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IBM Circuit function

Note

Qiskit Functions are an experimental feature available only to IBM Quantum™ Premium Plan users. They are in preview release status and subject to change.


Overview

The IBM® Circuit function takes abstract PUBs as inputs, and returns mitigated expectation values as outputs. This circuit function includes an automated and customized pipeline to enable researchers to focus on algorithm and application discovery.


Description

After submitting your PUB, your abstract circuits and observables are automatically transpiled, executed on hardware, and post-processed to return mitigated expectation values. To do so, this combines the following tools:

IBM Circuit function

Get started

Authenticate using your IBM Quantum Platform API token, and select the Qiskit Function as follows:

from qiskit_ibm_catalog import QiskitFunctionsCatalog
 
catalog = QiskitFunctionsCatalog()
function = catalog.load("ibm/circuit-function")

Example

To get started, try this basic example:

from qiskit.circuit.random import random_circuit
from qiskit_ibm_runtime import QiskitRuntimeService
 
# You can skip this step if you have a target backend, e.g.
# backend_name = "ibm_sherbrooke"
# You'll need to specify the credentials when initializing QiskitRuntimeService, if they were not previously saved.
service = QiskitRuntimeService()
backend = service.least_busy(operational=True, simulator=False)
 
circuit = random_circuit(num_qubits=2, depth=2, seed=42)
observable = "Z" * circuit.num_qubits
pubs = [(circuit, observable)]
 
job = function.run(
    # Use `backend_name=backend_name` if you didn't initialize a backend object
    backend_name=backend.name,
    pubs=pubs,
)

Check your Qiskit Function workload's status or return results as follows:

print(job.status())
result = job.result()

Output:

QUEUED

The results have the same format as an Estimator result:

print(f"The result of the submitted job had {len(result)} PUB\n")
print(
    f"The associated PubResult of this job has the following DataBins:\n {result[0].data}\n"
)
print(f"And this DataBin has attributes: {result[0].data.keys()}")
print(
    f"The expectation values measured from this PUB are: \n{result[0].data.evs}"
)

Output:

The result of the submitted job had 1 PUB

The associated PubResult of this job has the following DataBins:
 DataBin(evs=np.ndarray(<shape=(), dtype=float64>), stds=np.ndarray(<shape=(), dtype=float64>), ensemble_standard_error=np.ndarray(<shape=(), dtype=float64>))

And this DataBin has attributes: dict_keys(['evs', 'stds', 'ensemble_standard_error'])
The expectation values measured from this PUB are: 
0.07302231237322515

Inputs

See the following table for all input parameters the IBM Circuit function accepts. The subsequent Options section goes into more details about the available options.

NameTypeDescriptionRequiredDefaultExample
backend_namestrName of the backend to make the query.YesN/Aibm_fez
pubsIterable[EstimatorPubLike]An iterable of abstract PUB-like (primitive unified bloc) objects, such as tuples (circuit, observables) or (circuit, observables, parameter_values). See Overview of PUBs for more information. The circuits can be abstract (non-ISA).YesN/A(circuit, observables, parameter_values)
optionsdictInput options. See the Options section for more details.NoSee the Options section for details.{"optimization_level": 3}
instancestrThe hub/group/project to use in that format.NoOne is randomly picked if your account has access to multiple instances.hub1/group1/project1

Options

Structure

Similar to Qiskit Runtime primitives, options for IBM Circuit function can be specified as a nested dictionary. Commonly used options, such as optimization_level and mitigation_level, are at the first level. Other, more advanced options are grouped into different categories, such as resilience.

Defaults

If you do not specify a value for an option, the default value specified by the service is used.

Mitigation level

IBM Circuit function also supports mitigation_level. The mitigation level specifies how much error suppression and mitigation to apply to the job. Higher levels generate more accurate results, at the expense of longer processing times. The degree of error reduction depends on the method applied. The mitigation level abstracts the detailed choice of error mitigation and suppression methods to allow users to reason about the cost/accuracy trade-off appropriate to their application. The following table shows the corresponding methods for each level.

Note

While the names are similar, mitigation_level applies different techniques than the ones used by Estimator’s resilience_level.

Similar to resilience_level in Qiskit Runtime Estimator, mitigation_level specifies a base set of curated options. Any options you manually specify in addition to the mitigation level are applied on top of the base set of options defined by the mitigation level. Therefore, in principle, you could set the mitigation level to 1, but then turn off measurement mitigation, although this is not advised.

Mitigation LevelTechnique
1 [Default]Dynamical decoupling + measurement twirling + TREX
2Level 1 + gate twirling + ZNE via gate folding
3Level 1 + gate twirling + ZNE via PEA

The following example demonstrates setting the mitigation level:

options = {"mitigation_level": 2}
 
job = function.run(backend_name=backend.name, pubs=pubs, options=options)

All available options

In addition to mitigation_level, the IBM Circuit function also provides a select number of advanced options that allow you to fine-tune the cost/accuracy trade-off. The following table shows all the available options:

