Construir una plantilla de función para simulación de Hamiltoniano
Esta plantilla encapsula un flujo de trabajo para simular la evolución temporal de un estado inicial respecto a un Hamiltoniano de espín definido por el usuario, y devuelve un conjunto de valores de expectación especificados usando el complemento AQC.
Esta plantilla está estructurada como un patrón de Qiskit con los siguientes pasos:
1. Recopilar entradas y mapear el problema
Esta sección recibe como entrada el Hamiltoniano a simular, un estado inicial en forma de QuantumCircuit, un conjunto de observables para estimar valores de expectación, y una especificación de opciones para el complemento AQC. Este paso valida que todos los datos de entrada requeridos estén presentes y en el formato correcto.
Los argumentos de entrada se usan luego para construir los circuitos cuánticos y operadores relevantes para el flujo de trabajo. Se crea un circuito objetivo y se obtiene una representación de estado producto matricial de ese circuito usando el complemento AQC. A continuación, se genera y optimiza un circuito ansatz usando métodos de redes tensoriales, produciendo un circuito final que ejecuta el resto de la evolución temporal.
2. Preparar los circuitos generados para su ejecución
Los circuitos generados por el complemento AQC se transpilan para ejecutarse en un backend elegido. Se crea una instancia de EstimatorV2 con un conjunto predeterminado de opciones de mitigación de errores para gestionar la ejecución del circuito.
3. Ejecución
Finalmente, el circuito ansatz se transpila y ejecuta en una QPU, y recopila estimaciones para todos los valores de expectación especificados, los cuales se devuelven en un formato serializable para que el usuario pueda acceder a ellos.
Escribir la plantilla de función
Primero, escribe una plantilla de función para simulación de Hamiltoniano que use el complemento AQC-Tensor de Qiskit para mapear la descripción del problema a un circuito de profundidad reducida que se pueda ejecutar en hardware.
A lo largo del proceso, el código se guarda en ./source_files/template_hamiltonian_simulation.py. Este archivo es la plantilla de función que puedes subir y ejecutar de forma remota con Qiskit Serverless.
# Added by doQumentation — required packages for this notebook
!pip install -q mergedeep numpy qiskit qiskit-addon-aqc-tensor qiskit-addon-utils qiskit-ibm-catalog qiskit-ibm-runtime qiskit-serverless quimb scipy
# This cell is hidden from users, it just creates a new folder
from pathlib import Path
Path("./source_files").mkdir(exist_ok=True)
Recopilar y validar las entradas
Comienza obteniendo las entradas para la plantilla. Este ejemplo tiene entradas específicas del dominio relevantes para la simulación de Hamiltoniano (como el Hamiltoniano y el observable) y opciones específicas de capacidad (como cuánto quieres comprimir las capas iniciales del circuito de Trotter usando AQC-Tensor, o opciones avanzadas para ajustar la supresión y mitigación de errores más allá de los valores predeterminados que forman parte de este ejemplo).
%%writefile ./source_files/template_hamiltonian_simulation.py
from qiskit import QuantumCircuit
from qiskit_serverless import get_arguments, save_result
# Extract parameters from arguments
#
# Do this at the top of the program so it fails early if any required arguments are missing or invalid.
arguments = get_arguments()
dry_run = arguments.get("dry_run", False)
backend_name = arguments["backend_name"]
aqc_evolution_time = arguments["aqc_evolution_time"]
aqc_ansatz_num_trotter_steps = arguments["aqc_ansatz_num_trotter_steps"]
aqc_target_num_trotter_steps = arguments["aqc_target_num_trotter_steps"]
remainder_evolution_time = arguments["remainder_evolution_time"]
remainder_num_trotter_steps = arguments["remainder_num_trotter_steps"]
# Stop if this fidelity is achieved
aqc_stopping_fidelity = arguments.get("aqc_stopping_fidelity", 1.0)
# Stop after this number of iterations, even if stopping fidelity is not achieved
aqc_max_iterations = arguments.get("aqc_max_iterations", 500)
hamiltonian = arguments["hamiltonian"]
observable = arguments["observable"]
initial_state = arguments.get("initial_state", QuantumCircuit(hamiltonian.num_qubits))
Writing ./source_files/template_hamiltonian_simulation.py
%%writefile --append ./source_files/template_hamiltonian_simulation.py
import numpy as np
import json
from mergedeep import merge
# Configure `EstimatorOptions`, to control the parameters of the hardware experiment
#
# Set default options
estimator_default_options = {
"resilience": {
"measure_mitigation": True,
"zne_mitigation": True,
"zne": {
"amplifier": "gate_folding",
"noise_factors": [1, 2, 3],
"extrapolated_noise_factors": list(np.linspace(0, 3, 31)),
"extrapolator": ["exponential", "linear", "fallback"],
},
"measure_noise_learning": {
"num_randomizations": 512,
"shots_per_randomization": 512,
},
},
"twirling": {
"enable_gates": True,
"enable_measure": True,
"num_randomizations": 300,
"shots_per_randomization": 100,
"strategy": "active",
},
}
# Merge with user-provided options
estimator_options = merge(
arguments.get("estimator_options", {}), estimator_default_options
)
Appending to ./source_files/template_hamiltonian_simulation.py
Cuando la plantilla de función está en ejecución, es útil devolver información en los registros mediante sentencias print, para que puedas evaluar mejor el progreso de la carga de trabajo. A continuación se muestra un ejemplo simple de cómo imprimir las estimator_options para que quede un registro de las opciones reales del Estimator utilizadas. Hay muchos más ejemplos similares a lo largo del programa para reportar el progreso durante la ejecución, incluyendo el valor de la función objetivo durante el componente iterativo de AQC-Tensor, y la profundidad de dos qubits del circuito final de arquitectura de conjunto de instrucciones (ISA) destinado a ejecutarse en hardware.
