qiskit-documentation/docs/api/qiskit/0.29/qiskit.quantum_info.Statevector.mdx

---
title: Statevector (v0.29)
description: API reference for qiskit.quantum_info.Statevector in qiskit v0.29
in_page_toc_min_heading_level: 1
python_api_type: class
python_api_name: qiskit.quantum_info.Statevector
---

# Statevector

<Class id="qiskit.quantum_info.Statevector" isDedicatedPage={true} github="https://github.com/qiskit/qiskit/tree/stable/0.18/qiskit/quantum_info/states/statevector.py" signature="Statevector(data, dims=None)" modifiers="class">
  Bases: `qiskit.quantum_info.states.quantum_state.QuantumState`, `qiskit.quantum_info.operators.mixins.tolerances.TolerancesMixin`

  Statevector class

  Initialize a statevector object.

  **Parameters**

  *   \*\*(****np.array**** or ****list**** or ****Statevector**** or ****Operator**** or \*\***QuantumCircuit or** (*data*) – qiskit.circuit.Instruction): Data from which the statevector can be constructed. This can be either a complex vector, another statevector, a ```Operator` with only one column or a ``QuantumCircuit``` or `Instruction`. If the data is a circuit or instruction, the statevector is constructed by assuming that all qubits are initialized to the zero state.
  *   **dims** (*int or tuple or list*) – Optional. The subsystem dimension of the state (See additional information).

  **Raises**

  **QiskitError** – if input data is not valid.

  **Additional Information:**

  The `dims` kwarg can be None, an integer, or an iterable of integers.

  *   `Iterable` – the subsystem dimensions are the values in the list with the total number of subsystems given by the length of the list.
  *   `Int` or `None` – the length of the input vector specifies the total dimension of the density matrix. If it is a power of two the state will be initialized as an N-qubit state. If it is not a power of two the state will have a single d-dimensional subsystem.

  ## Methods

  <span id="qiskit-quantum-info-statevector-conjugate" />

  ### conjugate

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

  <span id="qiskit-quantum-info-statevector-copy" />

  ### copy

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

  <span id="qiskit-quantum-info-statevector-dims" />

  ### dims

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

  <span id="qiskit-quantum-info-statevector-draw" />

  ### draw

  <Function id="qiskit.quantum_info.Statevector.draw" signature="Statevector.draw(output=None, **drawer_args)">
    Return a visualization of the Statevector.

    **repr**: ASCII TextMatrix of the state’s `__repr__`.

    **text**: ASCII TextMatrix that can be printed in the console.

    **latex**: An IPython Latex object for displaying in Jupyter Notebooks.

    **latex\_source**: Raw, uncompiled ASCII source to generate array using LaTeX.

    **qsphere**: Matplotlib figure, rendering of statevector using plot\_state\_qsphere().

    **hinton**: Matplotlib figure, rendering of statevector using plot\_state\_hinton().

    **bloch**: Matplotlib figure, rendering of statevector using plot\_bloch\_multivector().

    **city**: Matplotlib figure, rendering of statevector using plot\_state\_city().

    **paulivec**: Matplotlib figure, rendering of statevector using plot\_state\_paulivec().

    **Parameters**

    *   **output** (*str*) – Select the output method to use for drawing the state. Valid choices are repr, text, latex, latex\_source, qsphere, hinton, bloch, city, or paulivec. Default is repr. Default can be changed by adding the line `state_drawer = <default>` to `~/.qiskit/settings.conf` under `[default]`.
    *   **drawer\_args** – Arguments to be passed directly to the relevant drawing function or constructor (TextMatrix(), array\_to\_latex(), plot\_state\_qsphere(), plot\_state\_hinton() or plot\_bloch\_multivector()). See the relevant function under qiskit.visualization for that function’s documentation.

    **Returns**

    `matplotlib.Figure` or `str` or `TextMatrix` or `IPython.display.Latex`: Drawing of the Statevector.

    **Raises**

    **ValueError** – when an invalid output method is selected.
  </Function>

  <span id="qiskit-quantum-info-statevector-equiv" />

  ### equiv

  <Function id="qiskit.quantum_info.Statevector.equiv" signature="Statevector.equiv(other, rtol=None, atol=None)">
    Return True if other is equivalent as a statevector up to global phase.

