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In
computer science Computer science is the study of computation, automation, and information. Computer science spans theoretical disciplines (such as algorithms, theory of computation, information theory, and automation) to Applied science, practical discipli ...
, the controlled NOT gate (also C-NOT or CNOT), controlled-''X'' gate'','' controlled-bit-flip gate, Feynman gate or controlled Pauli-X is a
quantum logic gate In quantum computing and specifically the quantum circuit model of computation, a quantum logic gate (or simply quantum gate) is a basic quantum circuit operating on a small number of qubits. They are the building blocks of quantum circuits, lik ...
that is an essential component in the construction of a gate-based
quantum computer Quantum computing is a type of computation whose operations can harness the phenomena of quantum mechanics, such as superposition, interference, and entanglement. Devices that perform quantum computations are known as quantum computers. Though ...
. It can be used to entangle and disentangle
Bell state The Bell states or EPR pairs are specific quantum states of two qubits that represent the simplest (and maximal) examples of quantum entanglement; conceptually, they fall under the study of quantum information science. The Bell states are a form o ...
s. Any quantum circuit can be simulated to an arbitrary degree of accuracy using a combination of CNOT gates and single
qubit In quantum computing, a qubit () or quantum bit is a basic unit of quantum information—the quantum version of the classic binary bit physically realized with a two-state device. A qubit is a two-state (or two-level) quantum-mechanical system, ...
rotations. The gate is sometimes named after
Richard Feynman Richard Phillips Feynman (; May 11, 1918 – February 15, 1988) was an American theoretical physicist, known for his work in the path integral formulation of quantum mechanics, the theory of quantum electrodynamics, the physics of the superflu ...
who developed an early notation for quantum gate diagrams in 1986. The CNOT can be expressed in the Pauli basis as: : \mbox = e^= e^. Being both
unitary Unitary may refer to: Mathematics * Unitary divisor * Unitary element * Unitary group * Unitary matrix * Unitary morphism * Unitary operator * Unitary transformation * Unitary representation * Unitarity (physics) * ''E''-unitary inverse semigrou ...
and
Hermitian {{Short description, none Numerous things are named after the French mathematician Charles Hermite (1822–1901): Hermite * Cubic Hermite spline, a type of third-degree spline * Gauss–Hermite quadrature, an extension of Gaussian quadrature m ...
, CNOT has the property e^=(\cos \theta)I+(i\sin \theta) U and U =e^=e^, and is involutory. The CNOT gate can be further decomposed as products of rotation operator gates and exactly one two qubit interaction gate, for example : \mbox =e^R_(-\pi/2)R_(-\pi/2)R_(-\pi/2)R_(\pi/2)R_(\pi/2). In general, any single qubit unitary gate can be expressed as U = e^ , where ''H'' is a
Hermitian matrix In mathematics, a Hermitian matrix (or self-adjoint matrix) is a complex square matrix that is equal to its own conjugate transpose—that is, the element in the -th row and -th column is equal to the complex conjugate of the element in the -th ...
, and then the controlled ''U'' is CU = e^ . The CNOT gate is also used in classical
reversible computing Reversible computing is any model of computation where the computational process, to some extent, is time-reversible. In a model of computation that uses deterministic transitions from one state of the abstract machine to another, a necessary c ...
.