%%writefile --append ./source_files/template_hamiltonian_simulation.py
print("estimator_options =", json.dumps(estimator_options, indent=4))
Appending to ./source_files/template_hamiltonian_simulation.py
Validar las entradas
Un aspecto importante para garantizar que la plantilla pueda reutilizarse en una variedad de entradas es la validación de entradas. El siguiente código es un ejemplo de cómo verificar que la fidelidad de parada durante AQC-Tensor se haya especificado correctamente y, en caso contrario, devolver un mensaje de error informativo sobre cómo corregirlo.
%%writefile --append ./source_files/template_hamiltonian_simulation.py
# Perform parameter validation
if not 0.0 < aqc_stopping_fidelity <= 1.0:
raise ValueError(
f"Invalid stopping fidelity: {aqc_stopping_fidelity}. It must be a positive float no greater than 1."
)
Appending to ./source_files/template_hamiltonian_simulation.py
Preparar las salidas de la función
Primero, prepara un diccionario para almacenar todas las salidas de la plantilla de función. A lo largo del flujo de trabajo se irán añadiendo claves a este diccionario, y se devuelve al final del programa.
%%writefile --append ./source_files/template_hamiltonian_simulation.py
output = {}
Appending to ./source_files/template_hamiltonian_simulation.py
Mapear el problema y pre-procesar el circuito con AQC
La optimización AQC-Tensor ocurre en el paso 1 de un patrón de Qiskit. Primero se construye un estado objetivo. En este ejemplo, se construye a partir de un circuito objetivo que evoluciona el mismo Hamiltoniano durante el mismo período de tiempo que la porción AQC. Luego, se genera un ansatz a partir de un circuito equivalente pero con menos pasos de Trotter. En la parte principal del algoritmo AQC, ese ansatz se aproxima iterativamente al estado objetivo. Finalmente, el resultado se combina con el resto de los pasos de Trotter necesarios para alcanzar el tiempo de evolución deseado.
Observa los ejemplos adicionales de registro incorporados en el siguiente código.
%%writefile --append ./source_files/template_hamiltonian_simulation.py
import os
os.environ["NUMBA_CACHE_DIR"] = "/data"
import datetime
import quimb.tensor
from scipy.optimize import OptimizeResult, minimize
from qiskit.synthesis import SuzukiTrotter
from qiskit_addon_utils.problem_generators import generate_time_evolution_circuit
from qiskit_addon_aqc_tensor.ansatz_generation import (
generate_ansatz_from_circuit,
AnsatzBlock,
)
from qiskit_addon_aqc_tensor.simulation import (
tensornetwork_from_circuit,
compute_overlap,
)
from qiskit_addon_aqc_tensor.simulation.quimb import QuimbSimulator
from qiskit_addon_aqc_tensor.objective import OneMinusFidelity
print("Hamiltonian:", hamiltonian)
print("Observable:", observable)
simulator_settings = QuimbSimulator(quimb.tensor.CircuitMPS, autodiff_backend="jax")
# Construct the AQC target circuit
aqc_target_circuit = initial_state.copy()
if aqc_evolution_time:
aqc_target_circuit.compose(
generate_time_evolution_circuit(
hamiltonian,
synthesis=SuzukiTrotter(reps=aqc_target_num_trotter_steps),
time=aqc_evolution_time,
),
inplace=True,
)
# Construct matrix-product state representation of the AQC target state
aqc_target_mps = tensornetwork_from_circuit(aqc_target_circuit, simulator_settings)
print("Target MPS maximum bond dimension:", aqc_target_mps.psi.max_bond())
output["target_bond_dimension"] = aqc_target_mps.psi.max_bond()
# Generate an ansatz and initial parameters from a Trotter circuit with fewer steps
aqc_good_circuit = initial_state.copy()
if aqc_evolution_time:
aqc_good_circuit.compose(
generate_time_evolution_circuit(
hamiltonian,
synthesis=SuzukiTrotter(reps=aqc_ansatz_num_trotter_steps),
time=aqc_evolution_time,
),
inplace=True,
)
aqc_ansatz, aqc_initial_parameters = generate_ansatz_from_circuit(aqc_good_circuit)
print("Number of AQC parameters:", len(aqc_initial_parameters))
output["num_aqc_parameters"] = len(aqc_initial_parameters)
# Calculate the fidelity of ansatz circuit vs. the target state, before optimization
good_mps = tensornetwork_from_circuit(aqc_good_circuit, simulator_settings)
starting_fidelity = abs(compute_overlap(good_mps, aqc_target_mps)) ** 2
print("Starting fidelity of AQC portion:", starting_fidelity)
output["aqc_starting_fidelity"] = starting_fidelity
# Optimize the ansatz parameters by using MPS calculations
def callback(intermediate_result: OptimizeResult):
fidelity = 1 - intermediate_result.fun
print(f"{datetime.datetime.now()} Intermediate result: Fidelity {fidelity:.8f}")
if intermediate_result.fun < stopping_point:
raise StopIteration
objective = OneMinusFidelity(aqc_target_mps, aqc_ansatz, simulator_settings)
stopping_point = 1.0 - aqc_stopping_fidelity
result = minimize(
objective,
aqc_initial_parameters,
method="L-BFGS-B",
jac=True,
options={"maxiter": aqc_max_iterations},
callback=callback,
)
if result.status not in (
0,
1,
99,
): # 0 => success; 1 => max iterations reached; 99 => early termination via StopIteration
raise RuntimeError(
f"Optimization failed: {result.message} (status={result.status})"
)
print(f"Done after {result.nit} iterations.")