    <Admonition title="Note" type="note">
      If other is not a Statevector, but can be used to initialize a statevector object, this will check that Statevector(other) is equivalent to the current statevector up to global phase.
    </Admonition>

    **Parameters**

    *   **other** ([*Statevector*](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")) – an object from which a `Statevector` can be constructed.
    *   **rtol** (*float*) – relative tolerance value for comparison.
    *   **atol** (*float*) – absolute tolerance value for comparison.

    **Returns**

    True if statevectors are equivalent up to global phase.

    **Return type**

    bool
  </Function>

  <span id="qiskit-quantum-info-statevector-evolve" />

  ### evolve

  <Function id="qiskit.quantum_info.Statevector.evolve" signature="Statevector.evolve(other, qargs=None)">
    Evolve a quantum state by the operator.

    **Parameters**

    *   **other** ([*Operator*](qiskit.quantum_info.Operator "qiskit.quantum_info.Operator")) – The operator to evolve by.
    *   **qargs** (*list*) – a list of Statevector subsystem positions to apply the operator on.

    **Returns**

    the output quantum state.

    **Return type**

    [Statevector](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")

    **Raises**

    **QiskitError** – if the operator dimension does not match the specified Statevector subsystem dimensions.
  </Function>

  <span id="qiskit-quantum-info-statevector-expand" />

  ### expand

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

    **Parameters**

    **other** ([*Statevector*](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")) – a quantum state object.

    **Returns**

    the tensor product state other ⊗ self.

    **Return type**

    [Statevector](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")

    **Raises**

    **QiskitError** – if other is not a quantum state.
  </Function>

  <span id="qiskit-quantum-info-statevector-expectation-value" />

  ### expectation\_value

  <Function id="qiskit.quantum_info.Statevector.expectation_value" signature="Statevector.expectation_value(oper, qargs=None)">
    Compute the expectation value of an operator.

    **Parameters**

    *   **oper** ([*Operator*](qiskit.quantum_info.Operator "qiskit.quantum_info.Operator")) – an operator to evaluate expval of.
    *   **qargs** (*None or list*) – subsystems to apply operator on.

    **Returns**

    the expectation value.

    **Return type**

    complex
  </Function>

  <span id="qiskit-quantum-info-statevector-from-instruction" />

  ### from\_instruction

  <Function id="qiskit.quantum_info.Statevector.from_instruction" signature="Statevector.from_instruction(instruction)" modifiers="classmethod">
    Return the output statevector of an instruction.

    The statevector is initialized in the state $|{0,\ldots,0}\rangle$ of the same number of qubits as the input instruction or circuit, evolved by the input instruction, and the output statevector returned.

    **Parameters**

    **instruction** ([*qiskit.circuit.Instruction*](qiskit.circuit.Instruction "qiskit.circuit.Instruction")  *or*[*QuantumCircuit*](qiskit.circuit.QuantumCircuit "qiskit.circuit.QuantumCircuit")) – instruction or circuit

    **Returns**

    The final statevector.

    **Return type**

    [Statevector](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")

    **Raises**

    **QiskitError** – if the instruction contains invalid instructions for the statevector simulation.
  </Function>

  <span id="qiskit-quantum-info-statevector-from-int" />

  ### from\_int

  <Function id="qiskit.quantum_info.Statevector.from_int" signature="Statevector.from_int(i, dims)" modifiers="static">
    Return a computational basis statevector.

    **Parameters**

    *   **i** (*int*) – the basis state element.
    *   **dims** (*int or tuple or list*) – The subsystem dimensions of the statevector (See additional information).

    **Returns**

    The computational basis state $|i\rangle$.

    **Return type**

    [Statevector](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")

    #### Additional Information:

    The `dims` kwarg can be an integer or an iterable of integers.

    *   `Iterable` – the subsystem dimensions are the values in the list with the total number of subsystems given by the length of the list.
    *   `Int` – the integer specifies the total dimension of the state. If it is a power of two the state will be initialized as an N-qubit state. If it is not a power of two the state will have a single d-dimensional subsystem.
  </Function>

  <span id="qiskit-quantum-info-statevector-from-label" />

  ### from\_label

  <Function id="qiskit.quantum_info.Statevector.from_label" signature="Statevector.from_label(label)" modifiers="classmethod">
    Return a tensor product of Pauli X,Y,Z eigenstates.

    | Label | Statevector                     |
    | ----- | ------------------------------- |
    | `"0"` | $[1, 0]$                        |
    | `"1"` | $[0, 1]$                        |
    | `"+"` | $[1 / \sqrt{2}, 1 / \sqrt{2}]$  |
    | `"-"` | $[1 / \sqrt{2}, -1 / \sqrt{2}]$ |
    | `"r"` | $[1 / \sqrt{2}, i / \sqrt{2}]$  |
    | `"l"` | $[1 / \sqrt{2}, -i / \sqrt{2}]$ |

    **Parameters**

    **label** (*string*) – a eigenstate string ket label (see table for allowed values).

    **Returns**

    The N-qubit basis state density matrix.

