def floquet_modes_table(f_modes_0, f_energies, tlist, H, T, args=None): """ Pre-calculate the Floquet modes for a range of times spanning the floquet period. Can later be used as a table to look up the floquet modes for any time. Parameters ---------- f_modes_0 : list of :class:`qutip.Qobj` (kets) Floquet modes at :math:`t` f_energies : list Floquet energies. tlist : array The list of times at which to evaluate the floquet modes. H : :class:`qutip.Qobj` system Hamiltonian, time-dependent with period `T` T : float The period of the time-dependence of the hamiltonian. args : dictionary dictionary with variables required to evaluate H Returns ------- output : nested list A nested list of Floquet modes as kets for each time in `tlist` """ # truncate tlist to the driving period tlist_period = tlist[np.where(tlist <= T)] f_modes_table_t = [[] for t in tlist_period] opt = Odeoptions() opt.rhs_reuse = True for n, f_mode in enumerate(f_modes_0): output = mesolve(H, f_mode, tlist_period, [], [], args, opt) for t_idx, f_state_t in enumerate(output.states): f_modes_table_t[t_idx].append( f_state_t * exp(1j * f_energies[n] * tlist_period[t_idx])) return f_modes_table_t
def floquet_modes_table(f_modes_0, f_energies, tlist, H, T, args=None): """ Pre-calculate the Floquet modes for a range of times spanning the floquet period. Can later be used as a table to look up the floquet modes for any time. Parameters ---------- f_modes_0 : list of :class:`qutip.Qobj` (kets) Floquet modes at :math:`t` f_energies : list Floquet energies. tlist : array The list of times at which to evaluate the floquet modes. H : :class:`qutip.Qobj` system Hamiltonian, time-dependent with period `T` T : float The period of the time-dependence of the hamiltonian. args : dictionary dictionary with variables required to evaluate H Returns ------- output : nested list A nested list of Floquet modes as kets for each time in `tlist` """ # truncate tlist to the driving period tlist_period = tlist[np.where(tlist <= T)] f_modes_table_t = [[] for t in tlist_period] opt = Odeoptions() opt.rhs_reuse = True for n, f_mode in enumerate(f_modes_0): output = mesolve(H, f_mode, tlist_period, [], [], args, opt) for t_idx, f_state_t in enumerate(output.states): f_modes_table_t[t_idx].append(f_state_t * exp(1j * f_energies[n]*tlist_period[t_idx])) return f_modes_table_t
def floquet_modes_table(f_modes_0, f_energies, tlist, H, T, args=None): """ Pre-calculate the Floquet modes for a range of times spanning the floquet period. Can later be used as a table to look up the floquet modes for any time. """ # truncate tlist to the driving period tlist_period = tlist[where(tlist <= T)] f_modes_table_t = [[] for t in tlist_period] opt = Odeoptions() opt.rhs_reuse = True for n, f_mode in enumerate(f_modes_0): output = mesolve(H, f_mode, tlist_period, [], [], args, opt) for t_idx, f_state_t in enumerate(output.states): f_modes_table_t[t_idx].append(f_state_t * exp(1j * f_energies[n]*tlist_period[t_idx])) return f_modes_table_t
def floquet_modes_table(f_modes_0, f_energies, tlist, H, T, args=None): """ Pre-calculate the Floquet modes for a range of times spanning the floquet period. Can later be used as a table to look up the floquet modes for any time. """ # truncate tlist to the driving period tlist_period = tlist[where(tlist <= T)] f_modes_table_t = [[] for t in tlist_period] opt = Odeoptions() opt.rhs_reuse = True for n, f_mode in enumerate(f_modes_0): output = mesolve(H, f_mode, tlist_period, [], [], args, opt) for t_idx, f_state_t in enumerate(output.states): f_modes_table_t[t_idx].append( f_state_t * exp(1j * f_energies[n] * tlist_period[t_idx])) return f_modes_table_t
def odesolve(H, rho0, tlist, c_op_list, expt_ops, H_args=None, options=None): """ Master equation evolution of a density matrix for a given Hamiltonian. Evolution of a state vector or density matrix (`rho0`) for a given Hamiltonian (`H`) and set of collapse operators (`c_op_list`), by integrating the set of ordinary differential equations that define the system. The output is either the state vector at arbitrary points in time (`tlist`), or the expectation values of the supplied operators (`expt_ops`). For problems with time-dependent Hamiltonians, `H` can be a callback function that takes two arguments, time and `H_args`, and returns the Hamiltonian at that point in time. `H_args` is a list of parameters that is passed to the callback function `H` (only used for time-dependent Hamiltonians). Parameters ---------- H : :class:`qutip.Qobj` system Hamiltonian, or a callback function for time-dependent Hamiltonians. rho0 : :class:`qutip.Qobj` initial density matrix or state vector (ket). tlist : *list* / *array* list of times for :math:`t`. c_op_list : list of :class:`qutip.Qobj` list of collapse operators. expt_ops : list of :class:`qutip.Qobj` / callback function list of operators for which to evaluate expectation values. H_args : *dictionary* dictionary of parameters for time-dependent Hamiltonians and collapse operators. options : :class:`qutip.Qdeoptions` with options for the ODE solver. Returns ------- output :array Expectation values of wavefunctions/density matrices for the times specified by `tlist`. Notes ----- On using callback function: odesolve transforms all :class:`qutip.Qobj` objects to sparse matrices before handing the problem to the integrator function. In order for your callback function to work correctly, pass all :class:`qutip.Qobj` objects that are used in constructing the Hamiltonian via H_args. odesolve will check for :class:`qutip.Qobj` in `H_args` and handle the conversion to sparse matrices. All other :class:`qutip.Qobj` objects that are not passed via `H_args` will be passed on to the integrator to scipy who will raise an NotImplemented exception. Depreciated in QuTiP 2.0.0. Use :func:`mesolve` instead. """ if options == None: options = Odeoptions() options.nsteps = 2500 # options.max_step = max(tlist)/10.0 # take at least 10 steps.. if (c_op_list and len(c_op_list) > 0) or not isket(rho0): if isinstance(H, list): output = mesolve_list_td(H, rho0, tlist, c_op_list, expt_ops, H_args, options) if isinstance(H, FunctionType): output = mesolve_func_td(H, rho0, tlist, c_op_list, expt_ops, H_args, options) else: output = mesolve_const(H, rho0, tlist, c_op_list, expt_ops, H_args, options) else: if isinstance(H, list): output = wfsolve_list_td(H, rho0, tlist, expt_ops, H_args, options) if isinstance(H, FunctionType): output = wfsolve_func_td(H, rho0, tlist, expt_ops, H_args, options) else: output = wfsolve_const(H, rho0, tlist, expt_ops, H_args, options) if len(expt_ops) > 0: return output.expect else: return output.states
