"해밀토니언"의 두 판 사이의 차이

노트

위키데이터

• ID : Q660488

말뭉치

1. Hamiltonian operator, a term used in a quantum theory for the linear operator on a complex ► Hilbert space associated with the generator of the dynamics of a given quantum system.^[1]
2. Operating on the wavefunction with the Hamiltonian produces the Schrodinger equation.^[2]
3. The full role of the Hamiltonian is shown in the time dependent Shrodinger equation where both its spatial and time operations manifest themselves.^[2]
4. In quantum mechanics, the Hamiltonian of a system is an operator corresponding to the total energy of that system, including both kinetic energy and potential energy.^[3]
5. The Hamiltonian of a system is the sum of the kinetic energies of all the particles, plus the potential energy of the particles associated with the system.^[3]
6. Although this is not the technical definition of the Hamiltonian in classical mechanics, it is the form it most commonly takes.^[3]
7. The Hamiltonian generates the time evolution of quantum states.^[3]
8. σ z /2, represents the internal Hamiltonian of the spin (i.e., the energy observable, here given in units for which the reduced Planck constant, ℏ = h/(2π) = 1).^[4]
9. The dominant term of the internal Hamiltonian represents the action of a strong magnetic field applied to the sample.^[4]
10. We will use the Hamiltonian operatorwhich, for our purposes, is the sum of the kinetic and potential energies.^[5]
11. This RRHO Hamiltonian combines the kinetic energy elements of both previous models as well as an associated potential energy (as that in the harmonic oscillator scenario).^[6]
12. This version of the Hamiltonian looks more complicated than Equation \ref{7-7}, but it has the advantage of using variables that are separable (see Separation of Variables).^[7]
13. In the field of quantum mechanics, the Hamiltonian of a system is an operator corresponding to the total energy of that system, including both kinetic energy and potential energy.^[8]
14. In my post on the post on the Hamiltonian, I explained that those C i and D i coefficients are usually a function of time, and how they can be determined.^[9]
15. We introduced operators – but not very rigorously – when explaining the Hamiltonian.^[9]
16. Well… It turns out his Hamiltonian operators is useful to calculate lots of stuff.^[9]
17. The deeper problem with this supposition is that it assumes a conceptual identity between the notions of Hamiltonian and energy, and this is an identity that is not correct.^[10]
18. The Hamiltonian, on the other hand, is a mathematically modified version of the Lagrangian, through what is called the Legendre transform.^[10]
19. What this equation is "really" saying is that in order for such a time series to represent a valid physical evolution, the Hamiltonian must also be able to translate it through time.^[10]
20. Typically being a non-unitary operator, the action of the Hamiltonian is either encoded using complex ancilla-based circuits, or implemented effectively as a sum of Pauli string terms.^[11]
21. Here, we show how to approximate the Hamiltonian operator as a sum propagators using a differential representation.^[11]
22. Its Hamiltonian is often called the Hamiltonian.^[12]
23. The eigenvalues of the Hamiltonian operator for a closed quantum system are exactly the energy eigenvalues of that system.^[12]
24. Thus the Hamiltonian is interpreted as being an “energy” operator.^[12]
25. In the example below, the Hamiltonian Operator node inputs the Hamiltonian of a harmonic oscillator and applies it to a Gaussian function to give a new function.^[13]
26. The Hamiltonian operator, H, is patterned after those discussed previously for the one electron "box" and atom.^[14]
27. The above definitions show that the Hamiltonian operator depends in a simple and obvious way on a molecule's composition.^[14]
28. First, note that the electronic Hamiltonian contains three sums.^[14]
29. We focus on partial Hamiltonian systems for the characterization of their operators and related first integrals.^[15]
30. Firstly, it is shown that if an operator is a partial Hamiltonian operator which yields a first integral, then so does its evolutionary representative.^[15]
31. Secondly, extra operator conditions are provided for a partial Hamiltonian operator in evolutionary form to yield a first integral.^[15]
32. Thirdly, characterization of partial Hamiltonian operators and related first integral conditions are provided for the partial Hamiltonian system.^[15]
33. The hamiltonian class wraps most of the functionalty of the QuSpin package.^[16]
34. basis basis : basis used to build the hamiltonian object.^[16]
35. Returns copy of a hamiltonian object at time time as a scipy.sparse.linalg.^[16]
36. copy () Returns a copy of hamiltonian object.^[16]

소스

메타데이터

위키데이터

• ID : Q660488

Spacy 패턴 목록

• [{'LOWER': 'hamiltonian'}, {'LEMMA': 'operator'}]
• [{'LEMMA': 'hamiltonian'}]