F1 = 3 - (np.sin(2 * a_beta)**2 * np.sin(2 * a_gamma)**2 - 0.5 * np.sin(
4 * a_beta) * np.sin(4 * a_gamma)) * (1 + np.cos(4 * a_gamma)**2)
result = np.where(F1 == np.amax(F1))
a = list(zip(result[0], result[1]))[0]
gamma = a[0] * step_size
beta = a[1] * step_size
prog = make_circuit(4)
sample_shot = 3962
writefile = open("../data/startQiskit_QC263.csv", "w")
# prog.draw('mpl', filename=(kernel + '.png'))
IBMQ.load_account()
provider = IBMQ.get_provider(hub='ibm-q')
provider.backends()
backend = provider.get_backend("ibmq_5_yorktown")
circuit1 = transpile(prog, FakeYorktown())
circuit1.measure_all()
prog = circuit1
info = execute(prog, backend=backend,
shots=sample_shot).result().get_counts()
print(info, file=writefile)
print("results end", file=writefile)
print(circuit1.depth(), file=writefile)
print(circuit1, file=writefile)
writefile.close()
# -*- coding: utf-8 -*-
"""
Created Nov 2020
@author: hassi
"""
from qiskit import QuantumCircuit, execute
from qiskit import IBMQ
from qiskit.tools.monitor import job_monitor
from IPython.core.display import display
print("Getting provider...")
if not IBMQ.active_account():
IBMQ.load_account()
provider = IBMQ.get_provider()
print("Ch 4: Quantum coin toss on IBM Q backend")
print("----------------------------------------")
qc = QuantumCircuit(2, 2)
qc.h(0)
qc.cx(0, 1)
qc.measure([0, 1], [0, 1])
display(qc.draw('mpl'))
from qiskit.providers.ibmq import least_busy
backend = least_busy(
provider.backends(n_qubits=5, operational=True, simulator=False))
# In[10]:
result = execute(circuit, backend = simulator).result()
# In[11]:
plot_histogram(result.get_counts(circuit))
# In[12]:
provider = IBMQ.get_provider('ibm-q')
# In[14]:
qcomp = provider.get_backend('ibmq_16_melbourne')
# In[15]:
job = execute(circuit, backend = qcomp)
# In[ ]:
from qiskit import IBMQ, Aer
from qiskit import QuantumCircuit, QuantumRegister, ClassicalRegister
import matplotlib.pyplot as plt
import os
from rwutil import *
OUTPUT = "output"
IBMQ.load_account()
Prov = IBMQ.get_provider(group='open')
BACKENDS = {
'qasm_simulator': (Aer.get_backend('qasm_simulator'), True),
'ibmq_qasm_simulator': (Prov.get_backend('ibmq_qasm_simulator'), False),
'ibmq_london': (Prov.get_backend('ibmq_qasm_simulator'), False),
'ibmq_vigo': (Prov.get_backend('ibmq_qasm_simulator'), False)
}
SHOTS = 1000
T = [*range(0, 5)]
def shift_gate():
q = QuantumRegister(3)
circuit = QuantumCircuit(q, name='shift')
circuit.ccx(0, 1, 2)
circuit.cx(0, 1)
circuit.x(0)
circuit.x(1)
circuit.ccx(0, 1, 2)
# uncompute
for i in range(self.n - 1, 1, -1):
self.circ.ccx(self.ctrl[i], self.anc[i - 2], self.anc[i - 1])
self.circ.ccx(self.ctrl[0], self.ctrl[1], self.anc[0])
def calc_theta(self, p1, p0):
return 2 * np.arctan(np.sqrt((p1) / (p0)))
#if __name__=='__main__':
from jupyterthemes import jtplot
jtplot.style(theme='monokai', context='notebook', ticks=True, grid=False)
from qiskit.tools.jupyter import *
from qiskit import IBMQ
IBMQ.load_account()
# provider = IBMQ.get_provider(hub='ibm-q', group='open', project='main')
provider = IBMQ.get_provider(hub='ibm-q-oxford',
group='on-boarding',
project='on-boarding-proj')
from qiskit import BasicAer
backend = BasicAer.get_backend('unitary_simulator')
n = 3
parents = np.random.rand(n * 2)
child = np.random.rand(2**(n + 1))
b = byskit(provider, backend, n, parents, child)
def _initialize_backend(self, backend="ibmq_qasm_simulator"):
#self.backend = IBMQ.get_backend(backend)
#TO-DO once IBMQ.get_provider() actually works use that
self.backend = IBMQ.get_provider().get_backend(backend)
