cirq.XPowGate

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

Inherits From: EigenGate, Gate

cirq.XPowGate(
    *,
    exponent: cirq.TParamVal = 1.0,
    global_shift: float = 0.0,
    dimension: int = 2
)

Used in the notebooks

Used in the tutorials
Quantum variational algorithm Best practices

The unitary matrix of cirq.XPowGate(exponent=t, global_shift=s) is:

\[ e^{i \pi t (s + 1/2)} \begin{bmatrix} \cos(\pi t /2) & -i \sin(\pi t /2) \\ -i \sin(\pi t /2) & \cos(\pi t /2) \end{bmatrix} \]

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

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

Args
`exponent`	The t in gatet. Determines how much the eigenvalues of the gate are phased by. For example, eigenvectors phased by -1 when `gate1` is applied will gain a relative phase of e^{i pi exponent} when `gateexponent` is applied (relative to eigenvectors unaffected by `gate1`).
`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 for global_shift=s is: `exp(i * pi * s * t)` 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.
`dimension`	Qudit dimension of this gate. For qubits (the default), this is set to 2.

Args

exponent The t in gate**t. Determines how much the eigenvalues of the gate are phased 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 for global_shift=s is:

exp(i * pi * s * t)

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.

dimension Qudit dimension of this gate. For qubits (the default), this is set to 2.

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

Attributes
`dimension`
`exponent`
`global_shift`
`phase_exponent`

Args
`num_controls`	Total number of control qubits.
`control_values`	Which control computational basis state to apply the sub gate. A sequence of length `num_controls` where each entry is an integer (or set of integers) corresponding to the computational basis state (or set of possible values) where that control is enabled. When all controls are enabled, the sub gate is applied. If unspecified, control values default to 1.
`control_qid_shape`	The qid shape of the controls. A tuple of the expected dimension of each control qid. Defaults to `(2,) * num_controls`. Specify this argument when using qudits.

Raises
`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.

cirq.XPowGate

Used in the notebooks

Args

Raises

Attributes

Methods

controlled

in_su2

num_qubits

on

on_each

validate_args

with_canonical_global_phase

with_probability

wrap_in_linear_combination

__add__

__call__

__eq__

__mul__

__ne__

__neg__

__pow__

__rmul__

__sub__

__truediv__

`controlled`

`in_su2`

`num_qubits`

`on`

`on_each`

`validate_args`

`with_canonical_global_phase`

`with_probability`

`wrap_in_linear_combination`

`add`

`call`

`eq`

`mul`

`ne`

`neg`

`pow`

`rmul`

`sub`

`truediv`