Grover
class Grover(iterations=None, growth_rate=None, sample_from_iterations=False, quantum_instance=None)
Bases: qiskit.algorithms.amplitude_amplifiers.amplitude_amplifier.AmplitudeAmplifier
Grover’s Search algorithm.
Grover’s Search [1, 2] is a well known quantum algorithm that can be used for searching through unstructured collections of records for particular targets with quadratic speedup compared to classical algorithms.
Given a set of elements and a boolean function , the goal of an unstructured-search problem is to find an element such that .
The search is called unstructured because there are no guarantees as to how the database is ordered. On a sorted database, for instance, one could perform binary search to find an element in worst-case time. Instead, in an unstructured-search problem, there is no prior knowledge about the contents of the database. With classical circuits, there is no alternative but to perform a linear number of queries to find the target element. Conversely, Grover’s Search algorithm allows to solve the unstructured-search problem on a quantum computer in queries.
To carry out this search a so-called oracle is required, that flags a good element/state. The action of the oracle is
i.e. it flips the phase of the state if is a hit. The details of how works are unimportant to the algorithm; Grover’s search algorithm treats the oracle as a black box.
This class supports oracles in form of a QuantumCircuit
.
With the given oracle, Grover’s Search constructs the Grover operator to amplify the amplitudes of the good states:
where flips the phase of the all-zero state and acts as identity on all other states. Sometimes the first three operands are summarized as diffusion operator, which implements a reflection over the equal superposition state.
If the number of solutions is known, we can calculate how often should be applied to find a solution with very high probability, see the method optimal_num_iterations. If the number of solutions is unknown, the algorithm tries different powers of Grover’s operator, see the iterations argument, and after each iteration checks if a good state has been measured using good_state.
The generalization of Grover’s Search, Quantum Amplitude Amplification [3], uses a modified version of where the diffusion operator does not reflect about the equal superposition state, but another state specified via an operator :
For more information, see the GroverOperator
in the circuit library.
References
[1]: L. K. Grover (1996), A fast quantum mechanical algorithm for database search,
[2]: I. Chuang & M. Nielsen, Quantum Computation and Quantum Information,
Cambridge: Cambridge University Press, 2000. Chapter 6.1.2.
[3]: Brassard, G., Hoyer, P., Mosca, M., & Tapp, A. (2000).
Quantum Amplitude Amplification and Estimation. arXiv:quant-ph/0005055.
Parameters
- iterations (
Union
[List
[int
],Iterator
[int
],int
,None
]) – Specify the number of iterations/power of Grover’s operator to be checked. * If an int, only one circuit is run with that power of the Grover operator. If the number of solutions is known, this option should be used with the optimal power. The optimal power can be computed withGrover.optimal_num_iterations
. * If a list, all the powers in the list are run in the specified order. * If an iterator, the powers yielded by the iterator are checked, until a maximum number of iterations or maximum power is reached. * IfNone
, theAmplificationProblem
provided must have anis_good_state
, and circuits are run until that good state is reached. - growth_rate (
Optional
[float
]) – If specified, the iterator is set to increasing powers ofgrowth_rate
, i.e. toint(growth_rate ** 1), int(growth_rate ** 2), ...
until a maximum number of iterations is reached. - sample_from_iterations (
bool
) – If True, instead of taking the values initerations
as powers of the Grover operator, a random integer sample between 0 and smaller value than the iteration is used as a power, see [1], Section 4. - quantum_instance (
Union
[QuantumInstance
,Backend
,BaseBackend
,None
]) – A Quantum Instance or Backend to run the circuits.
Raises
- ValueError – If
growth_rate
is a float but not larger than 1. - ValueError – If both
iterations
andgrowth_rate
is set.
References
[1]: Boyer et al., Tight bounds on quantum searching
https://arxiv.org/abs/quant-ph/9605034
Methods
amplify
Grover.amplify(amplification_problem)
Run the Grover algorithm.
Parameters
amplification_problem (AmplificationProblem
) – The amplification problem.
Return type
GroverResult
Returns
The result as a GroverResult
, where e.g. the most likely state can be queried as result.top_measurement
.
Raises
- TypeError – If
is_good_state
is not provided and is required (i.e. when iterations - is None** or a list)** –
construct_circuit
Grover.construct_circuit(problem, power=None, measurement=False)
Construct the circuit for Grover’s algorithm with power
Grover operators.
Parameters
- problem (
AmplificationProblem
) – The amplification problem for the algorithm. - power (
Optional
[int
]) – The number of times the Grover operator is repeated. If None, this argument is set to the first item initerations
. - measurement (
bool
) – Boolean flag to indicate if measurement should be included in the circuit.
Returns
the QuantumCircuit object for the constructed circuit
Return type
Raises
ValueError – If no power is passed and the iterations are not an integer.
optimal_num_iterations
static Grover.optimal_num_iterations(num_solutions, num_qubits)
Return the optimal number of iterations, if the number of solutions is known.
Parameters
- num_solutions (
int
) – The number of solutions. - num_qubits (
int
) – The number of qubits used to encode the states.
Return type
int
Returns
The optimal number of iterations for Grover’s algorithm to succeed.
Attributes
quantum_instance
Get the quantum instance. :rtype: Optional
[QuantumInstance
] :returns: The quantum instance used to run this algorithm.