qiskit-documentation/docs/api/qiskit/0.24/qiskit.quantum_info.SuperOp.mdx

---
title: SuperOp
description: API reference for qiskit.quantum_info.SuperOp
in_page_toc_min_heading_level: 1
python_api_type: class
python_api_name: qiskit.quantum_info.SuperOp
---

<span id="qiskit-quantum-info-superop" />

# qiskit.quantum\_info.SuperOp

<Class id="qiskit.quantum_info.SuperOp" isDedicatedPage={true} github="https://github.com/qiskit/qiskit/tree/stable/0.16/qiskit/quantum_info/operators/channel/superop.py" signature="SuperOp(data, input_dims=None, output_dims=None)" modifiers="class">
  Superoperator representation of a quantum channel.

  The Superoperator representation of a quantum channel $\mathcal{E}$ is a matrix $S$ such that the evolution of a [`DensityMatrix`](qiskit.quantum_info.DensityMatrix "qiskit.quantum_info.DensityMatrix") $\rho$ is given by

$$
|\mathcal{E}(\rho)\rangle\!\rangle = S |\rho\rangle\!\rangle
$$

  where the double-ket notation $|A\rangle\!\rangle$ denotes a vector formed by stacking the columns of the matrix $A$ *(column-vectorization)*.

  See reference \[1] for further details.

  **References**

  1.  C.J. Wood, J.D. Biamonte, D.G. Cory, *Tensor networks and graphical calculus for open quantum systems*, Quant. Inf. Comp. 15, 0579-0811 (2015). [arXiv:1111.6950 \[quant-ph\]](https://arxiv.org/abs/1111.6950)

  Initialize a quantum channel Superoperator operator.

  **Parameters**

  *   \*\*(\*\***QuantumCircuit or** (*data*) – Instruction or BaseOperator or matrix): data to initialize superoperator.
  *   **input\_dims** (*tuple*) – the input subsystem dimensions. \[Default: None]
  *   **output\_dims** (*tuple*) – the output subsystem dimensions. \[Default: None]

  **Raises**

  **QiskitError** – if input data cannot be initialized as a superoperator.

  **Additional Information:**

  If the input or output dimensions are None, they will be automatically determined from the input data. If the input data is a Numpy array of shape (4\*\*N, 4\*\*N) qubit systems will be used. If the input operator is not an N-qubit operator, it will assign a single subsystem with dimension specified by the shape of the input.

  ### \_\_init\_\_

  <Function id="qiskit.quantum_info.SuperOp.__init__" signature="__init__(data, input_dims=None, output_dims=None)">
    Initialize a quantum channel Superoperator operator.

    **Parameters**

    *   \*\*(\*\***QuantumCircuit or** (*data*) – Instruction or BaseOperator or matrix): data to initialize superoperator.
    *   **input\_dims** (*tuple*) – the input subsystem dimensions. \[Default: None]
    *   **output\_dims** (*tuple*) – the output subsystem dimensions. \[Default: None]

    **Raises**

    **QiskitError** – if input data cannot be initialized as a superoperator.

    **Additional Information:**

    If the input or output dimensions are None, they will be automatically determined from the input data. If the input data is a Numpy array of shape (4\*\*N, 4\*\*N) qubit systems will be used. If the input operator is not an N-qubit operator, it will assign a single subsystem with dimension specified by the shape of the input.
  </Function>

