Nama : Tera Nurul Harfiah
Kelas : 4ia10
NPM : 56410863
QUANTUM COMPUTATION
A quantum computer (also known as a quantum
supercomputer) is a computation device
that makes direct use of quantum-mechanical phenomena, such as superposition
and entanglement,
to perform operations
on data. Quantum computers are different from
digital computers based on transistors. Whereas
digital computers require data to be encoded into binary digits (bits),
each of which is always in one of two definite states (0 or 1), quantum
computation uses qubits (quantum bits), which can be in
superpositions of states. A theoretical model is the quantum Turing
machine, also known as the universal quantum computer. Quantum
computers share theoretical similarities with non-deterministic
and probabilistic
computers; one example is the ability to be in more than one state
simultaneously. The field of quantum computing was first introduced by Yuri Manin in 1980 and Richard Feynman in 1982. A quantum computer
with spins as quantum bits was also formulated for use as a quantum space–time in 1969.
As of 2014 quantum computing is still in its
infancy but experiments have been carried out in which quantum computational
operations were executed on a very small number of qubits. Both practical and
theoretical research continues, and many national governments and military
funding agencies support quantum computing research to develop quantum computers for both civilian and national
security purposes, such as cryptanalysis.a
Large-scale quantum computers will be able to
solve certain problems much more quickly than any classical computer using the
best currently known algorithms, like integer
factorization using Shor's algorithm or the simulation of quantum
many-body systems. There exist quantum algorithms, such as Simon's algorithm,
which run faster than any possible probabilistic classical algorithm. Given sufficient computational resources,
however, a classical computer could be made to simulate any quantum algorithm;
quantum computation does not violate the Church–Turing
thesis.
QUANTUM ENTANGLEMENT
Quantum entanglement is a physical
phenomenon that occurs when pairs or groups of particles are generated or interact in ways
such that the quantum state
of each particle cannot be described independently – instead, a quantum state
may be given for the system as a whole.
Measurements of physical
properties such as position, momentum, spin, polarization,
etc. performed on entangled particles are found to be appropriately correlated. For example, if a pair of
particles is generated in such a way that their total spin is known to be zero,
and one particle is found to have clockwise spin on a certain axis, then the
spin of the other particle, measured on the same axis, will be found to be
counterclockwise. Because of the nature of quantum measurement, however, this
behavior gives rise to effects that can appear paradoxical: any measurement of a property
of a particle can be seen as acting on that particle (e.g. by collapsing a
number of superimposed
states); and in the case of entangled particles, such action must be on the
entangled system as a whole. It thus appears that one particle of an entangled
pair "knows" what measurement has been performed on the other, and
with what outcome, even though there is no known means for such information to
be communicated between the particles, which at the time of measurement may be
separated by arbitrarily large distances.
Such phenomena were the subject of a 1935 paper
by Albert Einstein,
Boris Podolsky and Nathan Rosen, describing what came to be
known as the EPR paradox, and
several papers by Erwin Schrödinger
shortly thereafter. Einstein and others considered such behavior to be
impossible, as it violated the local realist view of causality (Einstein
referred to it as "spooky action at a distance"),and argued that the
accepted formulation of quantum mechanics
must therefore be incomplete. Later, however, the counterintuitive predictions
of quantum mechanics were verified experimentally. Experiments have been
performed involving measuring the polarization or spin of entangled particles
in different directions, which – by producing violations of Bell's inequality
– demonstrate statistically that
the local realist view cannot be correct. This has been shown to occur even
when the measurements are performed more quickly than light could travel
between the sites of measurement: there is no lightspeed or slower influence that can
pass between the entangled particles. Recent experiments have measured
entangled particles within less than one part in 10,000 of the light travel
time between them. According to the formalism of quantum theory, the effect of
measurement happens instantly. It is not possible, however, to use this effect
to transmit classical information at faster-than-light speeds(see Faster-than-light →
Quantum mechanics).
Quantum entanglement is an area of extremely
active research by the physics community, and its effects have been demonstrated
experimentally with photons, electrons, molecules the size of buckyballs, and even small diamonds.
Research is also focused on the utilization of entanglement effects in communication
and computation.
QUBIT OPERATION
While a classical three-bit state and a quantum
three-qubit state are both eight-dimensional vectors, they are manipulated quite
differently for classical or quantum computation. For computing in either case,
the system must be initialized, for example into the all-zeros string, 
,
corresponding to the vector (1,0,0,0,0,0,0,0). In classical randomized
computation, the system evolves according to the application of stochastic matrices, which preserve that
the probabilities add up to one (i.e., preserve the L1 norm). In quantum computation, on the
other hand, allowed operations are unitary matrices, which are effectively
rotations (they preserve that the sum of the squares add up to one, the Euclidean or L2 norm). (Exactly what
unitaries can be applied depend on the physics of the quantum device.)
Consequently, since rotations can be undone by rotating backward, quantum
computations are reversible.
