Implicit Differentiation Cal 对比 Quantum Wave in a Box 的使用情况和统计数据
Download this implicit differentiation calculator with steps to find the solution to complex derivative questions.
What is the implicit derivative calculator?
This application works as a math/calculus tool for computing the differentiation solutions. It is detailed and includes almost every option one might require during computation.
What is implicit differentiation?
One of the most complex topics alongside limits and integrals. Implicit differentiation is a type of finding derivatives i.e the rate of change with respect to some value (variable).
It involves functions that are implicit in nature and performing differentiation on them.
How to solve implicit derivatives?
If you ever face an implicit differentiation question then the dy/dx calculator is always there for your rescue.
Those who want to solve derivatives manually will have to learn the rules of differentiation and require a lot of practice. Which, again, is possible if you download this particular application.
How to use this application?
The developers have programmed this implicit derivative calculator with steps very easy to use but as mentioned before, the derivation is a complicated topic.
Therefore, it is necessary to pay attention to the instructions below if you want this tool to operate accurately.
1. Enter the values of function f and g.
2. Choose the variable.
3. Review the equation from the display box.
4. Click calculate.
Make sure that the selected variable is a part of the entered function.
Features of this application:
Let’s shed some light on the main features of this application to convince you of its fineness.
1. Easy interface to allow beginners to use it without any problem. This app has high usability which makes it an ideal choice for everyone.
2. Examples to give users an idea of implicit differentiation questions and their solutions.
3. The results of this application are a game-changer without any doubt. It is common for derivative calculators to give steps but this application has more to offer.
Not only do you get the steps but also an explanation for each step. This is useful for newbies. It will help them to learn more about differentiation and its rules.
1. Keyboard for math functions like trigonometric, exponents e.t.c
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Schrödinger equation solver 1D. User defined potential V(x). Diagonalization of hamiltonian matrix. Animation showing evolution in time of a gaussian wave-packet.
In Quantum Mechanics the one-dimensional Schrödinger equation is a fundamental academic though exciting subject of study for both students and teachers of Physics. A solution of this differential equation represents the motion of a non-relativistic particle in a potential energy field V(x). But very few solutions can be derived with a paper and pencil.
Have you ever dreamed of an App which would solve this equation (numerically) for each input of V(x) ?
Give you readily energy levels and wave-functions and let you see as an animation how evolves in time a gaussian wave-packet in this particular interaction field ?
Quantum Wave in a Box does it ! For a large range of values of the quantum system parameters.
Actually the originally continuous x-spatial differential problem is discretized over a finite interval (the Box) while time remains a continuous variable. The time-independent Schrödinger equation H ψ(x) = E ψ(x), represented by a set of linear equations, is solved by using quick diagonalization routines. The solution ψ(x,t) of the time-dependent Schrödinger equation is then computed as ψ(x,t) = exp(-iHt) ψ₀(x) where ψ₀(x) is a gaussian wave-packet at initial time t = 0.
You enter V(x) as RPN expression, set values of parameters and will get a solution in many cases within seconds !
- Atomic units used throughout (mass of electron = 1)
- Quantum system defined by mass, interval [a, b] representing the Box and (real) potential energy V(x).
- Spatially continuous problem discretized over [a, b] and time-independent Schrödinger equation represented by a system of N+1 linear equations using a 3, 5 or 7 point stencil; N being the number of x-steps. Maximum value of N depends on device’s RAM: up to 4000 when computing eigenvalues and eigenvectors, up to 8000 when computing eigenvalues only.
- Diagonalization of hamiltonian matrix H gives eigenvalues and eigenfunctions. When computing eigenvalues only, lowest energy levels of bound states (if any) with up to 10-digit precision.
- Listing of energy levels and visualisation of eigenwave-functions.
- Animation shows gaussian wave-packet ψ(x,t) evolving with real-time evaluation of average velocity, kinetic energy and total energy.
- Toggle between clockwise and counter-clockwise evolution of ψ(x,t).
- Watch Real ψ, Imag ψ or probability density |ψ|².
- Change initial gaussian parameters of the wave-packet (position, group velocity, standard deviation), enter any time value, then tap refresh button to observe changes in curves without new diagonalization. This is particularly useful to get a (usually more precise) solution for any time value t when animation is slower in cases of N being large.
- Watch both solution ψ(x,t) and free wave-packet curves evolve together in time and separate when entering non-zero potential energy region.
- Zoom in and out any part of the curves and watch how ψ(x,t) evolve locally.
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Implicit Differentiation Cal VS. 
Quantum Wave in a Box十二月 17, 2024