qat.opt.MaxCut
- class qat.opt.MaxCut(graph, **kwargs)
Specialization of the
Isingclass for Max Cut.This class allows for the encoding of a Max Cut problem for a given graph. The method
produce_j_h_and_offset()is automatically called. It calculates the coupling matrix \(J\), magnetic field \(h\) and Ising energy offset corresponding to the Hamiltonian representation of the problem, as described in the reference. These are stored in the parent classIsingand would be needed if one wishes to solve the problem through Simulated Annealing (SA), for instance - see the Max Cut notebook.- Reference
import networkx as nx from qat.opt import MaxCut graph = nx.full_rary_tree(2, 2**8) maxcut = MaxCut(graph) print("To anneal the problem, the solver would need " + str(len(graph.nodes())) + " spins.")
To anneal the problem, the solver would need 256 spins.
- Parameters
graph (networkx.Graph) – a networkx graph
- get_best_parameters()
This method returns a dictionary with the best found parameters (after benchmarking) for simulated quantum annealing (SQA), available in the QLM. However, the temperature parameters could also be used for simulated annealing (SA).
- Returns
6-key dictionary containing
n_monte_carlo_updates (int) - the number of Monte Carlo updates
n_trotters (int) - the number of “classical replicas” or “Trotter replicas”
gamma_max (double) - the starting magnetic field
gamma_min (double) - the final magnetic field
temp_max (double) - the starting temperature
temp_min (double) - the final temperature
- parse_result(result, inverse=False)
Returns the best approximated solution of the Max Cut problem from a list of samples
- Parameters
result (
BatchResult) – BatchResult containing a list of samples- Returns
The best partition among the samples with the maximum cut size
- Return type
- qat.opt.max_cut.produce_j_h_and_offset(graph)
Returns the \(J\) coupling matrix of the problem, along with the magnetic field \(h\) and the Ising energy offset.
- Parameters
graph (networkx.Graph) – a networkx graph