def bloch_redfield_solve(R, ekets, rho0, tlist, e_ops=[], opt=None): """ Evolve the ODEs defined by Bloch-Redfeild master equation. """ if opt == None: opt = Odeoptions() opt.nsteps = 2500 # if opt.tidy: R.tidyup() # # check initial state # if isket(rho0): # Got a wave function as initial state: convert to density matrix. rho0 = rho0 * rho0.dag() # # prepare output array # m n_e_ops = len(e_ops) n_tsteps = len(tlist) dt = tlist[1] - tlist[0] if n_e_ops == 0: result_list = [] else: result_list = [] for op in e_ops: if op.isherm and rho0.isherm: result_list.append(zeros(n_tsteps)) else: result_list.append(zeros(n_tsteps, dtype=complex)) # # transform the initial density matrix and the e_ops opterators to the # eigenbasis # if ekets != None: rho0 = rho0.transform(ekets) for n in arange(len(e_ops)): e_ops[n] = e_ops[n].transform(ekets, False) # # setup integrator # initial_vector = mat2vec(rho0.full()) r = scipy.integrate.ode(cyq_ode_rhs) r.set_f_params(R.data.data, R.data.indices, R.data.indptr) r.set_integrator( 'zvode', method=opt.method, order=opt.order, atol=opt.atol, rtol=opt.rtol, #nsteps=opt.nsteps, #first_step=opt.first_step, min_step=opt.min_step, max_step=opt.max_step) r.set_initial_value(initial_vector, tlist[0]) # # start evolution # rho = Qobj(rho0) t_idx = 0 for t in tlist: if not r.successful(): break rho.data = vec2mat(r.y) # calculate all the expectation values, or output rho if no operators if n_e_ops == 0: result_list.append(Qobj(rho)) else: for m in range(0, n_e_ops): result_list[m][t_idx] = expect(e_ops[m], rho) r.integrate(r.t + dt) t_idx += 1 return result_list
def propagator(H, t, c_op_list, H_args=None, opt=None): """ Calculate the propagator U(t) for the density matrix or wave function such that :math:`\psi(t) = U(t)\psi(0)` or :math:`\\rho_{\mathrm vec}(t) = U(t) \\rho_{\mathrm vec}(0)` where :math:`\\rho_{\mathrm vec}` is the vector representation of the density matrix. Parameters ---------- H : qobj Hamiltonian t : float Time. c_op_list : list List of qobj collapse operators. Other Parameters ---------------- H_args : list/array/dictionary Parameters to callback functions for time-dependent Hamiltonians. Returns ------- a : qobj Instance representing the propagator :math:`U(t)`. """ if opt == None: opt = Odeoptions() opt.rhs_reuse = True if len(c_op_list) == 0: # calculate propagator for the wave function if isinstance(H, FunctionType): H0 = H(0.0, H_args) N = H0.shape[0] elif isinstance(H, list): if isinstance(H[0], list): H0 = H[0][0] N = H0.shape[0] else: H0 = H[0] N = H0.shape[0] else: N = H.shape[0] u = zeros([N, N], dtype=complex) for n in range(0, N): psi0 = basis(N, n) output = mesolve(H, psi0, [0, t], [], [], H_args, opt) u[:, n] = output.states[1].full().T # todo: evolving a batch of wave functions: #psi_0_list = [basis(N, n) for n in range(N)] #psi_t_list = mesolve(H, psi_0_list, [0, t], [], [], H_args, opt) #for n in range(0, N): # u[:,n] = psi_t_list[n][1].full().T else: # calculate the propagator for the vector representation of the # density matrix if isinstance(H, FunctionType): H0 = H(0.0, H_args) N = H0.shape[0] elif isinstance(H, list): if isinstance(H[0], list): H0 = H[0][0] N = H0.shape[0] else: H0 = H[0] N = H0.shape[0] else: N = H.shape[0] u = zeros([N * N, N * N], dtype=complex) for n in range(0, N * N): psi0 = basis(N * N, n) rho0 = Qobj(vec2mat(psi0.full())) output = mesolve(H, rho0, [0, t], c_op_list, [], H_args, opt) u[:, n] = mat2vec(output.states[1].full()).T return Qobj(u)
def propagator(H, t, c_op_list, H_args=None, opt=None): """ Calculate the propagator U(t) for the density matrix or wave function such that :math:`\psi(t) = U(t)\psi(0)` or :math:`\\rho_{\mathrm vec}(t) = U(t) \\rho_{\mathrm vec}(0)` where :math:`\\rho_{\mathrm vec}` is the vector representation of the density matrix. Parameters ---------- H : qobj or list Hamiltonian as a Qobj instance of a nested list of Qobjs and coefficients in the list-string or list-function format for time-dependent Hamiltonians (see description in :func:`qutip.mesolve`). t : float or array-like Time or list of times for which to evaluate the propagator. c_op_list : list List of qobj collapse operators. H_args : list/array/dictionary Parameters to callback functions for time-dependent Hamiltonians. Returns ------- a : qobj Instance representing the propagator :math:`U(t)`. """ if opt == None: opt = Odeoptions() opt.rhs_reuse = True tlist = [0, t] if isinstance(t,(int,float,np.int64,np.float64)) else t if len(c_op_list) == 0: # calculate propagator for the wave function if isinstance(H, types.FunctionType): H0 = H(0.0, H_args) N = H0.shape[0] elif isinstance(H, list): if isinstance(H[0], list): H0 = H[0][0] N = H0.shape[0] else: H0 = H[0] N = H0.shape[0] else: N = H.shape[0] u = np.zeros([N, N, len(tlist)], dtype=complex) for n in range(0, N): psi0 = basis(N, n) output = mesolve(H, psi0, tlist, [], [], H_args, opt) for k, t in enumerate(tlist): u[:,n,k] = output.states[k].full().T # todo: evolving a batch of wave functions: #psi_0_list = [basis(N, n) for n in range(N)] #psi_t_list = mesolve(H, psi_0_list, [0, t], [], [], H_args, opt) #for n in range(0, N): # u[:,n] = psi_t_list[n][1].full().T else: # calculate the propagator for the vector representation of the # density matrix if isinstance(H, types.FunctionType): H0 = H(0.0, H_args) N = H0.shape[0] elif isinstance(H, list): if isinstance(H[0], list): H0 = H[0][0] N = H0.shape[0] else: H0 = H[0] N = H0.shape[0] else: N = H.shape[0] u = np.zeros([N*N, N*N, len(tlist)], dtype=complex) for n in range(0, N*N): psi0 = basis(N*N, n) rho0 = Qobj(vec2mat(psi0.full())) output = mesolve(H, rho0, tlist, c_op_list, [], H_args, opt) for k, t in enumerate(tlist): u[:,n,k] = mat2vec(output.states[k].full()).T if len(tlist) == 2: return Qobj(u[:,:,1]) else: return [Qobj(u[:,:,k]) for k in range(len(tlist))]
