Are Linear Operators Commutative When They Share Common Eigen Vectors?

frederick
Messages
2
Reaction score
0
If A & B are linear operators, and AY=aY & BY=bY, what is the relationship between A & B such that e^A*e^B=e^(A+B)?? --where e^x=1+x+x^2/2+x^3/3!+...+x^n/n!
 
Physics news on Phys.org
Hint: write it out. And remember to watch out for which side you're multiplying on with A or B since, in general, AB \neq BA.
 
Since Y is a common eigenvector for A and B (assuming of course they don't have a continuous spectrum), then A and B commute. Then using Baker-Campbell-Hausdorff formula one sees that "A and B commute" is enough to have e^{A}e^{B}=e^{A+B}.

Daniel.
 
then A and B commute.
What am I missing? Consider the matrices:

<br /> \left(\begin{array}{cc}<br /> 3 &amp; 0 \\<br /> 1 &amp; 1 \\<br /> \end{array}\right) and \left(<br /> \begin{array}{cc}<br /> 2 &amp; 0 \\<br /> 0 &amp; 1 \\<br /> \end{array}\right)<br />

These share a common eigenvector [0 1]^T, but don't commute.
 
Yes, sloppy me, the theorem goes: 2 linear operators commute iff they share a COMPLETE system of common eigen vectors.

Daniel.
 

Thread 'Direction of the magnetic field of an oscillating charge'

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...
View full post »

Thread 'Initial conditions for orbits around a wormhole'

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...
View full post »

Similar threads

Derivation of an expression involving boson operators
Replies
2
Views
2K
Linear operators, quantum mechanics
Replies
12
Views
2K
Show that this dephasing operation is Markovian
Replies
1
Views
1K
Explicit demonstration of a measurement interaction
Replies
3
Views
2K
Particle in a cylindrically symmetric potential (Quantum mechanics)
Replies
5
Views
2K
First order linearized Euler's equation for a small perturbation
Replies
7
Views
2K
Fourier transform of t-V model for t=0 case
Replies
0
Views
1K
Momentum measurement of a particle in Quantum Mechanics
Replies
6
Views
3K
Operator that commutes with the Hamiltonian
Replies
3
Views
2K
QHO: Time dependant expectation value of the potential energy
Replies
3
Views
2K

Hot Threads

Recent Insights

Back
Top