OptionSub-optionSub-sub-optionDescriptionChoicesDefault
default_precisionThe default precision to use for any PUB or run()
call that does not specify one.
Each input PUB can specify its own precision. If the run() method is given a precision, then that value is used for all PUBs in the run() call that do not specify their own.
float > 00.015625
max_execution_timeMaximum execution time in seconds, which is based
on QPU usage (not wall clock time). QPU usage is the
amount of time that the QPU is dedicated to processing your job. If a job exceeds this time limit, it is forcibly canceled.
Integer number of seconds in the range [1, 10800]
mitigation_levelHow much error suppression and mitigation to apply. Refer to the Mitigation level section for more information about the methods used at each level.1 / 2 / 31
optimization_levelHow much optimization to perform on the circuits. Higher levels generate more optimized circuits, at the expense of longer transpilation time.1 / 2 / 32
dynamical_decouplingenableWhether to enable dynamical decoupling. Refer to Error suppression and mitigation techniques for the explanation of the method.True/FalseTrue
sequence_typeWhich dynamical decoupling sequence to use.
* XX: use the sequence tau/2 - (+X) - tau - (+X) - tau/2
* XpXm: use the sequence tau/2 - (+X) - tau - (-X) - tau/2
* XY4: use the sequence
tau/2 - (+X) - tau - (+Y) - tau (-X) - tau - (-Y) - tau/2
'XX'/'XpXm'/'XY4''XX'
twirlingenable_gatesWhether to apply 2-qubit Clifford gate twirling.True/FalseFalse
enable_measureWhether to enable twirling of measurements.True/FalseTrue
resiliencemeasure_mitigationWhether to enable TREX measurement error mitigation method. Refer to Error suppression and mitigation techniques for the explanation of the method.True/FalseTrue
zne_mitigationWhether to turn on Zero Noise Extrapolation error mitigation method. Refer to Error suppression and mitigation techniques for the explanation of the method.True/FalseFalse
zneamplifierWhich technique to use for amplifying noise. One of:
- gate_folding (default) uses 2-qubit gate folding to amplify noise. If the noise factor requires amplifying only a subset of the gates, then these gates are chosen randomly.

- gate_folding_front uses 2-qubit gate folding to amplify noise. If the noise factor requires amplifying only a subset of the gates, then these gates are selected from the front of the topologically ordered DAG circuit.

- gate_folding_back uses 2-qubit gate folding to amplify noise. If the noise factor requires amplifying only a subset of the gates, then these gates are selected from the back of the topologically ordered DAG circuit.

- pea uses a technique called Probabilistic error amplification (PEA) to amplify noise. Refer to Error suppression and mitigation techniques for the explanation of the method.
gate_folding / gate_folding_front / gate_folding_back / peagate_folding
noise_factorsNoise factors to use for noise amplification.list of floats; each float >= 1(1, 1.5, 2) for PEA, and (1, 3, 5) otherwise.
extrapolatorNoise factors to evaluate the fit extrapolation models at. This option does not affect execution or model fitting in any way; it only determines the points at which the extrapolators are evaluated to be returned in the data fields called evs_extrapolated and stds_extrapolated.one or more of exponential,linear, double_exponential,polynomial_degree_(1 <= k <= 7)(exponential, linear)
pec_mitigationWhether to turn on Probabilistic Error Cancellation error mitigation method. Refer to Error suppression and mitigation techniques for the explanation of the method.True/FalseFalse
pecmax_overheadThe maximum circuit sampling overhead allowed, or None for no maximum.None/ integer >1100

In the following example, setting the mitigation level to 1 initially turns off ZNE mitigation, but setting zne_mitigation to True overrides the relevent setup from mitigation_level.

options = {"mitigation_level": 1, "resilience": {"zne_mitigation": True}}

Outputs

The output of a Circuit function is a PrimitiveResult, which contains two fields:

  • One or more PubResult objects. These can be indexed directly from the PrimitiveResult.

  • Job-level metadata.

Each PubResult contains a data and a metadata field.

  • The data field contains at least an array of expectation values (PubResult.data.evs) and an array of standard errors (PubResult.data.stds). It can also contain more data, depending on the options used.

  • The metadata field contains PUB-level metadata (PubResult.metadata).

The following code snippet describes the PrimitiveResult (and associated PubResult) format.

print(f"The result of the submitted job had {len(result)} PUB")
print(
    f"The expectation values measured from this PUB are: \n{result[0].data.evs}"
)
print(f"And the associated metadata is: \n{result[0].metadata}")

Output:

The result of the submitted job had 1 PUB
The expectation values measured from this PUB are: 
0.07302231237322515
And the associated metadata is: 
{'shots': 4096, 'target_precision': 0.015625, 'circuit_metadata': {}, 'resilience': {}, 'num_randomizations': 32}

Fetching error messages

If your workload status is ERROR, use job.result() to fetch the error message to help debug as follows:

job = function.run(
    backend_name="bad_backend_name", pubs=pubs, options=options
)
 
print(job.result())

Output:

Traceback (most recent call last):
  File "/runner/runner.py", line 10, in run
    func = CircuitFunction(**arguments)
           ^^^^^^^^^^^^^^^^^^^^^^^^^^^^
  File "/runner/circuit_function/circuit_function.py", line 86, in __init__
    self._backend = self._service.backend(
                    ^^^^^^^^^^^^^^^^^^^^^^
  File "/usr/local/lib/python3.11/site-packages/qiskit_ibm_runtime/qiskit_runtime_service.py", line 787, in backend
    backends = self.backends(name, instance=instance, use_fractional_gates=use_fractional_gates)
               ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
  File "/usr/local/lib/python3.11/site-packages/qiskit_ibm_runtime/qiskit_runtime_service.py", line 536, in backends
    raise QiskitBackendNotFoundError("No backend matches the criteria.")
qiskit.providers.exceptions.QiskitBackendNotFoundError: 'No backend matches the criteria.'


Get support

Reach out to IBM Quantum support, and include the following information:

  • Qiskit Function Job ID (qiskit-ibm-catalog), job.job_id
  • A detailed description of the issue
  • Any relevant error messages or codes
  • Steps to reproduce the issue

Next steps

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