  ## Methods

  |                                                                                                                                |                                                                            |
  | ------------------------------------------------------------------------------------------------------------------------------ | -------------------------------------------------------------------------- |
  | [`__init__`](#qiskit.quantum_info.SuperOp.__init__ "qiskit.quantum_info.SuperOp.__init__")(data\[, input\_dims, output\_dims]) | Initialize a quantum channel Superoperator operator.                       |
  | [`add`](#qiskit.quantum_info.SuperOp.add "qiskit.quantum_info.SuperOp.add")(other)                                             | Return the linear operator self + other.                                   |
  | [`adjoint`](#qiskit.quantum_info.SuperOp.adjoint "qiskit.quantum_info.SuperOp.adjoint")()                                      | Return the adjoint of the operator.                                        |
  | [`compose`](#qiskit.quantum_info.SuperOp.compose "qiskit.quantum_info.SuperOp.compose")(other\[, qargs, front])                | Return the composed quantum channel self @ other.                          |
  | [`conjugate`](#qiskit.quantum_info.SuperOp.conjugate "qiskit.quantum_info.SuperOp.conjugate")()                                | Return the conjugate of the QuantumChannel.                                |
  | [`copy`](#qiskit.quantum_info.SuperOp.copy "qiskit.quantum_info.SuperOp.copy")()                                               | Make a deep copy of current operator.                                      |
  | [`dot`](#qiskit.quantum_info.SuperOp.dot "qiskit.quantum_info.SuperOp.dot")(other\[, qargs])                                   | Return the right multiplied operator self \* other.                        |
  | [`expand`](#qiskit.quantum_info.SuperOp.expand "qiskit.quantum_info.SuperOp.expand")(other)                                    | Return the tensor product channel other ⊗ self.                            |
  | [`input_dims`](#qiskit.quantum_info.SuperOp.input_dims "qiskit.quantum_info.SuperOp.input_dims")(\[qargs])                     | Return tuple of input dimension for specified subsystems.                  |
  | [`is_cp`](#qiskit.quantum_info.SuperOp.is_cp "qiskit.quantum_info.SuperOp.is_cp")(\[atol, rtol])                               | Test if Choi-matrix is completely-positive (CP)                            |
  | [`is_cptp`](#qiskit.quantum_info.SuperOp.is_cptp "qiskit.quantum_info.SuperOp.is_cptp")(\[atol, rtol])                         | Return True if completely-positive trace-preserving (CPTP).                |
  | [`is_tp`](#qiskit.quantum_info.SuperOp.is_tp "qiskit.quantum_info.SuperOp.is_tp")(\[atol, rtol])                               | Test if a channel is completely-positive (CP)                              |
  | [`is_unitary`](#qiskit.quantum_info.SuperOp.is_unitary "qiskit.quantum_info.SuperOp.is_unitary")(\[atol, rtol])                | Return True if QuantumChannel is a unitary channel.                        |
  | [`multiply`](#qiskit.quantum_info.SuperOp.multiply "qiskit.quantum_info.SuperOp.multiply")(other)                              | Return the linear operator other \* self.                                  |
  | [`output_dims`](#qiskit.quantum_info.SuperOp.output_dims "qiskit.quantum_info.SuperOp.output_dims")(\[qargs])                  | Return tuple of output dimension for specified subsystems.                 |
  | [`power`](#qiskit.quantum_info.SuperOp.power "qiskit.quantum_info.SuperOp.power")(n)                                           | Return the compose of a QuantumChannel with itself n times.                |
  | [`reshape`](#qiskit.quantum_info.SuperOp.reshape "qiskit.quantum_info.SuperOp.reshape")(\[input\_dims, output\_dims])          | Return a shallow copy with reshaped input and output subsystem dimensions. |
  | [`set_atol`](#qiskit.quantum_info.SuperOp.set_atol "qiskit.quantum_info.SuperOp.set_atol")(value)                              | Set the class default absolute tolerance parameter for float comparisons.  |
  | [`set_rtol`](#qiskit.quantum_info.SuperOp.set_rtol "qiskit.quantum_info.SuperOp.set_rtol")(value)                              | Set the class default relative tolerance parameter for float comparisons.  |
  | [`subtract`](#qiskit.quantum_info.SuperOp.subtract "qiskit.quantum_info.SuperOp.subtract")(other)                              | Return the linear operator self - other.                                   |
  | [`tensor`](#qiskit.quantum_info.SuperOp.tensor "qiskit.quantum_info.SuperOp.tensor")(other)                                    | Return the tensor product channel self ⊗ other.                            |
  | [`to_instruction`](#qiskit.quantum_info.SuperOp.to_instruction "qiskit.quantum_info.SuperOp.to_instruction")()                 | Convert to a Kraus or UnitaryGate circuit instruction.                     |
  | [`to_operator`](#qiskit.quantum_info.SuperOp.to_operator "qiskit.quantum_info.SuperOp.to_operator")()                          | Try to convert channel to a unitary representation Operator.               |
  | [`transpose`](#qiskit.quantum_info.SuperOp.transpose "qiskit.quantum_info.SuperOp.transpose")()                                | Return the transpose of the QuantumChannel.                                |

  ## Attributes

  |                                                                                                  |                                                                      |
  | ------------------------------------------------------------------------------------------------ | -------------------------------------------------------------------- |
  | [`atol`](#qiskit.quantum_info.SuperOp.atol "qiskit.quantum_info.SuperOp.atol")                   | The default absolute tolerance parameter for float comparisons.      |
  | [`data`](#qiskit.quantum_info.SuperOp.data "qiskit.quantum_info.SuperOp.data")                   | Return data.                                                         |
  | [`dim`](#qiskit.quantum_info.SuperOp.dim "qiskit.quantum_info.SuperOp.dim")                      | Return tuple (input\_shape, output\_shape).                          |
  | [`num_qubits`](#qiskit.quantum_info.SuperOp.num_qubits "qiskit.quantum_info.SuperOp.num_qubits") | Return the number of qubits if a N-qubit operator or None otherwise. |
  | [`qargs`](#qiskit.quantum_info.SuperOp.qargs "qiskit.quantum_info.SuperOp.qargs")                | Return the qargs for the operator.                                   |
  | [`rtol`](#qiskit.quantum_info.SuperOp.rtol "qiskit.quantum_info.SuperOp.rtol")                   | The relative tolerance parameter for float comparisons.              |

  ### add

  <Function id="qiskit.quantum_info.SuperOp.add" signature="add(other)">
    Return the linear operator self + other.

