A gate that rotates around the Z axis of the Bloch sphere.

Inherits From: EigenGate, SingleQubitGate, Gate

Used in the notebooks

Used in the tutorials

The unitary matrix of ZPowGate(exponent=t) is:

[[1, 0],
 [0, g]]


g = exp(i·π·t).

Note in particular that this gate has a global phase factor of e^{i·π·t/2} vs the traditionally defined rotation matrices about the Pauli Z axis. See cirq.Rz for rotations without the global phase. The global phase factor can be adjusted by using the global_shift parameter when initializing.

cirq.Z, the Pauli Z gate, is an instance of this gate at exponent=1.

exponent The t in gate**t. Determines how much the eigenvalues of the gate are scaled by. For example, eigenvectors phased by -1 when gate**1 is applied will gain a relative phase of e^{i pi exponent} when gate**exponent is applied (relative to eigenvectors unaffected by gate**1).
global_shift Offsets the eigenvalues of the gate at exponent=1. In effect, this controls a global phase factor on the gate's unitary matrix. The factor is:

exp(i * pi * global_shift * exponent)

For example, cirq.X**t uses a global_shift of 0 but cirq.rx(t) uses a global_shift of -0.5, which is why cirq.unitary(cirq.rx(pi)) equals -iX instead of X.

ValueError If the supplied exponent is a complex number with an imaginary component.





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Returns a controlled ZPowGate, using a CZPowGate where possible.

The controlled method of the Gate class, of which this class is a child, returns a ControlledGate. This method overrides this behavior to return a CZPowGate or a ControlledGate of a CZPowGate, when this is possible.

The conditions for the override to occur are:

* The `global_shift` of the `ZPowGate` is 0.
* The `control_values` and `control_qid_shape` are compatible with
    the `CZPowGate`:
    * The last value of `control_qid_shape` is a qubit.
    * The last value of `control_values` corresponds to the
        control being satisfied if that last qubit is 1 and
        not satisfied if the last qubit is 0.

If these conditions are met, then the returned object is a CZPowGate or, in the case that there is more than one controlled qudit, a ControlledGate with the Gate being a CZPowGate. In the latter case the ControlledGate is controlled by one less qudit than specified in control_values and control_qid_shape (since one of these, the last qubit, is used as the control for the CZPowGate).

If the above conditions are not met, a ControlledGate of this gate will be returned.


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Returns an equal-up-global-phase gate from the group SU2.


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The number of qubits this gate acts on.


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Returns an application of this gate to the given qubits.

*qubits The collection of qubits to potentially apply the gate to.


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Returns a list of operations applying the gate to all targets.

*targets The qubits to apply this gate to. For single-qubit gates this can be provided as varargs or a combination of nested iterables. For multi-qubit gates this must be provided as an Iterable[Sequence[Qid]], where each sequence has num_qubits qubits.

Operations applying this gate to the target qubits.

ValueError If targets are not instances of Qid or Iterable[Qid]. If the gate qubit number is incompatible.
TypeError If a single target is supplied and it is not iterable.


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Checks if this gate can be applied to the given qubits.

By default checks that:

  • inputs are of type Qid
  • len(qubits) == num_qubits()
  • qubit_i.dimension == qid_shape[i] for all qubits

Child classes can override. The child implementation should call super().validate_args(qubits) then do custom checks.

qubits The sequence of qubits to potentially apply the gate to.


  • ValueError: The gate can't be applied to the qubits.


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Returns an equal-up-global-phase standardized form of the gate.


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Call self as a function.


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