    **Return type**

    [Statevector](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")

    **Raises**

    **QiskitError** – if the label contains invalid characters, or the length of the label is larger than an explicitly specified num\_qubits.
  </Function>

  <span id="qiskit-quantum-info-statevector-is-valid" />

  ### is\_valid

  <Function id="qiskit.quantum_info.Statevector.is_valid" signature="Statevector.is_valid(atol=None, rtol=None)">
    Return True if a Statevector has norm 1.
  </Function>

  <span id="qiskit-quantum-info-statevector-measure" />

  ### measure

  <Function id="qiskit.quantum_info.Statevector.measure" signature="Statevector.measure(qargs=None)">
    Measure subsystems and return outcome and post-measure state.

    Note that this function uses the QuantumStates internal random number generator for sampling the measurement outcome. The RNG seed can be set using the [`seed()`](qiskit.quantum_info.Statevector#seed "qiskit.quantum_info.Statevector.seed") method.

    **Parameters**

    **qargs** (*list or None*) – subsystems to sample measurements for, if None sample measurement of all subsystems (Default: None).

    **Returns**

    **the pair `(outcome, state)` where `outcome` is the**

    measurement outcome string label, and `state` is the collapsed post-measurement state for the corresponding outcome.

    **Return type**

    tuple
  </Function>

  <span id="qiskit-quantum-info-statevector-probabilities" />

  ### probabilities

  <Function id="qiskit.quantum_info.Statevector.probabilities" signature="Statevector.probabilities(qargs=None, decimals=None)">
    Return the subsystem measurement probability vector.

    Measurement probabilities are with respect to measurement in the computation (diagonal) basis.

    **Parameters**

    *   **qargs** (*None or list*) – subsystems to return probabilities for, if None return for all subsystems (Default: None).
    *   **decimals** (*None or int*) – the number of decimal places to round values. If None no rounding is done (Default: None).

    **Returns**

    The Numpy vector array of probabilities.

    **Return type**

    np.array

    **Examples**

    Consider a 2-qubit product state $|\psi\rangle=|+\rangle\otimes|0\rangle$.

    ```python
    from qiskit.quantum_info import Statevector

    psi = Statevector.from_label('+0')

    # Probabilities for measuring both qubits
    probs = psi.probabilities()
    print('probs: {}'.format(probs))

    # Probabilities for measuring only qubit-0
    probs_qubit_0 = psi.probabilities([0])
    print('Qubit-0 probs: {}'.format(probs_qubit_0))

    # Probabilities for measuring only qubit-1
    probs_qubit_1 = psi.probabilities([1])
    print('Qubit-1 probs: {}'.format(probs_qubit_1))
    ```

    ```
    probs: [0.5 0.  0.5 0. ]
    Qubit-0 probs: [1. 0.]
    Qubit-1 probs: [0.5 0.5]
    ```

    We can also permute the order of qubits in the `qargs` list to change the qubit position in the probabilities output

    ```python
    from qiskit.quantum_info import Statevector

    psi = Statevector.from_label('+0')

    # Probabilities for measuring both qubits
    probs = psi.probabilities([0, 1])
    print('probs: {}'.format(probs))

    # Probabilities for measuring both qubits
    # but swapping qubits 0 and 1 in output
    probs_swapped = psi.probabilities([1, 0])
    print('Swapped probs: {}'.format(probs_swapped))
    ```

    ```
    probs: [0.5 0.  0.5 0. ]
    Swapped probs: [0.5 0.5 0.  0. ]
    ```
  </Function>

  <span id="qiskit-quantum-info-statevector-probabilities-dict" />

  ### probabilities\_dict

  <Function id="qiskit.quantum_info.Statevector.probabilities_dict" signature="Statevector.probabilities_dict(qargs=None, decimals=None)">
    Return the subsystem measurement probability dictionary.

