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QPU information

IBM® offers both open and premium access to a wide variety of quantum processing units (QPUs). All QPUs deployed by IBM are based on superconducting qubit technology, as the control and scalability of this technology pave a clear path to achieving quantum advantage with these QPUs. You can see the full details of all IBM QPUs on the Quantum processing units page.


QPU versioning

Each QPU has a version number in the form X.Y.Z (major.minor.revision). A circuit compiled for a given version number is guaranteed to run on that QPU. If the revision number changes, the circuit will continue to run. If the major or minor number changes, the circuit is not guaranteed to run, although it may do so. The conditions under which a version number may change are listed below:

Major version

The major version will increment for changes such as:

  • Sample changes.
  • Major changes to the control electronics.
  • Moving the QPU to a new location, if significant behavior changes result.

Minor version

The minor version will increment for changes such as:

  • Warmup / cool-down cycles.
  • Swapping out some electronics, if the replacement appreciably affects operation.
  • Changing the direction of a controlled-NOT gate.
  • Dropping a gate for some duration of time due to calibration issues, and corrections cannot readily be done in software.

Revision version

The revision version number will increment for fixes that do not break the existing compiled circuit. These changes include:

  • Manual calibrations to improve fidelities.
  • Small electronics changes that don’t affect operation.
  • QPU software updates.

QPU configuration values

The following is a subset of QPU configuration values available in IBM Quantum Platform and from Qiskit.

These values are shown on both the Compute resources tab and the details page for each QPU.

  • Name - The unique name assigned to a specific QPU. QPUs hosted on IBM Cloud® have names that begin with ibmq_* (older QPUs) or ibm_* (newer QPUs). All QPUs are given a city name, e.g., ibmq_johannesburg. This name does not indicate where the actual QPU is hosted. They are named after IBM® locations around the world.
  • Qubits - The number of qubits in a QPU. For physical QPUs, this is the number of physical qubits in the device. For simulators, this number need not be uniquely defined, and instead can depend on the simulation method and/or the amount of memory available.
  • 2Q error (best) - The lowest two-qubit (2Q) error on any edge of the device as measured from isolated 2Q randomized benchmarking.
  • 2Q error (layered) - Average error per layered gate (EPLG) in a chain of 100 qubits. Average EPLG measures the average gate error in a layered chain of NN qubits (NN=100 here). It is derived from a similar quantity known as the layer fidelity (LF) where EPLG100_{100} = 4/5(1-LF199^{\frac{1}{99}}) and layer fidelity is the process fidelity of the layered chain of NN qubits. For details, see the paper Benchmarking quantum processor performance at scale. Note that in the paper EPLG is defined for process error, but for consistency with the individually reported gate errors here it is quoted for average gate error, thus the factor of 4/5.
  • CLOPS - Circuit layer operations per second, and also known as CLOPS_v, is a measure of how many layers of a Quantum volume circuit (virtual circuit) a QPU (quantum processing unit) can execute per unit of time. Find more information about this metric in the paper Quality, Speed, and Scale: three key attributes to measure the performance of near-term quantum computers.
  • CLOPS_h -- A measure of how many layers of a 100x100 circuit (hardware-aware circuit) a QPU (quantum processing unit) can execute per unit of time.
  • QV - Quantum volume. This value is another metric for QPU quality based on passing a fidelity threshold for a set of random, square all-to-all connected circuits. Provided as the peak value measured on a system of devices. For details, see the paper Validating quantum computers using randomized model circuits.
  • Status - The QPU status.
  • Total pending jobs - The total number of jobs that you have submitted to this QPU.
  • Processor type - Reflects the topology and indicates the approximate qubit count.
  • Features - Additional information about the QPU, such as whether it supports pulse inputs.
Average gate fidelity

Note that the metric for median ECR error (for Eagle processors) and median CZ error (for Heron processors) is the average gate fidelity, which is the average over all possible input states of the fidelity between the state produced by the actual operation and the state produced by the ideal operation.

Additional information available on the details page for each QPU

To access the details page, click the Compute resources tab, then click the name of the QPU.

  • Version - The version number of a QPU in the form major.minor.revision. See QPU versioning for details on how this number is assigned.

  • Calibration data - Download the calibration data as a CSV file or click the arrow to display the Topology diagram, Individual qubit readout graph, or the Calibration data table. You can customize the data that is shown, depending on the view you have open. For example, on the Topology diagram, you can choose the data you want to see for connections and qubits. The colored bars associated with the diagram or graph indicate the range that is shown, with the average value marked. The color maximum and minimum change depending on the QPU.

    • Topology diagram or coupling map - A diagram that indicates the pairs of qubits that support two-qubit gate operations between them. This is also called the coupling map or connectivity. Qubits are represented as circles and the supported two-qubit gate operations are displayed as lines connecting the qubits.
    • Individual qubit properties - Shows the selected property for each qubit on the QPU. You can view the frequency, T1, T2, Anharmonicity, probability measurements, error rates, and so on.
  • Your access instance - Instances that you can use. Click the arrow on the right to expand or collapse this section. For each instance, you can see the following information:

    • Max shots - The maximum number of times you can execute a single circuit on a QPU. The number of shots taken determines the precision of the output probability distribution over repeated executions.
    • Max circuits - The maximum number of quantum circuits that you can submit to this QPU at one time.
    • Max qubits per pulse gate - The maximum number of qubit arguments allowed to a gate.
    • Max channels per pulse gate - The maximum number of channels you can refer to within a pulse schedule. Typically each qubit is associated with a drive channel, a measure channel, an acquisition channel, and then auxiliary control channels for things like cross resonance.
    • Usage - Click the link to see the jobs that you have run on this QPU.

View QPU configuration

View QPU configuration values by selecting a QPU on the Quantum processing units page from the Compute resources tab. The three tabs in the Calibration data section let you choose how to view the calibration data; the Map view tab is automatically selected.

Expanded card for a sample QPU

An expanded card for a sample QPU.
Expanded card for a sample QPU

QPU tabs

Click the download icon in the upper right of any tab to download a CSV file of calibration data.

Graph view tab.

The graph view tab shows the calibration data as a graph.
Graph view tab

Table view tab

The table view tab shows the calibration information as numerical data.
Table view tab

Find QPU information from other channels

To find your available QPUs on IBM Cloud, view the IBM Cloud Compute resources page. You must be logged in to see your available compute resources. You are shown a snapshot of each QPU. To see full details, click the QPU name. You can also search for QPU from this page.

To see the QPUs available to you on IBM Quantum Platform, click the Compute resources tab from your dashboard. You are shown a snapshot of each QPU. To see full details, click the QPU name. You can also sort, filter, and search from this page.