    DEPRECATED: use `operator + other` instead.

    **Parameters**

    **other** (*BaseOperator*) – an operator object.

    **Returns**

    the operator self + other.

    **Return type**

    BaseOperator
  </Function>

  ### adjoint

  <Function id="qiskit.quantum_info.SuperOp.adjoint" signature="adjoint()">
    Return the adjoint of the operator.
  </Function>

  ### atol

  <Attribute id="qiskit.quantum_info.SuperOp.atol">
    The default absolute tolerance parameter for float comparisons.
  </Attribute>

  ### compose

  <Function id="qiskit.quantum_info.SuperOp.compose" signature="compose(other, qargs=None, front=False)">
    Return the composed quantum channel self @ other.

    **Parameters**

    *   **other** (*QuantumChannel*) – a quantum channel.
    *   **qargs** (*list or None*) – a list of subsystem positions to apply other on. If None apply on all subsystems \[default: None].
    *   **front** (*bool*) – If True compose using right operator multiplication, instead of left multiplication \[default: False].

    **Returns**

    The quantum channel self @ other.

    **Return type**

    [SuperOp](#qiskit.quantum_info.SuperOp "qiskit.quantum_info.SuperOp")

    **Raises**

    **QiskitError** – if other has incompatible dimensions.

    **Additional Information:**

    Composition (`@`) is defined as left matrix multiplication for [`SuperOp`](#qiskit.quantum_info.SuperOp "qiskit.quantum_info.SuperOp") matrices. That is that `A @ B` is equal to `B * A`. Setting `front=True` returns right matrix multiplication `A * B` and is equivalent to the [`dot()`](#qiskit.quantum_info.SuperOp.dot "qiskit.quantum_info.SuperOp.dot") method.
  </Function>

  ### conjugate

  <Function id="qiskit.quantum_info.SuperOp.conjugate" signature="conjugate()">
    Return the conjugate of the QuantumChannel.
  </Function>

  ### copy

  <Function id="qiskit.quantum_info.SuperOp.copy" signature="copy()">
    Make a deep copy of current operator.
  </Function>

  ### data

  <Attribute id="qiskit.quantum_info.SuperOp.data">
    Return data.
  </Attribute>

  ### dim

  <Attribute id="qiskit.quantum_info.SuperOp.dim">
    Return tuple (input\_shape, output\_shape).
  </Attribute>

  ### dot

  <Function id="qiskit.quantum_info.SuperOp.dot" signature="dot(other, qargs=None)">
    Return the right multiplied operator self \* other.

    **Parameters**

    *   **other** (*BaseOperator*) – an operator object.
    *   **qargs** (*list or None*) – a list of subsystem positions to apply other on. If None apply on all subsystems \[default: None].

    **Returns**

    The operator self \* other.

    **Return type**

    BaseOperator

    **Raises**

    **QiskitError** – if other cannot be converted to an operator, or has incompatible dimensions for specified subsystems.
  </Function>

  ### expand

  <Function id="qiskit.quantum_info.SuperOp.expand" signature="expand(other)">
    Return the tensor product channel other ⊗ self.

    **Parameters**

    **other** (*QuantumChannel*) – a quantum channel.

    **Returns**

    the tensor product channel other ⊗ self as a SuperOp object.

    **Return type**

    [SuperOp](#qiskit.quantum_info.SuperOp "qiskit.quantum_info.SuperOp")

    **Raises**

    **QiskitError** – if other cannot be converted to a channel.
  </Function>

  ### input\_dims

  <Function id="qiskit.quantum_info.SuperOp.input_dims" signature="input_dims(qargs=None)">
    Return tuple of input dimension for specified subsystems.
  </Function>

  ### is\_cp

  <Function id="qiskit.quantum_info.SuperOp.is_cp" signature="is_cp(atol=None, rtol=None)">
    Test if Choi-matrix is completely-positive (CP)
  </Function>

  ### is\_cptp

  <Function id="qiskit.quantum_info.SuperOp.is_cptp" signature="is_cptp(atol=None, rtol=None)">
    Return True if completely-positive trace-preserving (CPTP).
  </Function>

  ### is\_tp

  <Function id="qiskit.quantum_info.SuperOp.is_tp" signature="is_tp(atol=None, rtol=None)">
    Test if a channel is completely-positive (CP)
  </Function>

  ### is\_unitary

  <Function id="qiskit.quantum_info.SuperOp.is_unitary" signature="is_unitary(atol=None, rtol=None)">
    Return True if QuantumChannel is a unitary channel.
  </Function>

  ### multiply

  <Function id="qiskit.quantum_info.SuperOp.multiply" signature="multiply(other)">
    Return the linear operator other \* self.