    Measurement probabilities are with respect to measurement in the computation (diagonal) basis.

    This dictionary representation uses a Ket-like notation where the dictionary keys are qudit strings for the subsystem basis vectors. If any subsystem has a dimension greater than 10 comma delimiters are inserted between integers so that subsystems can be distinguished.

    **Parameters**

    *   **qargs** (*None or list*) – subsystems to return probabilities for, if None return for all subsystems (Default: None).
    *   **decimals** (*None or int*) – the number of decimal places to round values. If None no rounding is done (Default: None).

    **Returns**

    The measurement probabilities in dict (ket) form.

    **Return type**

    dict
  </Function>

  <span id="qiskit-quantum-info-statevector-purity" />

  ### purity

  <Function id="qiskit.quantum_info.Statevector.purity" signature="Statevector.purity()">
    Return the purity of the quantum state.
  </Function>

  <span id="qiskit-quantum-info-statevector-reset" />

  ### reset

  <Function id="qiskit.quantum_info.Statevector.reset" signature="Statevector.reset(qargs=None)">
    Reset state or subsystems to the 0-state.

    **Parameters**

    **qargs** (*list or None*) – subsystems to reset, if None all subsystems will be reset to their 0-state (Default: None).

    **Returns**

    the reset state.

    **Return type**

    [Statevector](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")

    #### Additional Information:

    If all subsystems are reset this will return the ground state on all subsystems. If only a some subsystems are reset this function will perform a measurement on those subsystems and evolve the subsystems so that the collapsed post-measurement states are rotated to the 0-state. The RNG seed for this sampling can be set using the [`seed()`](qiskit.quantum_info.Statevector#seed "qiskit.quantum_info.Statevector.seed") method.
  </Function>

  <span id="qiskit-quantum-info-statevector-reverse-qargs" />

  ### reverse\_qargs

  <Function id="qiskit.quantum_info.Statevector.reverse_qargs" signature="Statevector.reverse_qargs()">
    Return a Statevector with reversed subsystem ordering.

    For a tensor product state this is equivalent to reversing the order of tensor product subsystems. For a statevector $|\psi \rangle = |\psi_{n-1} \rangle \otimes ... \otimes |\psi_0 \rangle$ the returned statevector will be $|\psi_{0} \rangle \otimes ... \otimes |\psi_{n-1} \rangle$.

    **Returns**

    the Statevector with reversed subsystem order.

    **Return type**

    [Statevector](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")
  </Function>

  <span id="qiskit-quantum-info-statevector-sample-counts" />

  ### sample\_counts

  <Function id="qiskit.quantum_info.Statevector.sample_counts" signature="Statevector.sample_counts(shots, qargs=None)">
    Sample a dict of qubit measurement outcomes in the computational basis.

    **Parameters**

    *   **shots** (*int*) – number of samples to generate.
    *   **qargs** (*None or list*) – subsystems to sample measurements for, if None sample measurement of all subsystems (Default: None).

    **Returns**

    sampled counts dictionary.

    **Return type**

    [Counts](qiskit.result.Counts "qiskit.result.Counts")

    Additional Information:

    > This function *samples* measurement outcomes using the measure [`probabilities()`](qiskit.quantum_info.Statevector#probabilities "qiskit.quantum_info.Statevector.probabilities") for the current state and qargs. It does not actually implement the measurement so the current state is not modified.
    >
    > The seed for random number generator used for sampling can be set to a fixed value by using the stats [`seed()`](qiskit.quantum_info.Statevector#seed "qiskit.quantum_info.Statevector.seed") method.
  </Function>

  <span id="qiskit-quantum-info-statevector-sample-memory" />

  ### sample\_memory

  <Function id="qiskit.quantum_info.Statevector.sample_memory" signature="Statevector.sample_memory(shots, qargs=None)">
    Sample a list of qubit measurement outcomes in the computational basis.

    **Parameters**

    *   **shots** (*int*) – number of samples to generate.
    *   **qargs** (*None or list*) – subsystems to sample measurements for, if None sample measurement of all subsystems (Default: None).

    **Returns**

    list of sampled counts if the order sampled.

