Fredkin gate

The Fredkin gate (also CSWAP gate and conservative logic gate) is a computational circuit suitable for reversible computing, invented by Edward Fredkin. It is universal, which means that any logical or arithmetic operation can be constructed entirely of Fredkin gates. The Fredkin gate is a circuit or device with three inputs and three outputs that transmits the first bit unchanged and swaps the last two bits if, and only if, the first bit is 1.

Definition

The basic Fredkin gate[1] is a controlled swap gate that maps three inputs (C, I1, I2) onto three outputs (C, O1, O2). The C input is mapped directly to the C output. If C = 0, no swap is performed; I1 maps to O1, and I2 maps to O2. Otherwise, the two outputs are swapped so that I1 maps to O2, and I2 maps to O1. It is easy to see that this circuit is reversible, i.e., "undoes" itself when run backwards. A generalized n×n Fredkin gate passes its first n2 inputs unchanged to the corresponding outputs, and swaps its last two outputs if and only if the first n2 inputs are all 1.

The Fredkin gate is the reversible three-bit gate that swaps the last two bits if, and only if, the first bit is 1.

Truth tablePermutation matrix form
INPUT OUTPUT
CI1I2 CO1O2
 0  0  0   0  0  0 
001001
010010
011011
100100
101110
110101
111111

It has the useful property that the numbers of 0s and 1s are conserved throughout, which in the billiard ball model means the same number of balls are output as input. This corresponds nicely to the conservation of mass in physics, and helps to show that the model is not wasteful.

Truth functions with AND, OR, XOR, and NOT

The Fredkin gate can be defined using truth functions with AND, OR, XOR, and NOT, as follows:

O1 = I1 XOR S
O2 = I2 XOR S
Cout= Cin

where S = (I1 XOR I2) AND C

Alternatively:

O1 = (NOT C AND I1) OR (C AND I2)
O2 = (C AND I1) OR (NOT C AND I2)
Cout= Cin

Completeness

One way to see that the Fredkin gate is universal is to observe that it can be used to implement AND, NOT and OR:

If I2 = 0, then O2 = C AND I1.
If I2 = 1, then O1 = C OR I1.
If I1 = 0 and I2 = 1, then O2 = NOT C.

Example

Three-bit full adder (add with carry) using five Fredkin gates

Three-bit full adder (add with carry) using five Fredkin gates. The "g" garbage output bit is (p NOR q) if r=0, and (p NAND q) if r=1.

Inputs on the left, including two constants, go through three gates to quickly determine the parity. The 0 and 1 bits swap places for each input bit that is set, resulting in parity bit on the 4th row and inverse of parity on 5th row.

Then the carry row and the inverse parity row swap if the parity bit is set and swap again if one of the p or q input bits are set (it doesn't matter which is used) and the resulting carry output appears on the 3rd row.

The p and q inputs are only used as gate controls so they appear unchanged in the output.

Quantum Fredkin gate

On March 25, 2016, researchers from Griffith University and the University of Queensland announced they had built a quantum Fredkin gate that uses the quantum entanglement of particles of light to swap qubits. The availability of quantum Fredkin gates may facilitate the construction of quantum computers.[2][3]

See also

References

  1. Brown, Julian, The Quest for the Quantum Computer, New York : Touchstone, 2000.
  2. "Quantum computing is now a big step closer thanks to a new breakthrough: The Fredkin gate".
  3. A quantum Fredkin gate Raj B. Patel, Joseph Ho, Franck Ferreyrol, Timothy C. Ralph and Geoff J. Pryde, Science Advances, 25 Mar 2016, Vol. 2, no. 3, e1501531, DOI: 10.1126/sciadv.1501531

Further reading

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