def bloch_redfield_solve(R, ekets, rho0, tlist, e_ops=[], options=None): """ Evolve the ODEs defined by Bloch-Redfield master equation. The Bloch-Redfield tensor can be calculated by the function :func:`bloch_redfield_tensor`. Parameters ---------- R : :class:`qutip.Qobj` Bloch-Redfield tensor. ekets : array of :class:`qutip.Qobj` Array of kets that make up a basis tranformation for the eigenbasis. rho0 : :class:`qutip.Qobj` Initial density matrix. tlist : *list* / *array* List of times for :math:`t`. e_ops : list of :class:`qutip.Qobj` / callback function List of operators for which to evaluate expectation values. options : :class:`qutip.Qdeoptions` Options for the ODE solver. Returns ------- output: :class:`qutip.Odedata` An instance of the class :class:`qutip.Odedata`, which contains either an *array* of expectation values for the times specified by `tlist`. """ if options == None: options = Odeoptions() options.nsteps = 2500 # if options.tidy: R.tidyup() # # check initial state # if isket(rho0): # Got a wave function as initial state: convert to density matrix. rho0 = rho0 * rho0.dag() # # prepare output array # n_e_ops = len(e_ops) n_tsteps = len(tlist) dt = tlist[1] - tlist[0] if n_e_ops == 0: result_list = [] else: result_list = [] for op in e_ops: if op.isherm and rho0.isherm: result_list.append(np.zeros(n_tsteps)) else: result_list.append(np.zeros(n_tsteps, dtype=complex)) # # transform the initial density matrix and the e_ops opterators to the # eigenbasis # if ekets != None: rho0 = rho0.transform(ekets) for n in arange(len(e_ops)): e_ops[n] = e_ops[n].transform(ekets, False) # # setup integrator # initial_vector = mat2vec(rho0.full()) r = scipy.integrate.ode(cyq_ode_rhs) r.set_f_params(R.data.data, R.data.indices, R.data.indptr) r.set_integrator( 'zvode', method=options.method, order=options.order, atol=options.atol, rtol=options.rtol, #nsteps=options.nsteps, #first_step=options.first_step, min_step=options.min_step, max_step=options.max_step) r.set_initial_value(initial_vector, tlist[0]) # # start evolution # rho = Qobj(rho0) t_idx = 0 for t in tlist: if not r.successful(): break rho.data = vec2mat(r.y) # calculate all the expectation values, or output rho if no operators if n_e_ops == 0: result_list.append(Qobj(rho)) else: for m in range(0, n_e_ops): result_list[m][t_idx] = expect(e_ops[m], rho) r.integrate(r.t + dt) t_idx += 1 return result_list
def bloch_redfield_solve(R, ekets, rho0, tlist, e_ops=[], opt=None): """ Evolve the ODEs defined by Bloch-Redfeild master equation. """ if opt == None: opt = Odeoptions() opt.nsteps = 2500 # if opt.tidy: R.tidyup() # # check initial state # if isket(rho0): # Got a wave function as initial state: convert to density matrix. rho0 = rho0 * rho0.dag() # # prepare output array # m n_e_ops = len(e_ops) n_tsteps = len(tlist) dt = tlist[1]-tlist[0] if n_e_ops == 0: result_list = [] else: result_list = [] for op in e_ops: if op.isherm and rho0.isherm: result_list.append(zeros(n_tsteps)) else: result_list.append(zeros(n_tsteps,dtype=complex)) # # transform the initial density matrix and the e_ops opterators to the # eigenbasis # if ekets != None: rho0 = rho0.transform(ekets) for n in arange(len(e_ops)): e_ops[n] = e_ops[n].transform(ekets, False) # # setup integrator # initial_vector = mat2vec(rho0.full()) r = scipy.integrate.ode(cyq_ode_rhs) r.set_f_params(R.data.data, R.data.indices, R.data.indptr) r.set_integrator('zvode', method=opt.method, order=opt.order, atol=opt.atol, rtol=opt.rtol, #nsteps=opt.nsteps, #first_step=opt.first_step, min_step=opt.min_step, max_step=opt.max_step) r.set_initial_value(initial_vector, tlist[0]) # # start evolution # rho = Qobj(rho0) t_idx = 0 for t in tlist: if not r.successful(): break; rho.data = vec2mat(r.y) # calculate all the expectation values, or output rho if no operators if n_e_ops == 0: result_list.append(Qobj(rho)) else: for m in range(0, n_e_ops): result_list[m][t_idx] = expect(e_ops[m], rho) r.integrate(r.t + dt) t_idx += 1 return result_list
def mesolve(H, rho0, tlist, c_ops, expt_ops, args={}, options=None): """ Master equation evolution of a density matrix for a given Hamiltonian. Evolve the state vector or density matrix (`rho0`) using a given Hamiltonian (`H`) and an [optional] set of collapse operators (`c_op_list`), by integrating the set of ordinary differential equations that define the system. In the absense of collase operators the system is evolved according to the unitary evolution of the Hamiltonian. The output is either the state vector at arbitrary points in time (`tlist`), or the expectation values of the supplied operators (`expt_ops`). If expt_ops is a callback function, it is invoked for each time in `tlist` with time and the state as arguments, and the function does not use any return values. **Time-dependent operators** For problems with time-dependent problems `H` and `c_ops` can be callback functions that takes two arguments, time and `args`, and returns the Hamiltonian or Liuovillian for the system at that point in time (*callback format*). Alternatively, `H` and `c_ops` can be a specified in a nested-list format where each element in the list is a list of length 2, containing an operator (:class:`qutip.Qobj`) at the first element and where the second element is either a string (*list string format*) or a callback function (*list callback format*) that evaluates to the time-dependent coefficient for the corresponding operator. *Examples* H = [[H0, 'sin(w*t)'], [H1, 'sin(2*w*t)']] H = [[H0, f0_t], [H1, f1_t]] where f0_t and f1_t are python functions with signature f_t(t, args). In the *list string format* and *list callback format*, the string expression and the callback function must evaluate to a real or complex number (coefficient for the corresponding operator). In all cases of time-dependent operators, `args` is a dictionary of parameters that is used when evaluating operators. It is passed to the callback functions as second argument .. note:: On using callback function: mesolve transforms all :class:`qutip.Qobj` objects to sparse matrices before handing the problem to the integrator function. In order for your callback function to work correctly, pass all :class:`qutip.Qobj` objects that are used in constructing the Hamiltonian via args. odesolve will check for :class:`qutip.Qobj` in `args` and handle the conversion to sparse matrices. All other :class:`qutip.Qobj` objects that are not passed via `args` will be passed on to the integrator to scipy who will raise an NotImplemented exception. Parameters ---------- H : :class:`qutip.Qobj` system Hamiltonian, or a callback function for time-dependent Hamiltonians. rho0 : :class:`qutip.Qobj` initial density matrix or state vector (ket). tlist : *list* / *array* list of times for :math:`t`. c_ops : list of :class:`qutip.Qobj` list of collapse operators. expt_ops : list of :class:`qutip.Qobj` / callback function list of operators for which to evaluate expectation values. args : *dictionary* dictionary of parameters for time-dependent Hamiltonians and collapse operators. options : :class:`qutip.Qdeoptions` with options for the ODE solver. Returns ------- output: :class:`qutip.Odedata` An instance of the class :class:`qutip.Odedata`, which contains either an *array* of expectation values for the times specified by `tlist`, or an *array* or state vectors or density matrices corresponding to the times in `tlist` [if `expt_ops` is an empty list], or nothing if a callback function was given inplace of operators for which to calculate the expectation values. """ # check for type (if any) of time-dependent inputs n_const, n_func, n_str = _ode_checks(H, c_ops) if options == None: options = Odeoptions() if (not options.rhs_reuse) or (not odeconfig.tdfunc): #reset odeconfig collapse and time-dependence flags to default values _reset_odeconfig() # # dispatch the appropriate solver # if (c_ops and len(c_ops) > 0) or not isket(rho0): # # we have collapse operators # # # find out if we are dealing with all-constant hamiltonian and # collapse operators or if we have at least one time-dependent # operator. Then delegate to appropriate solver... # if isinstance(H, Qobj): # constant hamiltonian if n_func == 0 and n_str == 0: # constant collapse operators return _mesolve_const(H, rho0, tlist, c_ops, expt_ops, args, options) elif n_str > 0: # constant hamiltonian but time-dependent collapse operators in list string format return _mesolve_list_str_td([H], rho0, tlist, c_ops, expt_ops, args, options) elif n_func > 0: # constant hamiltonian but time-dependent collapse operators in list function format return _mesolve_list_func_td([H], rho0, tlist, c_ops, expt_ops, args, options) if isinstance(H, types.FunctionType): # old style time-dependence: must have constant collapse operators if n_str > 0: # or n_func > 0: raise TypeError( "Incorrect format: function-format Hamiltonian " + "cannot be mixed with time-dependent collapse operators.") else: return _mesolve_func_td(H, rho0, tlist, c_ops, expt_ops, args, options) if isinstance(H, list): # determine if we are dealing with list of [Qobj, string] or [Qobj, function] # style time-dependences (for pure python and cython, respectively) if n_func > 0: return _mesolve_list_func_td(H, rho0, tlist, c_ops, expt_ops, args, options) else: return _mesolve_list_str_td(H, rho0, tlist, c_ops, expt_ops, args, options) raise TypeError( "Incorrect specification of Hamiltonian or collapse operators.") else: # # no collapse operators: unitary dynamics # if n_func > 0: return _wfsolve_list_func_td(H, rho0, tlist, expt_ops, args, options) elif n_str > 0: return _wfsolve_list_str_td(H, rho0, tlist, expt_ops, args, options) elif isinstance(H, types.FunctionType): return _wfsolve_func_td(H, rho0, tlist, expt_ops, args, options) else: return _wfsolve_const(H, rho0, tlist, expt_ops, args, options)
def bloch_redfield_solve(R, ekets, rho0, tlist, e_ops=[], options=None): """ Evolve the ODEs defined by Bloch-Redfield master equation. The Bloch-Redfield tensor can be calculated by the function :func:`bloch_redfield_tensor`. Parameters ---------- R : :class:`qutip.Qobj` Bloch-Redfield tensor. ekets : array of :class:`qutip.Qobj` Array of kets that make up a basis tranformation for the eigenbasis. rho0 : :class:`qutip.Qobj` Initial density matrix. tlist : *list* / *array* List of times for :math:`t`. e_ops : list of :class:`qutip.Qobj` / callback function List of operators for which to evaluate expectation values. options : :class:`qutip.Qdeoptions` Options for the ODE solver. Returns ------- output: :class:`qutip.Odedata` An instance of the class :class:`qutip.Odedata`, which contains either an *array* of expectation values for the times specified by `tlist`. """ if options == None: options = Odeoptions() options.nsteps = 2500 # if options.tidy: R.tidyup() # # check initial state # if isket(rho0): # Got a wave function as initial state: convert to density matrix. rho0 = rho0 * rho0.dag() # # prepare output array # n_e_ops = len(e_ops) n_tsteps = len(tlist) dt = tlist[1]-tlist[0] if n_e_ops == 0: result_list = [] else: result_list = [] for op in e_ops: if op.isherm and rho0.isherm: result_list.append(np.zeros(n_tsteps)) else: result_list.append(np.zeros(n_tsteps,dtype=complex)) # # transform the initial density matrix and the e_ops opterators to the # eigenbasis # if ekets != None: rho0 = rho0.transform(ekets) for n in arange(len(e_ops)): e_ops[n] = e_ops[n].transform(ekets, False) # # setup integrator # initial_vector = mat2vec(rho0.full()) r = scipy.integrate.ode(cyq_ode_rhs) r.set_f_params(R.data.data, R.data.indices, R.data.indptr) r.set_integrator('zvode', method=options.method, order=options.order, atol=options.atol, rtol=options.rtol, #nsteps=options.nsteps, #first_step=options.first_step, min_step=options.min_step, max_step=options.max_step) r.set_initial_value(initial_vector, tlist[0]) # # start evolution # rho = Qobj(rho0) t_idx = 0 for t in tlist: if not r.successful(): break; rho.data = vec2mat(r.y) # calculate all the expectation values, or output rho if no operators if n_e_ops == 0: result_list.append(Qobj(rho)) else: for m in range(0, n_e_ops): result_list[m][t_idx] = expect(e_ops[m], rho) r.integrate(r.t + dt) t_idx += 1 return result_list
def brmesolve(H, psi0, tlist, c_ops, e_ops=[], spectra_cb=[], args={}, options=Odeoptions()): """ Solve the dynamics for the system using the Bloch-Redfeild master equation. .. note:: This solver does not currently support time-dependent Hamiltonian or collapse operators. Parameters ---------- H : :class:`qutip.Qobj` system Hamiltonian. rho0 / psi0: :class:`qutip.Qobj` initial density matrix or state vector (ket). tlist : *list* / *array* list of times for :math:`t`. c_ops : list of :class:`qutip.Qobj` list of collapse operators. expt_ops : list of :class:`qutip.Qobj` / callback function list of operators for which to evaluate expectation values. args : *dictionary* dictionary of parameters for time-dependent Hamiltonians and collapse operators. options : :class:`qutip.Qdeoptions` with options for the ODE solver. Returns ------- output: :class:`qutip.Odedata` An instance of the class :class:`qutip.Odedata`, which contains either an *array* of expectation values for the times specified by `tlist`. """ if len(spectra_cb) == 0: for n in range(len(c_ops)): spectra_cb.append( lambda w: 1.0) # add white noise callbacks if absent R, ekets = bloch_redfield_tensor(H, c_ops, spectra_cb) output = Odedata() output.times = tlist output.expect = bloch_redfield_solve(R, ekets, psi0, tlist, e_ops, options) return output