output["num_iterations"] = result.nit
aqc_final_parameters = result.x
output["aqc_final_parameters"] = list(aqc_final_parameters)
# Construct an optimized circuit for initial portion of time evolution
aqc_final_circuit = aqc_ansatz.assign_parameters(aqc_final_parameters)
# Calculate fidelity after optimization
aqc_final_mps = tensornetwork_from_circuit(aqc_final_circuit, simulator_settings)
aqc_fidelity = abs(compute_overlap(aqc_final_mps, aqc_target_mps)) ** 2
print("Fidelity of AQC portion:", aqc_fidelity)
output["aqc_fidelity"] = aqc_fidelity
# Construct final circuit, with remainder of time evolution
final_circuit = aqc_final_circuit.copy()
if remainder_evolution_time:
remainder_circuit = generate_time_evolution_circuit(
hamiltonian,
synthesis=SuzukiTrotter(reps=remainder_num_trotter_steps),
time=remainder_evolution_time,
)
final_circuit.compose(remainder_circuit, inplace=True)
Appending to ./source_files/template_hamiltonian_simulation.py
Optimizar el circuito final para su ejecución
Tras la porción AQC del flujo de trabajo, el final_circuit se transpila para el hardware como de costumbre.
%%writefile --append ./source_files/template_hamiltonian_simulation.py
from qiskit_ibm_runtime import QiskitRuntimeService
from qiskit.transpiler import generate_preset_pass_manager
service = QiskitRuntimeService()
backend = service.backend(backend_name)
# Transpile PUBs (circuits and observables) to match ISA
pass_manager = generate_preset_pass_manager(backend=backend, optimization_level=3)
isa_circuit = pass_manager.run(final_circuit)
isa_observable = observable.apply_layout(isa_circuit.layout)
isa_2qubit_depth = isa_circuit.depth(lambda x: x.operation.num_qubits == 2)
print("ISA circuit two-qubit depth:", isa_2qubit_depth)
output["twoqubit_depth"] = isa_2qubit_depth
Appending to ./source_files/template_hamiltonian_simulation.py
Salir anticipadamente si se usa el modo de ejecución en seco
Si se ha seleccionado el modo de ejecución en seco (dry run), el programa se detiene antes de ejecutarse en hardware. Esto puede ser útil si, por ejemplo, quieres inspeccionar primero la profundidad de dos qubits del circuito ISA antes de decidir ejecutar en hardware.
%%writefile --append ./source_files/template_hamiltonian_simulation.py
# Exit now if dry run; don't execute on hardware
if dry_run:
import sys
print("Exiting before hardware execution since `dry_run` is True.")
save_result(output)
sys.exit(0)
Appending to ./source_files/template_hamiltonian_simulation.py
Ejecutar el circuito en hardware
%%writefile --append ./source_files/template_hamiltonian_simulation.py
# ## Step 3: Execute quantum experiments on backend
from qiskit_ibm_runtime import EstimatorV2 as Estimator
estimator = Estimator(backend, options=estimator_options)
# Submit the underlying Estimator job. Note that this is not the
# actual function job.
job = estimator.run([(isa_circuit, isa_observable)])
print("Job ID:", job.job_id())
output["job_id"] = job.job_id()
# Wait until job is complete
hw_results = job.result()
hw_results_dicts = [pub_result.data.__dict__ for pub_result in hw_results]
# Save hardware results to serverless output dictionary
output["hw_results"] = hw_results_dicts
# Reorganize expectation values
hw_expvals = [pub_result_data["evs"].tolist() for pub_result_data in hw_results_dicts]
# Save expectation values to Qiskit Serverless
print("Hardware expectation values", hw_expvals)
output["hw_expvals"] = hw_expvals[0]
Appending to ./source_files/template_hamiltonian_simulation.py
Guardar la salida
Esta plantilla de función devuelve la salida relevante a nivel de dominio para este flujo de trabajo de simulación de Hamiltoniano (valores de expectación), además de metadatos importantes generados a lo largo del proceso.
%%writefile --append ./source_files/template_hamiltonian_simulation.py
save_result(output)
Appending to ./source_files/template_hamiltonian_simulation.py
Desplegar la función en IBM Quantum Platform
La sección anterior creó un programa para ejecutarse de forma remota. El código de esta sección sube ese programa a Qiskit Serverless.