# **1.3. Experimento:** Cuando un qubit esta inicializado en $|0>\rangle$ el resultado de la medición debe ser, en teoria, siempre $|0>\rangle$(con probabilidad del 100%). 1000 shots en computador cuantico real
# In[14]:
from qiskit import IBMQ
IBMQ.load_account()
# In[17]:
#Ejecución en un computador cuantico real
proveedor = IBMQ.get_provider('ibm-q')
comp_cuantico = proveedor.get_backend('ibmq_burlington')
ejecucion = execute(circuito_12, backend=comp_cuantico,shots=1000)
from qiskit.tools.monitor import job_monitor
job_monitor(ejecucion)
resultado = ejecucion.result()
conteos = resultado.get_counts()
print(conteos)
# In[20]:
if not backend:
backend = Aer.get_backend('qasm_simulator')
elif type(backend) == str:
if 'state' in backend:
backend = Aer.get_backend('statevector_simulator')
state_vector = execute(circuit, backend).result().get_statevector()
return state_vector
else:
try:
from warnings import filterwarnings
filterwarnings("ignore")
IBMQ.load_account()
provider = IBMQ.get_provider("ibm-q")
backend = provider.get_backend(backend)
except Exception as e:
print(f'Error: could not get IBMQ provider, {e}')
assert None
if display_job_status:
print(f'running on: {backend.name()}')
if measure:
circuit.measure(range(len(circuit.clbits)), range(len(circuit.clbits)))
if draw:
print(circuit.draw())
circuit.data = [e for e in circuit.data if type(e[0]) != Barrier]
import numpy as np
from qiskit import IBMQ
from qiskit import pulse # This is where we access all of our Pulse features!
from qiskit.pulse import Play
from qiskit.pulse import pulse_lib # This Pulse module helps us build sampled pulses for common pulse shapes
from qiskit import assemble
from qiskit.tools.monitor import job_monitor
"""
Программа для сбора данных с квантовго компьютера IBM Armonk
"""
IBMQ.load_account()
provider = IBMQ.get_provider(hub='ibm-q', group='open', project='main')
backend = provider.get_backend('ibmq_armonk')
backend_config = backend.configuration()
assert backend_config.open_pulse, "Backend doesn't support Pulse"
dt = backend_config.dt
print(f"Sampling time: {dt * 1e9} ns")
backend_defaults = backend.defaults()
qubit = 0
# достаем из текстового файла частоту кубита и амплитуду pi импулса
with open("qubit_params.txt", "r") as f:
rough_qubit_frequency, pi_amp = list(map(lambda x: float(x.strip()), f.readlines()))
us = 1.0e-6 # Microseconds
scale_factor = 1e-14
from functions import QuantumNeuralNetwork, EffectiveDimension
from qiskit.aqua import QuantumInstance
from qiskit import IBMQ, Aer
from qiskit.circuit.library import ZFeatureMap, RealAmplitudes
from qiskit.providers.aer.noise.noise_model import NoiseModel
import numpy as np
TOKEN = 'insert token here'
IBMQ.save_account(TOKEN, overwrite=True)
provider = IBMQ.load_account()
provider = IBMQ.get_provider(hub='ibm-q-internal', group='deployed', project='default')
backend_name = 'ibmq_montreal'
backend_ibmq = provider.get_backend(backend_name)
properties = backend_ibmq.properties()
coupling_map = backend_ibmq.configuration().coupling_map
noise_model = NoiseModel.from_backend(properties)
layout = [1, 2, 3, 5, 8, 11, 14, 13, 12, 10]
qi_ibmq_noise_model = QuantumInstance(backend=Aer.get_backend('qasm_simulator'),
noise_model=noise_model, optimization_level=0, shots=8000,
seed_transpiler=2, initial_layout=layout)
qi = qi_ibmq_noise_model
compile_config = {'initial_layout': layout,
'seed_transpiler': 2,
'optimization_level': 3
}
n = [1000, 2000, 8000, 10000, 40000, 60000, 100000, 150000, 200000, 500000, 1000000, 10000000, 10000000000, 10000000000000]
qubits = 10
fm = ZFeatureMap(qubits, reps=1)
varform = RealAmplitudes(qubits, reps=9, entanglement='full')
qnet = QuantumNeuralNetwork(fm, varform)
ed = EffectiveDimension(qnet, 100, 100)