def rhs_generate(H, psi0, tlist, c_ops, e_ops, ntraj=500, args={}, options=Odeoptions(), solver='me', name=None): """ Used to generate the Cython functions for solving the dynamics of a given system before using the parfor function. Parameters ---------- H : qobj System Hamiltonian. psi0 : qobj Initial state vector tlist : array_like Times at which results are recorded. ntraj : int Number of trajectories to run. c_ops : array_like ``list`` or ``array`` of collapse operators. e_ops : array_like ``list`` or ``array`` of operators for calculating expectation values. args : dict Arguments for time-dependent Hamiltonian and collapse operator terms. options : Odeoptions Instance of ODE solver options. solver: str String indicating which solver "me" or "mc" name: str Name of generated RHS """ _reset_odeconfig() #clear odeconfig #------------------------ # GENERATE MCSOLVER DATA #------------------------ if solver == 'mc': odeconfig.tlist = tlist if isinstance(ntraj, (list, ndarray)): odeconfig.ntraj = sort(ntraj)[-1] else: odeconfig.ntraj = ntraj #check for type of time-dependence (if any) time_type, h_stuff, c_stuff = _ode_checks(H, c_ops, 'mc') h_terms = len(h_stuff[0]) + len(h_stuff[1]) + len(h_stuff[2]) c_terms = len(c_stuff[0]) + len(c_stuff[1]) + len(c_stuff[2]) #set time_type for use in multiprocessing odeconfig.tflag = time_type #check for collapse operators if c_terms > 0: odeconfig.cflag = 1 else: odeconfig.cflag = 0 #Configure data _mc_data_config(H, psi0, h_stuff, c_ops, c_stuff, args, e_ops, options) os.environ['CFLAGS'] = '-w' import pyximport pyximport.install(setup_args={'include_dirs': [numpy.get_include()]}) if odeconfig.tflag in array([1, 11]): code = compile( 'from ' + odeconfig.tdname + ' import cyq_td_ode_rhs,col_spmv,col_expect', '<string>', 'exec') exec(code) odeconfig.tdfunc = cyq_td_ode_rhs odeconfig.colspmv = col_spmv odeconfig.colexpect = col_expect else: code = compile( 'from ' + odeconfig.tdname + ' import cyq_td_ode_rhs', '<string>', 'exec') exec(code) odeconfig.tdfunc = cyq_td_ode_rhs try: os.remove(odeconfig.tdname + ".pyx") except: print("Error removing pyx file. File not found.") #------------------------ # GENERATE MESOLVER STUFF #------------------------ elif solver == 'me': odeconfig.tdname = "rhs" + str(odeconfig.cgen_num) cgen = Codegen(h_terms=n_L_terms, h_tdterms=Lcoeff, args=args) cgen.generate(odeconfig.tdname + ".pyx") os.environ['CFLAGS'] = '-O3 -w' import pyximport pyximport.install(setup_args={'include_dirs': [numpy.get_include()]}) code = compile('from ' + odeconfig.tdname + ' import cyq_td_ode_rhs', '<string>', 'exec') exec(code) odeconfig.tdfunc = cyq_td_ode_rhs
def rhs_generate(H,c_ops,args={},options=Odeoptions(),name=None): """ Generates the Cython functions needed for solving the dynamics of a given system using the mesolve function inside a parfor loop. Parameters ---------- H : qobj System Hamiltonian. c_ops : list ``list`` of collapse operators. args : dict Arguments for time-dependent Hamiltonian and collapse operator terms. options : Odeoptions Instance of ODE solver options. name: str Name of generated RHS Notes ----- Using this function with any solver other than the mesolve function will result in an error. """ _reset_odeconfig() #clear odeconfig if name: odeconfig.tdname=name else: odeconfig.tdname="rhs"+str(odeconfig.cgen_num) n_op = len(c_ops) Lconst = 0 Ldata = [] Linds = [] Lptrs = [] Lcoeff = [] # loop over all hamiltonian terms, convert to superoperator form and # add the data of sparse matrix represenation to for h_spec in H: if isinstance(h_spec, Qobj): h = h_spec Lconst += -1j*(spre(h) - spost(h)) elif isinstance(h_spec, list): h = h_spec[0] h_coeff = h_spec[1] L = -1j*(spre(h) - spost(h)) Ldata.append(L.data.data) Linds.append(L.data.indices) Lptrs.append(L.data.indptr) Lcoeff.append(h_coeff) else: raise TypeError("Incorrect specification of time-dependent " + "Hamiltonian (expected string format)") # loop over all collapse operators for c_spec in c_ops: if isinstance(c_spec, Qobj): c = c_spec cdc = c.dag() * c Lconst += spre(c) * spost(c.dag()) - 0.5 * spre(cdc) - 0.5 * spost(cdc) elif isinstance(c_spec, list): c = c_spec[0] c_coeff = c_spec[1] cdc = c.dag() * c L = spre(c) * spost(c.dag()) - 0.5 * spre(cdc) - 0.5 * spost(cdc) Ldata.append(L.data.data) Linds.append(L.data.indices) Lptrs.append(L.data.indptr) Lcoeff.append("("+c_coeff+")**2") else: raise TypeError("Incorrect specification of time-dependent " + "collapse operators (expected string format)") # add the constant part of the lagrangian if Lconst != 0: Ldata.append(Lconst.data.data) Linds.append(Lconst.data.indices) Lptrs.append(Lconst.data.indptr) Lcoeff.append("1.0") # the total number of liouvillian terms (hamiltonian terms + collapse operators) n_L_terms = len(Ldata) cgen=Codegen(h_terms=n_L_terms,h_tdterms=Lcoeff, args=args) cgen.generate(odeconfig.tdname+".pyx") os.environ['CFLAGS'] = '-O3 -w' import pyximport pyximport.install(setup_args={'include_dirs':[numpy.get_include()]}) code = compile('from '+odeconfig.tdname+' import cyq_td_ode_rhs', '<string>', 'exec') exec(code) odeconfig.tdfunc=cyq_td_ode_rhs try: os.remove(odeconfig.tdname+".pyx") except: pass
def fmmesolve(H, rho0, tlist, c_ops, e_ops=[], spectra_cb=[], T=None, args={}, options=Odeoptions()): """ Solve the dynamics for the system using the Floquet-Markov master equation. .. note:: This solver currently does not support multiple collapse operators. Parameters ---------- H : :class:`qutip.Qobj` system Hamiltonian. rho0 / psi0 : :class:`qutip.Qobj` initial density matrix or state vector (ket). tlist : *list* / *array* list of times for :math:`t`. c_ops : list of :class:`qutip.Qobj` list of collapse operators. e_ops : list of :class:`qutip.Qobj` / callback function list of operators for which to evaluate expectation values. spectra_cb : list callback functions List of callback functions that compute the noise power spectrum as a function of frequency for the collapse operators in `c_ops`. T : float The period of the time-dependence of the hamiltonian. The default value 'None' indicates that the 'tlist' spans a single period of the driving. args : *dictionary* dictionary of parameters for time-dependent Hamiltonians and collapse operators. This dictionary should also contain an entry 'w_th', which is the temperature of the environment (if finite) in the energy/frequency units of the Hamiltonian. For example, if the Hamiltonian written in units of 2pi GHz, and the temperature is given in K, use the following conversion >>> temperature = 25e-3 # unit K >>> h = 6.626e-34 >>> kB = 1.38e-23 >>> args['w_th'] = temperature * (kB / h) * 2 * pi * 1e-9 options : :class:`qutip.Odeoptions` options for the ODE solver. Returns ------- output : :class:`qutip.Odedata` An instance of the class :class:`qutip.Odedata`, which contains either an *array* of expectation values for the times specified by `tlist`. """ if T == None: T = max(tlist) if len(spectra_cb) == 0: for n in range(len(c_ops)): spectra_cb.append( lambda w: 1.0) # add white noise callbacks if absent f_modes_0, f_energies = floquet_modes(H, T, args) kmax = 1 f_modes_table_t = floquet_modes_table(f_modes_0, f_energies, np.linspace(0, T, 500 + 1), H, T, args) # get w_th from args if it exists if args.has_key('w_th'): w_th = args['w_th'] else: w_th = 0 # TODO: loop over input c_ops and spectra_cb, calculate one R for each set # calculate the rate-matrices for the floquet-markov master equation Delta, X, Gamma, Amat = floquet_master_equation_rates( f_modes_0, f_energies, c_ops[0], H, T, args, spectra_cb[0], w_th, kmax, f_modes_table_t) # the floquet-markov master equation tensor R = floquet_master_equation_tensor(Amat, f_energies) return floquet_markov_mesolve(R, f_modes_0, rho0, tlist, e_ops, options)