Usa qiskit-ibm-catalog para autenticarte en QiskitServerless con tu clave API, que puedes encontrar en el panel de IBM Quantum Platform, y sube el programa.
Opcionalmente, puedes usar save_account() para guardar tus credenciales (consulta la guía Configura tu cuenta de IBM Cloud). Ten en cuenta que esto escribe tus credenciales en el mismo archivo que QiskitRuntimeService.save_account().
from qiskit_ibm_catalog import QiskitServerless, QiskitFunction
# Authenticate to the remote cluster and submit the pattern for remote execution
serverless = QiskitServerless()
Este programa tiene dependencias pip personalizadas. Agrégalas a un arreglo dependencies al construir la instancia de QiskitFunction:
template = QiskitFunction(
title="template_hamiltonian_simulation",
entrypoint="template_hamiltonian_simulation.py",
working_dir="./source_files/",
dependencies=[
"qiskit-addon-utils~=0.1.0",
"qiskit-addon-aqc-tensor[quimb-jax]~=0.1.2",
"mergedeep==1.3.4",
],
)
serverless.upload(template)
QiskitFunction(template_hamiltonian_simulation)
Por último, para verificar que el programa se subió correctamente, usa serverless.list():
serverless.list()
QiskitFunction(template_hamiltonian_simulation),
Ejecutar la plantilla de función de forma remota
La plantilla de función se ha subido, así que ya puedes ejecutarla de forma remota con Qiskit Serverless. Primero, carga la plantilla por nombre:
template = serverless.load("template_hamiltonian_simulation")
A continuación, ejecuta la plantilla con las entradas de nivel de dominio para la simulación hamiltoniana. Este ejemplo especifica un modelo XXZ de 50 qubits con acoplamientos aleatorios, y un estado inicial y un observable.
from itertools import chain
import numpy as np
from qiskit.quantum_info import SparsePauliOp
L = 50
# Generate the edge list for this spin-chain
edges = [(i, i + 1) for i in range(L - 1)]
# Generate an edge-coloring so we can make hw-efficient circuits
edges = edges[::2] + edges[1::2]
# Generate random coefficients for our XXZ Hamiltonian
np.random.seed(0)
Js = np.random.rand(L - 1) + 0.5 * np.ones(L - 1)
hamiltonian = SparsePauliOp.from_sparse_list(
chain.from_iterable(
[
[
("XX", (i, j), Js[i] / 2),
("YY", (i, j), Js[i] / 2),
("ZZ", (i, j), Js[i]),
]
for i, j in edges
]
),
num_qubits=L,
)
observable = SparsePauliOp.from_sparse_list(
[("ZZ", (L // 2 - 1, L // 2), 1.0)], num_qubits=L
)
from qiskit import QuantumCircuit
initial_state = QuantumCircuit(L)
for i in range(L):
if i % 2:
initial_state.x(i)
job = template.run(
dry_run=True,
initial_state=initial_state,
hamiltonian=hamiltonian,
observable=observable,
backend_name="ibm_fez",
estimator_options={},
aqc_evolution_time=0.2,
aqc_ansatz_num_trotter_steps=1,
aqc_target_num_trotter_steps=32,
remainder_evolution_time=0.2,
remainder_num_trotter_steps=4,
aqc_max_iterations=300,
)
print(job.job_id)
853b0edb-d63f-4629-be71-398b6dcf33cb
Verifica el estado del trabajo:
job.status()
'QUEUED'
Una vez que el trabajo esté en ejecución, puedes obtener los registros generados por las salidas de print(). Estos pueden proporcionar información útil sobre el progreso del flujo de trabajo de simulación hamiltoniana. Por ejemplo, el valor de la función objetivo durante el componente iterativo de AQC, o la profundidad de dos qubits del circuito ISA final previsto para su ejecución en hardware.
print(job.logs())
No logs yet.
Bloquea el resto del programa hasta que haya un resultado disponible. Una vez finalizado el trabajo, puedes recuperar los resultados. Estos incluyen la salida de nivel de dominio de la simulación hamiltoniana (valor esperado) y metadatos útiles.
result = job.result()
del result[
"aqc_final_parameters"
] # the list is too long to conveniently display here
result
{'target_bond_dimension': 5,
'num_aqc_parameters': 816,
'aqc_starting_fidelity': 0.9914382555614002,
'num_iterations': 72,
'aqc_fidelity': 0.9998108844412502,
'twoqubit_depth': 33}
Una vez que el trabajo se complete, toda la salida de registro estará disponible.
print(job.logs())
2024-12-17 14:50:15,580 INFO job_manager.py:531 -- Runtime env is setting up.