    DEPRECATED: use `other * operator` instead.

    **Parameters**

    **other** (*complex*) – a complex number.

    **Returns**

    the linear operator other \* self.

    **Return type**

    BaseOperator

    **Raises**

    **NotImplementedError** – if subclass does not support multiplication.
  </Function>

  ### num\_qubits

  <Attribute id="qiskit.quantum_info.SuperOp.num_qubits">
    Return the number of qubits if a N-qubit operator or None otherwise.
  </Attribute>

  ### output\_dims

  <Function id="qiskit.quantum_info.SuperOp.output_dims" signature="output_dims(qargs=None)">
    Return tuple of output dimension for specified subsystems.
  </Function>

  ### power

  <Function id="qiskit.quantum_info.SuperOp.power" signature="power(n)">
    Return the compose of a QuantumChannel with itself n times.

    **Parameters**

    **n** (*int*) – compute the matrix power of the superoperator matrix.

    **Returns**

    the n-times composition channel as a SuperOp object.

    **Return type**

    [SuperOp](#qiskit.quantum_info.SuperOp "qiskit.quantum_info.SuperOp")

    **Raises**

    **QiskitError** – if the input and output dimensions of the QuantumChannel are not equal, or the power is not an integer.
  </Function>

  ### qargs

  <Attribute id="qiskit.quantum_info.SuperOp.qargs">
    Return the qargs for the operator.
  </Attribute>

  ### reshape

  <Function id="qiskit.quantum_info.SuperOp.reshape" signature="reshape(input_dims=None, output_dims=None)">
    Return a shallow copy with reshaped input and output subsystem dimensions.

    **Arg:**

    **input\_dims (None or tuple): new subsystem input dimensions.**

    If None the original input dims will be preserved \[Default: None].

    **output\_dims (None or tuple): new subsystem output dimensions.**

    If None the original output dims will be preserved \[Default: None].

    **Returns**

    returns self with reshaped input and output dimensions.

    **Return type**

    BaseOperator

    **Raises**

    **QiskitError** – if combined size of all subsystem input dimension or subsystem output dimensions is not constant.
  </Function>

  ### rtol

  <Attribute id="qiskit.quantum_info.SuperOp.rtol">
    The relative tolerance parameter for float comparisons.
  </Attribute>

  ### set\_atol

  <Function id="qiskit.quantum_info.SuperOp.set_atol" signature="set_atol(value)" modifiers="classmethod">
    Set the class default absolute tolerance parameter for float comparisons.

    DEPRECATED: use operator.atol = value instead
  </Function>

  ### set\_rtol

  <Function id="qiskit.quantum_info.SuperOp.set_rtol" signature="set_rtol(value)" modifiers="classmethod">
    Set the class default relative tolerance parameter for float comparisons.

    DEPRECATED: use operator.rtol = value instead
  </Function>

  ### subtract

  <Function id="qiskit.quantum_info.SuperOp.subtract" signature="subtract(other)">
    Return the linear operator self - other.

    DEPRECATED: use `operator - other` instead.

    **Parameters**

    **other** (*BaseOperator*) – an operator object.

    **Returns**

    the operator self - other.

    **Return type**

    BaseOperator
  </Function>

  ### tensor

  <Function id="qiskit.quantum_info.SuperOp.tensor" signature="tensor(other)">
    Return the tensor product channel self ⊗ other.

    **Parameters**

    **other** (*QuantumChannel*) – a quantum channel.

    **Returns**

    the tensor product channel self ⊗ other as a SuperOp object.

    **Return type**

    [SuperOp](#qiskit.quantum_info.SuperOp "qiskit.quantum_info.SuperOp")

    **Raises**

    **QiskitError** – if other cannot be converted to a channel.
  </Function>

  ### to\_instruction

  <Function id="qiskit.quantum_info.SuperOp.to_instruction" signature="to_instruction()">
    Convert to a Kraus or UnitaryGate circuit instruction.

    If the channel is unitary it will be added as a unitary gate, otherwise it will be added as a kraus simulator instruction.

    **Returns**

    A kraus instruction for the channel.

    **Return type**

    [qiskit.circuit.Instruction](qiskit.circuit.Instruction "qiskit.circuit.Instruction")

    **Raises**

    **QiskitError** – if input data is not an N-qubit CPTP quantum channel.
  </Function>

  ### to\_operator

  <Function id="qiskit.quantum_info.SuperOp.to_operator" signature="to_operator()">
    Try to convert channel to a unitary representation Operator.
  </Function>

  ### transpose

  <Function id="qiskit.quantum_info.SuperOp.transpose" signature="transpose()">
    Return the transpose of the QuantumChannel.
  </Function>
</Class>