FiQCI Error Mitigation Service (EMS) is a Python library for quantum error mitigation as part of the Finnish Quantum Computing Infrastructure (FiQCI). It wraps IQM quantum backends and applies error mitigation transparently, allowing users to run circuits with improved accuracy by specifying a mitigation level.
This python package can be pre-installed on a HPC system or installed by the user. The main goal of the project is to allow users using FiQCI quantum computers to easily add flags to run error mitigated quantum jobs.
Sampler
| Level | Mitigation Applied | Technique |
|---|---|---|
| 0 | None | Raw results |
| 1 | Readout Error Mitigation | M3 (matrix-free measurement mitigation) |
| 2 | Level 1 + Dynamical Decoupling | Dynamical Decoupling |
| 3 | Level 2 + additional | TBD |
Estimator
| Level | Mitigation Applied | Technique |
|---|---|---|
| 0 | None | Raw results |
| 1 | Readout Error Mitigation | M3 (matrix-free measurement mitigation) |
| 2 | Level 1 + Dynamical Decoupling | Dynamical Decoupling |
| 3 | Level 2 + Zero Noise Extrapolation | Exponential Extrapolation, Local Folding |
Note
FiQCIBackend mitigation levels correspond to the Sampler levels.
The default is level 1, which applies M3 readout error mitigation.
UV is recommended for installation
uv pip install fiqci-ems
#or
uv add fiqci-emsRequires Python 3.11 or 3.12.
Start by initialising your IQM backend and a quantum circuit.
from iqm.qiskit_iqm import IQMProvider
from qiskit import QuantumCircuit, transpile
# Initialise backend
provider = IQMProvider()
backend = provider.get_backend()
# Define a quantum circuit
qc = QuantumCircuit(2)
qc.h(0)
qc.cx(0, 1)
qc.measure_all()
# Transpile the circuit
qc_transpiled = transpile(qc, backend=backend, initial_layout=qubit_indices)EMS provides three interfaces depending on your use case.
For users who need measurement counts with built-in mitigation:
from fiqci.ems import FiQCISampler
# Using mitigation_level
sampler = FiQCISampler(backend, mitigation_level=1)
# Execute the job
job = sampler.run(qc_transpiled, shots=2048)
# Get results
result = job.result()
# Or manually set mitigation options
sampler.rem(enabled=True, calibration_shots=2000, calibration_file="cals.json")
# See applied and available options
sampler.mitigation_options()Computes expectation values of Pauli observables directly from circuits:
from fiqci.ems import FiQCIEstimator
from qiskit.quantum_info import SparsePauliOp
# Using mitigation_level
estimator = FiQCIEstimator(backend, mitigation_level=1)
# Define observables
observables = SparsePauliOp.from_list([("ZZ", 1), ("IX", 1)])
# Map observables to transpiled layout
device_observables = observables.apply_layout(qc_transpiled.layout)
# Execute the job
job_collection = estimator.run(qc_transpiled, observables=device_observables, shots=2048)
# Get expectation values
evs = job_collection.expectation_values()
# Access all jobs executed by estimator
jobs = job_collection.jobs()
# Or manually set mitigation options
estimator.rem(enabled=True, calibration_shots=2000, calibration_file="cals.json")
# See applied and available options
estimator.mitigation_options()FiQCIBackend is used under the hood by both sampler and estimator. Wraps any IQM backend and applies error mitigation to run() calls:
from fiqci.ems import FiQCIBackend
# Using mitigation_level
backend = FiQCIBackend(backend, mitigation_level=1)
# Execute the job
job = backend.run(circuit, shots=1024)
# Get the results
result = job.result()
# Or manually set mitigation options
backend.rem(enabled=True, calibration_shots=2000, calibration_file="cals.json")
# See applied and available options
backend.mitigation_options()Access raw (pre-mitigation) counts via backend.raw_counts.
It is also possible to manually configure and directly use the M3 mitigator without the wrapper classes above. Consult the docs for how this is done.
All three interfaces accept the same core options:
| Parameter | Default | Description |
|---|---|---|
mitigation_level |
1 |
Mitigation level (0-3) |
calibration_shots |
1000 |
Shots used for M3 calibration circuits |
calibration_file |
None |
Path to save/load calibration data (JSON) |
Mitigation can also be configured directly. See the docs for FiQCISampler, FiQCIEstimator, and FiQCIBackend to see all available options.
Full documentation including API reference, guides, and Jupyter notebook examples is available at docs
# Install with dev dependencies
uv sync
# Run tests
uv run pytest
# Run tests with coverage
uv run pytest --cov
# Lint and format
uv run ruff check --fix
uv run ruff format
# Type check
uv run pyrefly check #Install docs dependencies
uv sync --group docs
#Build docs
uv run sphinx-build docs/ docs/_buildApache 2.0, see LICENSE for details.
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