estimator_options = {
"resilience": {
"measure_mitigation": true,
"zne_mitigation": true,
"zne": {
"amplifier": "gate_folding",
"noise_factors": [
1,
2,
3
],
"extrapolated_noise_factors": [
0.0,
0.1,
0.2,
0.30000000000000004,
0.4,
0.5,
0.6000000000000001,
0.7000000000000001,
0.8,
0.9,
1.0,
1.1,
1.2000000000000002,
1.3,
1.4000000000000001,
1.5,
1.6,
1.7000000000000002,
1.8,
1.9000000000000001,
2.0,
2.1,
2.2,
2.3000000000000003,
2.4000000000000004,
2.5,
2.6,
2.7,
2.8000000000000003,
2.9000000000000004,
3.0
],
"extrapolator": [
"exponential",
"linear",
"fallback"
]
},
"measure_noise_learning": {
"num_randomizations": 512,
"shots_per_randomization": 512
}
},
"twirling": {
"enable_gates": true,
"enable_measure": true,
"num_randomizations": 300,
"shots_per_randomization": 100,
"strategy": "active"
}
}
Hamiltonian: SparsePauliOp(['IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXX', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYY', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZ', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'XXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'YYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'ZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXI', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYI', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZI', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IIIZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IXXIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IYYIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII', 'IZZIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII'],
coeffs=[0.52440675+0.j, 0.52440675+0.j, 1.0488135 +0.j, 0.55138169+0.j,
0.55138169+0.j, 1.10276338+0.j, 0.4618274 +0.j, 0.4618274 +0.j,
0.9236548 +0.j, 0.46879361+0.j, 0.46879361+0.j, 0.93758721+0.j,
0.73183138+0.j, 0.73183138+0.j, 1.46366276+0.j, 0.64586252+0.j,
0.64586252+0.j, 1.29172504+0.j, 0.53402228+0.j, 0.53402228+0.j,
1.06804456+0.j, 0.28551803+0.j, 0.28551803+0.j, 0.57103606+0.j,
0.2601092 +0.j, 0.2601092 +0.j, 0.5202184 +0.j, 0.63907838+0.j,
0.63907838+0.j, 1.27815675+0.j, 0.73930917+0.j, 0.73930917+0.j,
1.47861834+0.j, 0.48073968+0.j, 0.48073968+0.j, 0.96147936+0.j,
0.30913721+0.j, 0.30913721+0.j, 0.61827443+0.j, 0.32167664+0.j,
0.32167664+0.j, 0.64335329+0.j, 0.51092416+0.j, 0.51092416+0.j,
1.02184832+0.j, 0.38227781+0.j, 0.38227781+0.j, 0.76455561+0.j,
0.47807517+0.j, 0.47807517+0.j, 0.95615033+0.j, 0.2593949 +0.j,
0.2593949 +0.j, 0.5187898 +0.j, 0.55604786+0.j, 0.55604786+0.j,
1.11209572+0.j, 0.72187404+0.j, 0.72187404+0.j, 1.44374808+0.j,
0.42975395+0.j, 0.42975395+0.j, 0.8595079 +0.j, 0.5988156 +0.j,
0.5988156 +0.j, 1.1976312 +0.j, 0.58338336+0.j, 0.58338336+0.j,
1.16676672+0.j, 0.35519128+0.j, 0.35519128+0.j, 0.71038256+0.j,
0.40771418+0.j, 0.40771418+0.j, 0.81542835+0.j, 0.60759468+0.j,
0.60759468+0.j, 1.21518937+0.j, 0.52244159+0.j, 0.52244159+0.j,
1.04488318+0.j, 0.57294706+0.j, 0.57294706+0.j, 1.14589411+0.j,
0.6958865 +0.j, 0.6958865 +0.j, 1.391773 +0.j, 0.44172076+0.j,
0.44172076+0.j, 0.88344152+0.j, 0.51444746+0.j, 0.51444746+0.j,
1.02889492+0.j, 0.71279832+0.j, 0.71279832+0.j, 1.42559664+0.j,
0.29356465+0.j, 0.29356465+0.j, 0.5871293 +0.j, 0.66630992+0.j,
0.66630992+0.j, 1.33261985+0.j, 0.68500607+0.j, 0.68500607+0.j,
1.37001215+0.j, 0.64957928+0.j, 0.64957928+0.j, 1.29915856+0.j,
0.64026459+0.j, 0.64026459+0.j, 1.28052918+0.j, 0.56996051+0.j,
0.56996051+0.j, 1.13992102+0.j, 0.72233446+0.j, 0.72233446+0.j,
1.44466892+0.j, 0.45733097+0.j, 0.45733097+0.j, 0.91466194+0.j,
0.63711684+0.j, 0.63711684+0.j, 1.27423369+0.j, 0.53421697+0.j,
0.53421697+0.j, 1.06843395+0.j, 0.55881775+0.j, 0.55881775+0.j,
1.1176355 +0.j, 0.558467 +0.j, 0.558467 +0.j, 1.116934 +0.j,
0.59091015+0.j, 0.59091015+0.j, 1.1818203 +0.j, 0.46851598+0.j,
0.46851598+0.j, 0.93703195+0.j, 0.28011274+0.j, 0.28011274+0.j,
0.56022547+0.j, 0.58531893+0.j, 0.58531893+0.j, 1.17063787+0.j,
0.31446315+0.j, 0.31446315+0.j, 0.6289263 +0.j])
Observable: SparsePauliOp(['IIIIIIIIIIIIIIIIIIIIIIIIZZIIIIIIIIIIIIIIIIIIIIIIII'],
coeffs=[1.+0.j])
Target MPS maximum bond dimension: 5
Number of AQC parameters: 816
Starting fidelity of AQC portion: 0.9914382555614002
2024-12-17 14:52:23.400028 Intermediate result: Fidelity 0.99764093
2024-12-17 14:52:23.429669 Intermediate result: Fidelity 0.99788003
2024-12-17 14:52:23.459674 Intermediate result: Fidelity 0.99795970
2024-12-17 14:52:23.489666 Intermediate result: Fidelity 0.99799067
2024-12-17 14:52:23.518545 Intermediate result: Fidelity 0.99803401