(Technically, quantum operations can be probabilistic combinations of
unitaries, so quantum computation really does generalize classical computation.
See quantum circuit
for a more precise formulation.)
,
corresponding to the vector (1,0,0,0,0,0,0,0). In classical randomized
computation, the system evolves according to the application of stochastic matrices, which preserve that
the probabilities add up to one (i.e., preserve the L1 norm). In quantum computation, on the
other hand, allowed operations are unitary matrices, which are effectively
rotations (they preserve that the sum of the squares add up to one, the Euclidean or L2 norm). (Exactly what
unitaries can be applied depend on the physics of the quantum device.)
Consequently, since rotations can be undone by rotating backward, quantum
computations are reversible.
(Technically, quantum operations can be probabilistic combinations of
unitaries, so quantum computation really does generalize classical computation.
See quantum circuit
for a more precise formulation.)
Finally, upon termination of the algorithm, the
result needs to be read off. In the case of a classical computer, we sample
from the probability
distribution on the three-bit register to obtain one definite
three-bit string, say 000. Quantum mechanically, we measure
the three-qubit state, which is equivalent to collapsing the quantum state down
to a classical distribution (with the coefficients in the classical state being
the squared magnitudes of the coefficients for the quantum state, as described
above), followed by sampling from that distribution. Note that this destroys
the original quantum state. Many algorithms will only give the correct answer
with a certain probability. However, by repeatedly initializing, running and
measuring the quantum computer, the probability of getting the correct answer
can be increased.
For more details on the sequences of operations
used for various quantum algorithms,
see universal
quantum computer, Shor's algorithm, Grover's algorithm,
Deutsch-Jozsa
algorithm, amplitude
amplification, quantum
Fourier transform, quantum gate, quantum
adiabatic algorithm and quantum error
correction.
QUANTUM GATES
In quantum computing and specifically the quantum circuit model of computation, a quantum
gate (or quantum logic gate) is a basic quantum circuit operating on a small number
of qubits. They are the building blocks of
quantum circuits, like classical logic gates are for conventional digital
circuits.
Unlike many classical logic gates, quantum logic
gates are reversible.
However, classical computing can be performed using only reversible gates. For
example, the reversible Toffoli gate can
implement all Boolean functions. This gate has a direct quantum equivalent,
showing that quantum circuits can perform all operations performed by classical
circuits.
Quantum logic gates are represented by unitary matrices. The most common quantum
gates operate on spaces of one or two qubits, just like the common classical
logic gates operate on one or two bits. This means that as matrices, quantum
gates can be described by 2 × 2 or 4 × 4 unitary matrices.
SHOR’S
ALGORYTHM
Shor's algorithm, named after
mathematician Peter Shor, is a quantum algorithm (an algorithm that runs on a quantum computer) for integer
factorization formulated in 1994. Informally it solves the following
problem: Given an integer N, find its prime factors.
On a quantum computer, to factor an integer N,
Shor's algorithm runs in polynomial time
(the time taken is polynomial in log N, which is the size of the input).
Specifically it takes time O((log N)3),
demonstrating that the integer factorization problem can be efficiently solved
on a quantum computer and is thus in the complexity class BQP.
This is substantially faster than the most efficient known classical factoring
algorithm, the general
number field sieve, which works in sub-exponential
time — about O(e1.9 (log N)1/3 (log log
N)2/3). The efficiency of Shor's algorithm is due to the
efficiency of the quantum
Fourier transform, and modular
exponentiation by repeated
squarings.
If a quantum computer with a sufficient number of
qubits could operate without succumbing to noise
and other quantum decoherence phenomena, Shor's algorithm could be used to
break public-key
cryptography schemes such as the widely used RSA scheme. RSA is based on the assumption
that factoring large numbers is computationally infeasible. So far as is known,
this assumption is valid for classical (non-quantum) computers; no classical
algorithm is known that can factor in polynomial time. However, Shor's
algorithm shows that factoring is efficient on an ideal quantum computer, so it
may be feasible to defeat RSA by constructing a large quantum computer. It was
also a powerful motivator for the design and construction of quantum computers
and for the study of new quantum computer algorithms. It has also facilitated
research on new cryptosystems that are secure from quantum computers, collectively
called post-quantum
cryptography.
In 2001, Shor's algorithm was demonstrated by a
group at IBM, who factored 15 into 3 × 5, using an NMR implementation of a quantum computer
with 7 qubits. However, some doubts have been raised as to
whether IBM's experiment was a true demonstration of quantum computation, since
no entanglement
was observed. Since IBM's implementation,
several other groups have implemented Shor's algorithm using photonic qubits,
emphasizing that entanglement was observed. In 2012, the factorization of 15
was repeated. Also in 2012, the factorization of 21 was achieved, setting the
record for the largest number factored with a quantum computer. In April 2012,
the factorization of 143 was achieved, although this used adiabatic
quantum computation rather than Shor's algorithm.
www.wikipedia.com
Tidak ada komentar:
Posting Komentar