QuTiP
3.1.0
qutip.org
Docs
Frontmatter
About This Documentation
Citing This Project
Funding
About QuTiP
Contributing to QuTiP
Installation
General Requirements
Platform-independent installation
Get the source code
Installing from source
Installation on Ubuntu Linux
Installation on Mac OS X (10.8+)
Installation on Windows
Optional Installation Options
Verifying the Installation
Checking Version Information using the About Function
Users Guide
Guide Overview
Basic Operations on Quantum Objects
Manipulating States and Operators
Using Tensor Products and Partial Traces
Time Evolution and Quantum System Dynamics
Solving for Steady-State Solutions
An Overview of the Eseries Class
Two-time correlation functions
Plotting on the Bloch Sphere
Visualization of quantum states and processes
Parallel computation
Saving QuTiP Objects and Data Sets
Generating Random Quantum States & Operators
Modifying Internal QuTiP Settings
API documentation
Classes
Functions
Change Log
Version 3.1.0 (January 1, 2015):
Version 3.0.1 (Aug 5, 2014):
Version 3.0.0 (July 17, 2014):
Version 2.2.0 (March 01, 2013):
Version 2.1.0 (October 05, 2012):
Version 2.0.0 (June 01, 2012):
Version 1.1.4 (May 28, 2012):
Version 1.1.3 (November 21, 2011):
Version 1.1.2 (October 27, 2011)
Version 1.1.1 (October 25, 2011)
Version 1.1.0 (October 04, 2011)
Version 1.0.0 (July 29, 2011)
Developers
Lead Developers
Contributors
Bibliography
Page
Time Evolution and Quantum System Dynamics
« Using Tensor Pro...
Dynamics Simulat... »
Time Evolution and Quantum System Dynamics
ΒΆ
Dynamics Simulation Results
The solver.Result Class
Accessing Result Data
Saving and Loading Result Objects
Lindblad Master Equation Solver
Unitary evolution
Non-unitary evolution
The Lindblad Master equation
Monte Carlo Solver
Introduction
Monte Carlo in QuTiP
Bloch-Redfield master equation
Introduction
Brief Derivation and Definitions
Bloch-Redfield master equation in QuTiP
Solving Problems with Time-dependent Hamiltonians
Methods for Writing Time-Dependent Operators
Function Based Time Dependence
String Format Method
Reusing Time-Dependent Hamiltonian Data
Running String-Based Time-Dependent Problems using Parfor
Floquet Formalism
Introduction
Floquet theory for unitary evolution
Floquet theory for dissipative evolution
Setting Options for the Dynamics Solvers