2024-12-17 14:52:23.546952 Intermediate result: Fidelity 0.99809821
2024-12-17 14:52:23.575271 Intermediate result: Fidelity 0.99824660
2024-12-17 14:52:23.604049 Intermediate result: Fidelity 0.99845326
2024-12-17 14:52:23.632709 Intermediate result: Fidelity 0.99870497
2024-12-17 14:52:23.660527 Intermediate result: Fidelity 0.99891442
2024-12-17 14:52:23.688273 Intermediate result: Fidelity 0.99904488
2024-12-17 14:52:23.716105 Intermediate result: Fidelity 0.99914438
2024-12-17 14:52:23.744336 Intermediate result: Fidelity 0.99922827
2024-12-17 14:52:23.773399 Intermediate result: Fidelity 0.99929071
2024-12-17 14:52:23.801482 Intermediate result: Fidelity 0.99932432
2024-12-17 14:52:23.830466 Intermediate result: Fidelity 0.99936460
2024-12-17 14:52:23.860738 Intermediate result: Fidelity 0.99938891
2024-12-17 14:52:23.889958 Intermediate result: Fidelity 0.99940607
2024-12-17 14:52:23.918703 Intermediate result: Fidelity 0.99941965
2024-12-17 14:52:23.949744 Intermediate result: Fidelity 0.99944337
2024-12-17 14:52:23.980871 Intermediate result: Fidelity 0.99946875
2024-12-17 14:52:24.012124 Intermediate result: Fidelity 0.99949009
2024-12-17 14:52:24.044359 Intermediate result: Fidelity 0.99952191
2024-12-17 14:52:24.075840 Intermediate result: Fidelity 0.99953669
2024-12-17 14:52:24.106303 Intermediate result: Fidelity 0.99955242
2024-12-17 14:52:24.139329 Intermediate result: Fidelity 0.99958412
2024-12-17 14:52:24.169725 Intermediate result: Fidelity 0.99960176
2024-12-17 14:52:24.198749 Intermediate result: Fidelity 0.99961606
2024-12-17 14:52:24.227874 Intermediate result: Fidelity 0.99963811
2024-12-17 14:52:24.256818 Intermediate result: Fidelity 0.99964383
2024-12-17 14:52:24.285889 Intermediate result: Fidelity 0.99964717
2024-12-17 14:52:24.315228 Intermediate result: Fidelity 0.99966064
2024-12-17 14:52:24.345322 Intermediate result: Fidelity 0.99966517
2024-12-17 14:52:24.374921 Intermediate result: Fidelity 0.99967089
2024-12-17 14:52:24.404309 Intermediate result: Fidelity 0.99968305
2024-12-17 14:52:24.432664 Intermediate result: Fidelity 0.99968889
2024-12-17 14:52:24.461639 Intermediate result: Fidelity 0.99969997
2024-12-17 14:52:24.491244 Intermediate result: Fidelity 0.99971666
2024-12-17 14:52:24.520354 Intermediate result: Fidelity 0.99972441
2024-12-17 14:52:24.549965 Intermediate result: Fidelity 0.99973561
2024-12-17 14:52:24.583464 Intermediate result: Fidelity 0.99973811
2024-12-17 14:52:24.617537 Intermediate result: Fidelity 0.99974074
2024-12-17 14:52:24.652247 Intermediate result: Fidelity 0.99974467
2024-12-17 14:52:24.686831 Intermediate result: Fidelity 0.99974991
2024-12-17 14:52:24.725476 Intermediate result: Fidelity 0.99975230
2024-12-17 14:52:24.764637 Intermediate result: Fidelity 0.99975373
2024-12-17 14:52:24.802499 Intermediate result: Fidelity 0.99975552
2024-12-17 14:52:24.839960 Intermediate result: Fidelity 0.99975885
2024-12-17 14:52:24.877472 Intermediate result: Fidelity 0.99976469
2024-12-17 14:52:24.916233 Intermediate result: Fidelity 0.99976517
2024-12-17 14:52:24.993750 Intermediate result: Fidelity 0.99976875
2024-12-17 14:52:25.034953 Intermediate result: Fidelity 0.99976887
2024-12-17 14:52:25.076197 Intermediate result: Fidelity 0.99977244
2024-12-17 14:52:25.112340 Intermediate result: Fidelity 0.99977638
2024-12-17 14:52:25.149947 Intermediate result: Fidelity 0.99977828
2024-12-17 14:52:25.190049 Intermediate result: Fidelity 0.99978174
2024-12-17 14:52:25.310903 Intermediate result: Fidelity 0.99978222
2024-12-17 14:52:25.347512 Intermediate result: Fidelity 0.99978508
2024-12-17 14:52:25.385201 Intermediate result: Fidelity 0.99978543
2024-12-17 14:52:25.457436 Intermediate result: Fidelity 0.99978770
2024-12-17 14:52:25.497133 Intermediate result: Fidelity 0.99978818
2024-12-17 14:52:25.541179 Intermediate result: Fidelity 0.99978913
2024-12-17 14:52:25.584791 Intermediate result: Fidelity 0.99978937
2024-12-17 14:52:25.621484 Intermediate result: Fidelity 0.99979068
2024-12-17 14:52:25.655847 Intermediate result: Fidelity 0.99979211
2024-12-17 14:52:25.691710 Intermediate result: Fidelity 0.99979700
2024-12-17 14:52:25.767711 Intermediate result: Fidelity 0.99979759
2024-12-17 14:52:25.804517 Intermediate result: Fidelity 0.99979807
2024-12-17 14:52:25.839394 Intermediate result: Fidelity 0.99980236
2024-12-17 14:52:25.874438 Intermediate result: Fidelity 0.99980296
2024-12-17 14:52:25.909900 Intermediate result: Fidelity 0.99980320
2024-12-17 14:52:26.713044 Intermediate result: Fidelity 0.99980320
Done after 72 iterations.