def floquet_markov_mesolve(R, ekets, rho0, tlist, e_ops, options=None): """ Solve the dynamics for the system using the Floquet-Markov master equation. """ if options == None: opt = Odeoptions() else: opt = options if opt.tidy: R.tidyup() # # check initial state # if isket(rho0): # Got a wave function as initial state: convert to density matrix. rho0 = ket2dm(rho0) # # prepare output array # n_tsteps = len(tlist) dt = tlist[1] - tlist[0] output = Odedata() output.times = tlist if isinstance(e_ops, FunctionType): n_expt_op = 0 expt_callback = True elif isinstance(e_ops, list): n_expt_op = len(e_ops) expt_callback = False if n_expt_op == 0: output.states = [] else: output.expect = [] output.num_expect = n_expt_op for op in e_ops: if op.isherm: output.expect.append(np.zeros(n_tsteps)) else: output.expect.append(np.zeros(n_tsteps, dtype=complex)) else: raise TypeError("Expectation parameter must be a list or a function") # # transform the initial density matrix and the e_ops opterators to the # eigenbasis: from computational basis to the floquet basis # if ekets != None: rho0 = rho0.transform(ekets, True) if isinstance(e_ops, list): for n in np.arange(len(e_ops)): # not working e_ops[n] = e_ops[n].transform(ekets) # # # setup integrator # initial_vector = mat2vec(rho0.full()) r = scipy.integrate.ode(cyq_ode_rhs) r.set_f_params(R.data.data, R.data.indices, R.data.indptr) r.set_integrator('zvode', method=opt.method, order=opt.order, atol=opt.atol, rtol=opt.rtol, max_step=opt.max_step) r.set_initial_value(initial_vector, tlist[0]) # # start evolution # rho = Qobj(rho0) t_idx = 0 for t in tlist: if not r.successful(): break rho.data = vec2mat(r.y) if expt_callback: # use callback method e_ops(t, Qobj(rho)) else: # calculate all the expectation values, or output rho if no operators if n_expt_op == 0: output.states.append(Qobj(rho)) # copy psi/rho else: for m in range(0, n_expt_op): output.expect[m][t_idx] = expect(e_ops[m], rho) # basis OK? r.integrate(r.t + dt) t_idx += 1 return output
def mesolve(H, rho0, tlist, c_ops, expt_ops, args={}, options=None): """ Master equation evolution of a density matrix for a given Hamiltonian. Evolve the state vector or density matrix (`rho0`) using a given Hamiltonian (`H`) and an [optional] set of collapse operators (`c_op_list`), by integrating the set of ordinary differential equations that define the system. In the absense of collase operators the system is evolved according to the unitary evolution of the Hamiltonian. The output is either the state vector at arbitrary points in time (`tlist`), or the expectation values of the supplied operators (`expt_ops`). If expt_ops is a callback function, it is invoked for each time in `tlist` with time and the state as arguments, and the function does not use any return values. **Time-dependent operators** For problems with time-dependent problems `H` and `c_ops` can be callback functions that takes two arguments, time and `args`, and returns the Hamiltonian or Liuovillian for the system at that point in time (*callback format*). Alternatively, `H` and `c_ops` can be a specified in a nested-list format where each element in the list is a list of length 2, containing an operator (:class:`qutip.Qobj`) at the first element and where the second element is either a string (*list string format*) or a callback function (*list callback format*) that evaluates to the time-dependent coefficient for the corresponding operator. *Examples* H = [[H0, 'sin(w*t)'], [H1, 'sin(2*w*t)']] H = [[H0, f0_t], [H1, f1_t]] where f0_t and f1_t are python functions with signature f_t(t, args). In the *list string format* and *list callback format*, the string expression and the callback function must evaluate to a real or complex number (coefficient for the corresponding operator). In all cases of time-dependent operators, `args` is a dictionary of parameters that is used when evaluating operators. It is passed to the callback functions as second argument .. note:: On using callback function: mesolve transforms all :class:`qutip.Qobj` objects to sparse matrices before handing the problem to the integrator function. In order for your callback function to work correctly, pass all :class:`qutip.Qobj` objects that are used in constructing the Hamiltonian via args. odesolve will check for :class:`qutip.Qobj` in `args` and handle the conversion to sparse matrices. All other :class:`qutip.Qobj` objects that are not passed via `args` will be passed on to the integrator to scipy who will raise an NotImplemented exception. Parameters ---------- H : :class:`qutip.Qobj` system Hamiltonian, or a callback function for time-dependent Hamiltonians. rho0 : :class:`qutip.Qobj` initial density matrix or state vector (ket). tlist : *list* / *array* list of times for :math:`t`. c_ops : list of :class:`qutip.Qobj` list of collapse operators. expt_ops : list of :class:`qutip.Qobj` / callback function list of operators for which to evaluate expectation values. args : *dictionary* dictionary of parameters for time-dependent Hamiltonians and collapse operators. options : :class:`qutip.Qdeoptions` with options for the ODE solver. Returns ------- output: :class:`qutip.Odedata` An instance of the class :class:`qutip.Odedata`, which contains either an *array* of expectation values for the times specified by `tlist`, or an *array* or state vectors or density matrices corresponding to the times in `tlist` [if `expt_ops` is an empty list], or nothing if a callback function was given inplace of operators for which to calculate the expectation values. """ # check for type (if