eikx dk
Just plug in the above relation for ##\psi_1## and ##\psi_2## in the left hand side of the relation to be proved.
 
ψ1(x)* = 1/√2π∫φ*(k)e-ikx dk
ψ2(x) = 1/√2π∫φ(k)eikx dk

Therefore applying LHS of Initial equation, we get:

∫ ψ1(x)*ψ2(x) dx = 1/2π∫φ*(k)e-ikx φ(k)eikx dk
∫ ψ1(x)*ψ2(x) dx = 1/2π∫φ*(k) φ(k) dk
∫ ψ1(x)*ψ2(x) dx = 1/2π∫φ*(k) φ(k) dk = 0 (By Orthogonality)
∫ ψ1(x)*ψ2(x) dx = ∫φ*(k) φ(k) dk = 0 = RHS of initial equation

Something like this?
 
MrPhoton said:
ψ1(x)* = 1/√2π∫φ*(k)e-ikx dk
ψ2(x) = 1/√2π∫φ(k)eikx dk

Therefore applying LHS of Initial equation, we get:

∫ ψ1(x)*ψ2(x) dx = 1/2π∫φ*(k)e-ikx φ(k)eikx dk
∫ ψ1(x)*ψ2(x) dx = 1/2π∫φ*(k) φ(k) dk
∫ ψ1(x)*ψ2(x) dx = 1/2π∫φ*(k) φ(k) dk = 0 (By Orthogonality)
∫ ψ1(x)*ψ2(x) dx = ∫φ*(k) φ(k) dk = 0 = RHS of initial equation

Something like this?
Watch out: in the expressions for psi_1 and for psi_2 you must use two different variables for the corresponding Fourier transforms. For example, use k in the FT of psi_1 and use k' in the FT of psi_2. If you have learned about the Dirac delta function, you will get the answer very easily.
By the way, you do not have (and should not) assume that the integral is zero. The proof is general, it does not require psi_1 and psi_2 to be orthogonal.
 
MrPhoton said:
∫ ψ1(x)*ψ2(x) dx = 1/2π∫φ*(k)e-ikx φ(k)eikx dk
You already made a couple of mistakes there. First, the wavefunctions in momentum space corresponding to ##\psi_1(x)## and ##\psi_2(x)## cannot be the same as Fourier transform is a linear operation. Second, you should just first plug in ##\psi_1^*(x) = \int \phi_1^*(k)e^{-ikx} dk## and ##\psi_2(x) = \int \phi_2(k)e^{ikx} dk## into the inner product expression, and the integration over ##x## should remain at this step.
 
Hello everyone, I’m considering a point charge q that oscillates harmonically about the origin along the z-axis, e.g. $$z_{q}(t)= A\sin(wt)$$ In a strongly simplified / quasi-instantaneous approximation I ignore retardation and take the electric field at the position ##r=(x,y,z)## simply to be the “Coulomb field at the charge’s instantaneous position”: $$E(r,t)=\frac{q}{4\pi\varepsilon_{0}}\frac{r-r_{q}(t)}{||r-r_{q}(t)||^{3}}$$ with $$r_{q}(t)=(0,0,z_{q}(t))$$ (I’m aware this isn’t...
Hi, I had an exam and I completely messed up a problem. Especially one part which was necessary for the rest of the problem. Basically, I have a wormhole metric: $$(ds)^2 = -(dt)^2 + (dr)^2 + (r^2 + b^2)( (d\theta)^2 + sin^2 \theta (d\phi)^2 )$$ Where ##b=1## with an orbit only in the equatorial plane. We also know from the question that the orbit must satisfy this relationship: $$\varepsilon = \frac{1}{2} (\frac{dr}{d\tau})^2 + V_{eff}(r)$$ Ultimately, I was tasked to find the initial...
Back
Top