Fidelity of AQC portion: 0.9998108844412502
ISA circuit two-qubit depth: 33
Exiting before hardware execution since `dry_run` is True.
Próximos pasos
Recomendaciones
Para profundizar en el complemento AQC-Tensor de Qiskit, consulta el tutorial Evolución temporal de Trotter mejorada con compilación cuántica aproximada o el repositorio qiskit-addon-aqc-tensor.
%%writefile ./source_files/template_hamiltonian_simulation_full.py
from qiskit import QuantumCircuit
from qiskit_serverless import get_arguments, save_result
# Extract parameters from arguments
#
# Do this at the top of the program so it fails early if any required arguments are missing or invalid.
arguments = get_arguments()
dry_run = arguments.get("dry_run", False)
backend_name = arguments["backend_name"]
aqc_evolution_time = arguments["aqc_evolution_time"]
aqc_ansatz_num_trotter_steps = arguments["aqc_ansatz_num_trotter_steps"]
aqc_target_num_trotter_steps = arguments["aqc_target_num_trotter_steps"]
remainder_evolution_time = arguments["remainder_evolution_time"]
remainder_num_trotter_steps = arguments["remainder_num_trotter_steps"]
# Stop if this fidelity is achieved
aqc_stopping_fidelity = arguments.get("aqc_stopping_fidelity", 1.0)
# Stop after this number of iterations, even if stopping fidelity is not achieved
aqc_max_iterations = arguments.get("aqc_max_iterations", 500)
hamiltonian = arguments["hamiltonian"]
observable = arguments["observable"]
initial_state = arguments.get("initial_state", QuantumCircuit(hamiltonian.num_qubits))
import numpy as np
import json
from mergedeep import merge
# Configure `EstimatorOptions`, to control the parameters of the hardware experiment
#
# Set default options
estimator_default_options = {
"resilience": {
"measure_mitigation": True,
"zne_mitigation": True,
"zne": {
"amplifier": "gate_folding",
"noise_factors": [1, 2, 3],
"extrapolated_noise_factors": list(np.linspace(0, 3, 31)),
"extrapolator": ["exponential", "linear", "fallback"],
},
"measure_noise_learning": {
"num_randomizations": 512,
"shots_per_randomization": 512,
},
},
"twirling": {
"enable_gates": True,
"enable_measure": True,
"num_randomizations": 300,
"shots_per_randomization": 100,
"strategy": "active",
},
}
# Merge with user-provided options
estimator_options = merge(
arguments.get("estimator_options", {}), estimator_default_options
)
print("estimator_options =", json.dumps(estimator_options, indent=4))
# Perform parameter validation
if not 0.0 < aqc_stopping_fidelity <= 1.0:
raise ValueError(
f"Invalid stopping fidelity: {aqc_stopping_fidelity}. It must be a positive float no greater than 1."