any) of time-dependent inputs n_const,n_func,n_str=_ode_checks(H,c_ops) if options == None: _reset_odeconfig() options = Odeoptions() options.max_step = max(tlist)/10.0 # take at least 10 steps. # # dispatch the appropriate solver # if (c_ops and len(c_ops) > 0) or not isket(rho0): # # we have collapse operators # # # find out if we are dealing with all-constant hamiltonian and # collapse operators or if we have at least one time-dependent # operator. Then delegate to appropriate solver... # if isinstance(H, Qobj): # constant hamiltonian if n_func == 0 and n_str == 0: # constant collapse operators return mesolve_const(H, rho0, tlist, c_ops, expt_ops, args, options) elif n_str > 0: # constant hamiltonian but time-dependent collapse operators in list string format return mesolve_list_str_td([H], rho0, tlist, c_ops, expt_ops, args, options) elif n_func > 0: # constant hamiltonian but time-dependent collapse operators in list function format return mesolve_list_func_td([H], rho0, tlist, c_ops, expt_ops, args, options) if isinstance(H, FunctionType): # old style time-dependence: must have constant collapse operators if n_str > 0: # or n_func > 0: raise TypeError("Incorrect format: function-format Hamiltonian cannot be mixed with time-dependent collapse operators.") else: return mesolve_func_td(H, rho0, tlist, c_ops, expt_ops, args, options) if isinstance(H, list): # determine if we are dealing with list of [Qobj, string] or [Qobj, function] # style time-dependences (for pure python and cython, respectively) if n_func > 0: return mesolve_list_func_td(H, rho0, tlist, c_ops, expt_ops, args, options) else: return mesolve_list_str_td(H, rho0, tlist, c_ops, expt_ops, args, options) raise TypeError("Incorrect specification of Hamiltonian or collapse operators.") else: # # no collapse operators: unitary dynamics # if n_func > 0: return wfsolve_list_func_td(H, rho0, tlist, expt_ops, args, options) elif n_str > 0: return wfsolve_list_str_td(H, rho0, tlist, expt_ops, args, options) elif isinstance(H, FunctionType): return wfsolve_func_td(H, rho0, tlist, expt_ops, args, options) else: return wfsolve_const(H, rho0, tlist, expt_ops, args, options)
def mcsolve(H, psi0, tlist, c_ops, e_ops, ntraj=500, args={}, options=Odeoptions()): """Monte-Carlo evolution of a state vector :math:`|\psi \\rangle` for a given Hamiltonian and sets of collapse operators, and possibly, operators for calculating expectation values. Options for the underlying ODE solver are given by the Odeoptions class. mcsolve supports time-dependent Hamiltonians and collapse operators using either Python functions of strings to represent time-dependent coefficients. Note that, the system Hamiltonian MUST have at least one constant term. As an example of a time-dependent problem, consider a Hamiltonian with two terms ``H0`` and ``H1``, where ``H1`` is time-dependent with coefficient ``sin(w*t)``, and collapse operators ``C0`` and ``C1``, where ``C1`` is time-dependent with coeffcient ``exp(-a*t)``. Here, w and a are constant arguments with values ``W`` and ``A``. Using the Python function time-dependent format requires two Python functions, one for each collapse coefficient. Therefore, this problem could be expressed as:: def H1_coeff(t,args): return sin(args['w']*t) def C1_coeff(t,args): return exp(-args['a']*t) H=[H0,[H1,H1_coeff]] c_op_list=[C0,[C1,C1_coeff]] args={'a':A,'w':W} or in String (Cython) format we could write:: H=[H0,[H1,'sin(w*t)']] c_op_list=[C0,[C1,'exp(-a*t)']] args={'a':A,'w':W} Constant terms are preferably placed first in the Hamiltonian and collapse operator lists. Parameters ---------- H : qobj System Hamiltonian. psi0 : qobj Initial state vector tlist : array_like Times at which results are recorded. ntraj : int Number of trajectories to run. c_ops : array_like ``list`` or ``array`` of collapse operators. e_ops : array_like ``list`` or ``array`` of operators for calculating expectation values. args : dict Arguments for time-dependent Hamiltonian and collapse operator terms. options : Odeoptions Instance of ODE solver options. Returns ------- results : Odedata Object storing all results from simulation. """ if psi0.type != 'ket': raise Exception("Initial state must be a state vector.") odeconfig.options = options #set num_cpus to the value given in qutip.settings if none in Odeoptions if not odeconfig.options.num_cpus: odeconfig.options.num_cpus = qutip.settings.num_cpus #set initial value data if options.tidy: odeconfig.psi0 = psi0.tidyup(options.atol).full() else: odeconfig.psi0 = psi0.full() odeconfig.psi0_dims = psi0.dims odeconfig.psi0_shape = psi0.shape #set general items odeconfig.tlist = tlist if isinstance(ntraj, (list, ndarray)): odeconfig.ntraj = sort(ntraj)[-1] else: odeconfig.ntraj = ntraj #---- #---------------------------------------------- # SETUP ODE DATA IF NONE EXISTS OR NOT REUSING #---------------------------------------------- if (not options.rhs_reuse) or (not odeconfig.tdfunc): #reset odeconfig collapse and time-dependence flags to default values _reset_odeconfig() #check for type of time-dependence (if any) time_type, h_stuff, c_stuff = _ode_checks(H, c_ops, 'mc') h_terms = len(h_stuff[0]) + len(h_stuff[1]) + len(h_stuff[2]) c_terms = len(c_stuff[0]) + len(c_stuff[1]) + len(c_stuff[2]) #set time_type for use in multiprocessing odeconfig.tflag = time_type #-Check for PyObjC on Mac platforms if sys.platform == 'darwin': try: import Foundation except: odeconfig.options.gui = False #check if running in iPython and using Cython compiling (then no GUI to work around error) if odeconfig.options.gui and odeconfig.tflag in array([1, 10, 11]): try: __IPYTHON__ except: pass else: odeconfig.options.gui = False if qutip.settings.qutip_gui == "NONE": odeconfig.options.gui = False #check for collapse operators if c_terms > 0: odeconfig.cflag = 1 else: odeconfig.cflag = 0 #Configure data _mc_data_config(H, psi0, h_stuff, c_ops, c_stuff, args, e_ops, options) if odeconfig.tflag in array([1, 10, 11]): #compile time-depdendent RHS code os.environ['CFLAGS'] = '-w' import pyximport pyximport.install( setup_args={'include_dirs': [numpy.get_include()]}) if odeconfig.tflag in array([1, 11]): code = compile( 'from ' + odeconfig.tdname + ' import cyq_td_ode_rhs,col_spmv,col_expect', '<string>', 'exec') exec(code, globals()) odeconfig.tdfunc = cyq_td_ode_rhs odeconfig.colspmv = col_spmv odeconfig.colexpect = col_expect else: code = compile( 'from ' + odeconfig.tdname + ' import cyq_td_ode_rhs', '<string>', 'exec') exec(code, globals()) odeconfig.tdfunc = cyq_td_ode_rhs try: os.remove(odeconfig.tdname + ".pyx") except: print("Error removing pyx file. File not found.") elif odeconfig.tflag == 0: odeconfig.tdfunc = cyq_ode_rhs else: #setup args for new parameters when rhs_reuse=True and tdfunc is given #string based if odeconfig.tflag in array([1, 10, 11]): if any(args): odeconfig.c_args = [] arg_items = args.items() for k in range(len(args)): odeconfig.c_args.append(arg_items[k][1]) #function based elif odeconfig.tflag in array([2, 3, 20, 22]): odeconfig.h_func_args = args #load monte-carlo class mc = MC_class() #RUN THE SIMULATION mc.run() #AFTER MCSOLVER IS DONE -------------------------------------- #-------COLLECT AND RETURN OUTPUT DATA IN ODEDATA OBJECT --------------# output = Odedata() output.solver = 'mcsolve' #state vectors if any(mc.psi_out) and odeconfig.options.mc_avg: output.states = mc.psi_out #expectation values if any( mc.expect_out ) and odeconfig.cflag and odeconfig.options.mc_avg: #averaging if multiple trajectories if isinstance(ntraj, int): output.expect = mean(mc.expect_out, axis=0) elif isinstance(ntraj, (list, ndarray)): output.expect = [] for num in ntraj: expt_data = mean(mc.expect_out[:num], axis=0) data_list = [] if any([op.isherm == False for op in e_ops]): for k in range(len(e_ops)): if e_ops[k].isherm: data_list.append(real(expt_data[k])) else: data_list.append(expt_data[k]) else: data_list = [data for data in expt_data] output.expect.append(data_list) else: #no averaging for single trajectory or if mc_avg flag (Odeoptions) is off output.expect = mc.expect_out #simulation parameters output.times = odeconfig.tlist output.num_expect = odeconfig.e_num output.num_collapse = odeconfig.c_num output.ntraj = odeconfig.ntraj output.col_times = mc.collapse_times_out output.col_which = mc.which_op_out return output
def propagator(H, t, c_op_list, H_args=None, opt=None): """ Calculate the propagator U(t) for the density matrix or wave function such that :math:`\psi(t) = U(t)\psi(0)` or :math:`\\rho_{\mathrm vec}(t) = U(t) \\rho_{\mathrm vec}(0)` where :math:`\\rho_{\mathrm vec}` is the vector representation of the density matrix. Parameters ---------- H : qobj Hamiltonian t : float Time. c_op_list : list List of qobj collapse operators. Other Parameters ---------------- H_args : list/array/dictionary Parameters to callback functions for time-dependent Hamiltonians. Returns ------- a : qobj Instance representing the propagator :math:`U(t)`. """ if opt == None: opt = Odeoptions() opt.rhs_reuse = True if len(c_op_list) == 0: # calculate propagator for the wave function if isinstance(H, FunctionType): H0 = H(0.0, H_args) N = H0.shape[0] elif isinstance(H, list): if isinstance(H[0], list): H0 = H[0][0] N = H0.shape[0] else: H0 = H[0] N = H0.shape[0] else: N = H.shape[0] u = zeros([N, N], dtype=complex) for n in range(0, N): psi0 = basis(N, n) output = mesolve(H, psi0, [0, t], [], [], H_args, opt) u[:,n] = output.states[1].full().T # todo: evolving a batch of wave functions: #psi_0_list = [basis(N, n) for n in range(N)] #psi_t_list = mesolve(H, psi_0_list, [0, t], [], [], H_args, opt) #for n in range(0, N): # u[:,n] = psi_t_list[n][1].full().T else: # calculate the propagator for the vector representation of the # density matrix if isinstance(H, FunctionType): H0 = H(0.0, H_args) N = H0.shape[0] elif isinstance(H, list): if isinstance(H[0], list): H0 = H[0][0] N = H0.shape[0] else: H0 = H[0] N = H0.shape[0] else: N = H.shape[0] u = zeros([N*N, N*N], dtype=complex) for n in range(0, N*N): psi0 = basis(N*N, n) rho0 = Qobj(vec2mat(psi0.full())) output = mesolve(H, rho0, [0, t], c_op_list, [], H_args, opt) u[:,n] = mat2vec(output.states[1].full()).T return Qobj(u)
def odesolve(H, rho0, tlist, c_op_list, expt_ops, H_args=None, options=None): """ Master equation evolution of a density matrix for a given Hamiltonian. Evolution of a state vector or density matrix (`rho0`) for a given Hamiltonian (`H`) and set of collapse operators (`c_op_list`), by integrating the set of ordinary differential equations that define the system. The output is either the state vector at arbitrary points in time (`tlist`), or the expectation values of the supplied operators (`expt_ops`). For problems with time-dependent Hamiltonians, `H` can be a callback function that takes two arguments, time and `H_args`, and returns the Hamiltonian at that point in time. `H_args` is a list of parameters that is passed to the callback function `H` (only used for time-dependent Hamiltonians). Parameters ---------- H : :class:`qutip.Qobj` system Hamiltonian, or a callback function for time-dependent Hamiltonians. rho0 : :class:`qutip.Qobj` initial density matrix or state vector (ket). tlist : *list* / *array* list of times for :math:`t`. c_op_list : list of :class:`qutip.Qobj` list of collapse operators. expt_ops : list of :class:`qutip.Qobj` / callback function list of operators for which to evaluate expectation values. H_args : *dictionary* dictionary of parameters for time-dependent Hamiltonians and collapse operators. options : :class:`qutip.Qdeoptions` with options for the ODE solver. Returns ------- output :array Expectation values of wavefunctions/density matrices for the times specified by `tlist`. Notes ----- On using callback function: odesolve transforms all :class:`qutip.Qobj` objects to sparse matrices before handing the problem to the integrator function. In order for your callback function to work correctly, pass all :class:`qutip.Qobj` objects that are used in constructing the Hamiltonian via H_args. odesolve will check for :class:`qutip.Qobj` in `H_args` and handle the conversion to sparse matrices. All other :class:`qutip.Qobj` objects that are not passed via `H_args` will be passed on to the integrator to scipy who will raise an NotImplemented exception. Deprecated in QuTiP 2.0.0. Use :func:`mesolve` instead. """ if options == None: options = Odeoptions() if (c_op_list and len(c_op_list) > 0) or not isket(rho0): if isinstance(H, list): output = _mesolve_list_td(H, rho0, tlist, c_op_list, expt_ops, H_args, options) if isinstance(H, types.FunctionType): output = _mesolve_func_td(H, rho0, tlist, c_op_list, expt_ops, H_args, options) else: output = _mesolve_const(H, rho0, tlist, c_op_list, expt_ops, H_args, options) else: if isinstance(H, list): output = _wfsolve_list_td(H, rho0, tlist, expt_ops, H_args, options) if isinstance(H, types.FunctionType): output = _wfsolve_func_td(H, rho0, tlist, expt_ops, H_args, options) else: output = _wfsolve_const(H, rho0, tlist, expt_ops, H_args, options) if len(expt_ops) > 0: return output.expect else: return output.states