    **Return type**

    np.array

    Additional Information:

    > This function *samples* measurement outcomes using the measure [`probabilities()`](qiskit.quantum_info.Statevector#probabilities "qiskit.quantum_info.Statevector.probabilities") for the current state and qargs. It does not actually implement the measurement so the current state is not modified.
    >
    > The seed for random number generator used for sampling can be set to a fixed value by using the stats [`seed()`](qiskit.quantum_info.Statevector#seed "qiskit.quantum_info.Statevector.seed") method.
  </Function>

  <span id="qiskit-quantum-info-statevector-seed" />

  ### seed

  <Function id="qiskit.quantum_info.Statevector.seed" signature="Statevector.seed(value=None)">
    Set the seed for the quantum state RNG.
  </Function>

  <span id="qiskit-quantum-info-statevector-tensor" />

  ### tensor

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

    **Parameters**

    **other** ([*Statevector*](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")) – a quantum state object.

    **Returns**

    the tensor product operator self ⊗ other.

    **Return type**

    [Statevector](qiskit.quantum_info.Statevector "qiskit.quantum_info.Statevector")

    **Raises**

    **QiskitError** – if other is not a quantum state.
  </Function>

  <span id="qiskit-quantum-info-statevector-to-dict" />

  ### to\_dict

  <Function id="qiskit.quantum_info.Statevector.to_dict" signature="Statevector.to_dict(decimals=None)">
    Convert the statevector to dictionary form.

    This dictionary representation uses a Ket-like notation where the dictionary keys are qudit strings for the subsystem basis vectors. If any subsystem has a dimension greater than 10 comma delimiters are inserted between integers so that subsystems can be distinguished.

    **Parameters**

    **decimals** (*None or int*) – the number of decimal places to round values. If None no rounding is done (Default: None).

    **Returns**

    the dictionary form of the Statevector.

    **Return type**

    dict

    **Example**

    The ket-form of a 2-qubit statevector $|\psi\rangle = |-\rangle\otimes |0\rangle$

    ```python
    from qiskit.quantum_info import Statevector

    psi = Statevector.from_label('-0')
    print(psi.to_dict())
    ```

    ```
    {'00': (0.7071067811865475+0j), '10': (-0.7071067811865475+0j)}
    ```

    For non-qubit subsystems the integer range can go from 0 to 9. For example in a qutrit system

    ```python
    import numpy as np
    from qiskit.quantum_info import Statevector

    vec = np.zeros(9)
    vec[0] = 1 / np.sqrt(2)
    vec[-1] = 1 / np.sqrt(2)
    psi = Statevector(vec, dims=(3, 3))
    print(psi.to_dict())
    ```

    ```
    {'00': (0.7071067811865475+0j), '22': (0.7071067811865475+0j)}
    ```

    For large subsystem dimensions delimiters are required. The following example is for a 20-dimensional system consisting of a qubit and 10-dimensional qudit.

    ```python
    import numpy as np
    from qiskit.quantum_info import Statevector

    vec = np.zeros(2 * 10)
    vec[0] = 1 / np.sqrt(2)
    vec[-1] = 1 / np.sqrt(2)
    psi = Statevector(vec, dims=(2, 10))
    print(psi.to_dict())
    ```

    ```
    {'00': (0.7071067811865475+0j), '91': (0.7071067811865475+0j)}
    ```
  </Function>

  <span id="qiskit-quantum-info-statevector-to-operator" />

  ### to\_operator

  <Function id="qiskit.quantum_info.Statevector.to_operator" signature="Statevector.to_operator()">
    Convert state to a rank-1 projector operator
  </Function>

  <span id="qiskit-quantum-info-statevector-trace" />

  ### trace

  <Function id="qiskit.quantum_info.Statevector.trace" signature="Statevector.trace()">
    Return the trace of the quantum state as a density matrix.
  </Function>

  ## Attributes

  ### atol

  <Attribute id="qiskit.quantum_info.Statevector.atol" attributeValue="1e-08" />

  ### data

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

  ### dim

  <Attribute id="qiskit.quantum_info.Statevector.dim">
    Return total state dimension.
  </Attribute>

  ### num\_qubits

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

  ### rtol

  <Attribute id="qiskit.quantum_info.Statevector.rtol" attributeValue="1e-05" />

  ### settings

  <Attribute id="qiskit.quantum_info.Statevector.settings">
    Return settings.

    **Return type**

    `Dict`
  </Attribute>
</Class>