)
output = {}
import os
os.environ["NUMBA_CACHE_DIR"] = "/data"
import datetime
import quimb.tensor
from scipy.optimize import OptimizeResult, minimize
from qiskit.synthesis import SuzukiTrotter
from qiskit_addon_utils.problem_generators import generate_time_evolution_circuit
from qiskit_addon_aqc_tensor.ansatz_generation import (
generate_ansatz_from_circuit,
AnsatzBlock,
)
from qiskit_addon_aqc_tensor.simulation import (
tensornetwork_from_circuit,
compute_overlap,
)
from qiskit_addon_aqc_tensor.simulation.quimb import QuimbSimulator
from qiskit_addon_aqc_tensor.objective import OneMinusFidelity
print("Hamiltonian:", hamiltonian)
print("Observable:", observable)
simulator_settings = QuimbSimulator(quimb.tensor.CircuitMPS, autodiff_backend="jax")
# Construct the AQC target circuit
aqc_target_circuit = initial_state.copy()
if aqc_evolution_time:
aqc_target_circuit.compose(
generate_time_evolution_circuit(
hamiltonian,
synthesis=SuzukiTrotter(reps=aqc_target_num_trotter_steps),
time=aqc_evolution_time,
),
inplace=True,
)
# Construct matrix-product state representation of the AQC target state
aqc_target_mps = tensornetwork_from_circuit(aqc_target_circuit, simulator_settings)
print("Target MPS maximum bond dimension:", aqc_target_mps.psi.max_bond())
output["target_bond_dimension"] = aqc_target_mps.psi.max_bond()
# Generate an ansatz and initial parameters from a Trotter circuit with fewer steps
aqc_good_circuit = initial_state.copy()
if aqc_evolution_time:
aqc_good_circuit.compose(
generate_time_evolution_circuit(
hamiltonian,
synthesis=SuzukiTrotter(reps=aqc_ansatz_num_trotter_steps),
time=aqc_evolution_time,
),
inplace=True,
)
aqc_ansatz, aqc_initial_parameters = generate_ansatz_from_circuit(aqc_good_circuit)
print("Number of AQC parameters:", len(aqc_initial_parameters))
output["num_aqc_parameters"] = len(aqc_initial_parameters)
# Calculate the fidelity of ansatz circuit vs. the target state, before optimization
good_mps = tensornetwork_from_circuit(aqc_good_circuit, simulator_settings)
starting_fidelity = abs(compute_overlap(good_mps, aqc_target_mps)) ** 2
print("Starting fidelity of AQC portion:", starting_fidelity)
output["aqc_starting_fidelity"] = starting_fidelity
# Optimize the ansatz parameters by using MPS calculations
def callback(intermediate_result: OptimizeResult):
fidelity = 1 - intermediate_result.fun
print(f"{datetime.datetime.now()} Intermediate result: Fidelity {fidelity:.8f}")
if intermediate_result.fun < stopping_point:
raise StopIteration
objective = OneMinusFidelity(aqc_target_mps, aqc_ansatz, simulator_settings)
stopping_point = 1.0 - aqc_stopping_fidelity
result = minimize(
objective,
aqc_initial_parameters,
method="L-BFGS-B",
jac=True,
options={"maxiter": aqc_max_iterations},
callback=callback,
)
if result.status not in (
0,
1,
99,
): # 0 => success; 1 => max iterations reached; 99 => early termination via StopIteration
raise RuntimeError(
f"Optimization failed: {result.message} (status={result.status})"
)
print(f"Done after {result.nit} iterations.")
output["num_iterations"] = result.nit
aqc_final_parameters = result.x
output["aqc_final_parameters"] = list(aqc_final_parameters)
# Construct an optimized circuit for initial portion of time evolution
aqc_final_circuit = aqc_ansatz.assign_parameters(aqc_final_parameters)
# Calculate fidelity after optimization
aqc_final_mps = tensornetwork_from_circuit(aqc_final_circuit, simulator_settings)
aqc_fidelity = abs(compute_overlap(aqc_final_mps, aqc_target_mps)) ** 2
print("Fidelity of AQC portion:", aqc_fidelity)
output["aqc_fidelity"] = aqc_fidelity
# Construct final circuit, with remainder of time evolution
final_circuit = aqc_final_circuit.copy()
if remainder_evolution_time:
remainder_circuit = generate_time_evolution_circuit(
hamiltonian,
synthesis=SuzukiTrotter(reps=remainder_num_trotter_steps),
time=remainder_evolution_time,
)
final_circuit.compose(remainder_circuit, inplace=True)
from qiskit_ibm_runtime import QiskitRuntimeService
from qiskit.transpiler import generate_preset_pass_manager
service = QiskitRuntimeService()
backend = service.backend(backend_name)
# Transpile PUBs (circuits and observables) to match ISA
pass_manager = generate_preset_pass_manager(backend=backend, optimization_level=3)
isa_circuit = pass_manager.run(final_circuit)
isa_observable = observable.apply_layout(isa_circuit.layout)
isa_2qubit_depth = isa_circuit.depth(lambda x: x.operation.num_qubits == 2)
print("ISA circuit two-qubit depth:", isa_2qubit_depth)
output["twoqubit_depth"] = isa_2qubit_depth
# Exit now if dry run; don't execute on hardware
if dry_run:
import sys
print("Exiting before hardware execution since `dry_run` is True.")
save_result(output)
sys.exit(0)
# ## Step 3: Execute quantum experiments on backend
from qiskit_ibm_runtime import EstimatorV2 as Estimator
estimator = Estimator(backend, options=estimator_options)
# Submit the underlying Estimator job. Note that this is not the
# actual function job.
job = estimator.run([(isa_circuit, isa_observable)])
print("Job ID:", job.job_id())
output["job_id"] = job.job_id()
# Wait until job is complete
hw_results = job.result()
hw_results_dicts = [pub_result.data.__dict__ for pub_result in hw_results]
# Save hardware results to serverless output dictionary
output["hw_results"] = hw_results_dicts
# Reorganize expectation values
hw_expvals = [pub_result_data["evs"].tolist() for pub_result_data in hw_results_dicts]
# Save expectation values to Qiskit Serverless
output["hw_expvals"] = hw_expvals[0]
save_result(output)
Overwriting ./source_files/template_hamiltonian_simulation_full.py
Código fuente completo del programa
A continuación se muestra el código fuente completo de ./source_files/template_hamiltonian_simulation.py en un único bloque de código.
# This cell is hidden from users. It verifies both source listings are identical then deletes the working folder we created
import shutil
with open("./source_files/template_hamiltonian_simulation.py") as f1:
with open("./source_files/template_hamiltonian_simulation_full.py") as f2:
assert f1.read() == f2.read()
shutil.rmtree("./source_files/")