Operation

The CNOT gate operates on a
quantum register In quantum computing, a quantum register is a system comprising multiple qubits. It is the quantum analogue of the classical processor register. Quantum computers perform calculations by manipulating qubits within a quantum register. Definition ...
consisting of 2 qubits. The CNOT gate flips the second qubit (the target qubit) if and only if the first qubit (the control qubit) is , 1\rangle. If \ are the only allowed input values for both qubits, then the TARGET output of the CNOT gate corresponds to the result of a classical
XOR gate XOR gate (sometimes EOR, or EXOR and pronounced as Exclusive OR) is a digital logic gate that gives a true (1 or HIGH) output when the number of true inputs is odd. An XOR gate implements an exclusive or (\nleftrightarrow) from mathematical log ...
. Fixing CONTROL as , 1\rangle, the TARGET output of the CNOT gate yields the result of a classical NOT gate. More generally, the inputs are allowed to be a linear superposition of \. The CNOT gate transforms the quantum state: a, 00\rangle + b, 01\rangle + c, 10\rangle + d, 11\rangle into: a, 00\rangle + b, 01\rangle + d, 10\rangle + c, 11\rangle The action of the CNOT gate can be represented by the matrix (
permutation matrix In mathematics, particularly in matrix theory, a permutation matrix is a square binary matrix that has exactly one entry of 1 in each row and each column and 0s elsewhere. Each such matrix, say , represents a permutation of elements and, when ...
form): : \operatorname = \begin 1 & 0 & 0 & 0 \\ 0 & 1 & 0 & 0 \\ 0 & 0 & 0 & 1 \\ 0 & 0 & 1 & 0 \end. The first experimental realization of a CNOT gate was accomplished in 1995. Here, a single
Beryllium Beryllium is a chemical element with the symbol Be and atomic number 4. It is a steel-gray, strong, lightweight and brittle alkaline earth metal. It is a divalent element that occurs naturally only in combination with other elements to form mi ...
ion in a
trap A trap is a mechanical device used to capture or restrain an animal for purposes such as hunting, pest control, or ecological research. Trap or TRAP may also refer to: Art and entertainment Films and television * ''Trap'' (2015 film), Fil ...
was used. The two qubits were encoded into an optical state and into the vibrational state of the ion within the trap. At the time of the experiment, the reliability of the CNOT-operation was measured to be on the order of 90%. In addition to a regular controlled NOT gate, one could construct a function-controlled NOT gate, which accepts an arbitrary number ''n''+1 of qubits as input, where ''n''+1 is greater than or equal to 2 (a
quantum register In quantum computing, a quantum register is a system comprising multiple qubits. It is the quantum analogue of the classical processor register. Quantum computers perform calculations by manipulating qubits within a quantum register. Definition ...
). This gate flips the last qubit of the register if and only if a built-in function, with the first ''n'' qubits as input, returns a 1. The function-controlled NOT gate is an essential element of the
Deutsch–Jozsa algorithm The Deutsch–Jozsa algorithm is a deterministic quantum algorithm proposed by David Deutsch and Richard Jozsa in 1992 with improvements by Richard Cleve, Artur Ekert, Chiara Macchiavello, and Michele Mosca in 1998. Although of little current p ...
.


Behaviour in the Hadamard transformed basis

When viewed only in the computational basis \, the behaviour of the CNOT appears to be like the equivalent classical gate. However, the simplicity of labelling one qubit the ''control'' and the other the ''target'' does not reflect the complexity of what happens for most input values of both qubits. Insight can be won by expressing the CNOT gate with respect to a Hadamard transformed basis \. The Hadamard transformed basis of a one-qubit
register Register or registration may refer to: Arts entertainment, and media Music * Register (music), the relative "height" or range of a note, melody, part, instrument, etc. * ''Register'', a 2017 album by Travis Miller * Registration (organ), th ...
is given by :, +\rangle = \frac(, 0\rangle + , 1\rangle),\qquad , -\rangle = \frac(, 0\rangle - , 1\rangle), and the corresponding basis of a 2-qubit register is :, ++\rangle = , +\rangle\otimes, +\rangle = \frac(, 0\rangle + , 1\rangle)\otimes(, 0\rangle + , 1\rangle) = \frac(, 00\rangle + , 01\rangle + , 10\rangle + , 11\rangle), etc. Viewing CNOT in this basis, the state of the second qubit remains unchanged, and the state of the first qubit is flipped, according to the state of the second bit. (For details see below.) "Thus, in this basis the sense of which bit is the ''control bit'' and which the ''target bit'' has reversed. But we have not changed the transformation at all, only the way we are thinking about it." The "computational" basis \ is the eigenbasis for the spin in the Z-direction, whereas the Hadamard basis \ is the eigenbasis for spin in the X-direction. Switching X and Z and qubits 1 and 2, then, recovers the original transformation." This expresses a fundamental symmetry of the CNOT gate. The observation that both qubits are (equally) affected in a CNOT interaction is of importance when considering information flow in entangled quantum systems.


Details of the computation

We now proceed to give the details of the computation. Working through each of the Hadamard basis states, the first qubit flips between , +\rangle and , -\rangle when the second qubit is , -\rangle: A quantum circuit that performs a Hadamard transform followed by CNOT then another Hadamard transform, can be described as performing the CNOT gate in the Hadamard basis (i.e. a
change of basis In mathematics, an ordered basis of a vector space of finite dimension allows representing uniquely any element of the vector space by a coordinate vector, which is a sequence of scalars called coordinates. If two different bases are considere ...
): The single-qubit Hadamard transform, H1, is
Hermitian {{Short description, none Numerous things are named after the French mathematician Charles Hermite (1822–1901): Hermite * Cubic Hermite spline, a type of third-degree spline * Gauss–Hermite quadrature, an extension of Gaussian quadrature m ...
and therefore its own inverse. The tensor product of two Hadamard transforms operating (independently) on two qubits is labelled H2. We can therefore write the matrices as: When multiplied out, this yields a matrix that swaps the , 01\rangle and , 11\rangle terms over, while leaving the , 00\rangle and , 10\rangle terms alone. This is equivalent to a CNOT gate where qubit 2 is the control qubit and qubit 1 is the target qubit: \frac \begin\begin 1 & 1 & 1 & 1\\ 1 & -1 & 1 & -1\\ 1 & 1 & -1 & -1\\ 1 & -1 & -1 & 1 \end\end . \begin 1 & 0 & 0 & 0\\ 0 & 1 & 0 & 0\\ 0 & 0 & 0 & 1\\ 0 & 0 & 1 & 0 \end . \frac \begin\begin 1 & 1 & 1 & 1\\ 1 & -1 & 1 & -1\\ 1 & 1 & -1 & -1\\ 1 & -1 & -1 & 1 \end\end = \begin 1 & 0 & 0 & 0\\ 0 & 0 & 0 & 1\\ 0 & 0 & 1 & 0\\ 0 & 1 & 0 & 0 \end


Constructing the Bell State , \Phi^+\rangle

A common application of the CNOT gate is to maximally entangle two qubits into the , \Phi^+\rangle
Bell state The Bell states or EPR pairs are specific quantum states of two qubits that represent the simplest (and maximal) examples of quantum entanglement; conceptually, they fall under the study of quantum information science. The Bell states are a form o ...
; this forms part of the setup of the
superdense coding In quantum information theory, superdense coding (also referred to as ''dense coding'') is a quantum communication protocol to communicate a number of classical bits of information by only transmitting a smaller number of qubits, under the assum ...
, quantum teleportation, and entangled
quantum cryptography Quantum cryptography is the science of exploiting quantum mechanical properties to perform cryptographic tasks. The best known example of quantum cryptography is quantum key distribution which offers an information-theoretically secure solution ...
algorithms. To construct , \Phi^+\rangle, the inputs A (control) and B (target) to the CNOT gate are: \frac(, 0\rangle + , 1\rangle)_A and , 0\rangle_B After applying CNOT, the resulting Bell State \frac(, 00\rangle + , 11\rangle) has the property that the individual qubits can be measured using any basis and will always present a 50/50 chance of resolving to each state. In effect, the individual qubits are in an undefined state. The correlation between the two qubits is the complete description of the state of the two qubits; if we both choose the same basis to measure both qubits and compare notes, the measurements will perfectly correlate. When viewed in the computational basis, it appears that qubit A is affecting qubit B. Changing our viewpoint to the Hadamard basis demonstrates that, in a symmetrical way, qubit B is affecting qubit A. The input state can alternately be viewed as: , +\rangle_A and \frac(, +\rangle + , -\rangle)_B In the Hadamard view, the control and target qubits have conceptually swapped and qubit A is inverted when qubit B is , -\rangle_B. The output state after applying the CNOT gate is \frac(, ++\rangle + , --\rangle) which can be shown to be exactly the same state as \frac(, 00\rangle + , 11\rangle).


C-ROT gate

The C-ROT gate (controlled Rabi rotation) is equivalent to a C-NOT gate except for a \pi /2 rotation of the nuclear spin around the z axis.


Implementations

Trapped ion quantum computers: * Cirac–Zoller controlled-NOT gate * Mølmer–Sørensen gate


See also

*
Toffoli gate In logic circuits, the Toffoli gate (also CCNOT gate), invented by Tommaso Toffoli, is a universal reversible logic gate, which means that any classical reversible circuit can be constructed from Toffoli gates. It is also known as the "controlle ...
(controlled-controlled-NOT gate)


Notes


References

{{reflist


External links


not gate">Michael Westmoreland: "Isolation and information flow in quantum dynamics" - discussion around the Cnot gate
Quantum gates Quantum information science