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QUANTUM COMPUTING

QUANTUM COMPUTING. By Sandeep Neeli. What is a Quantum Computer?. A quantum computer  is a device for computation that makes direct use of  quantum mechanical phenomena, such as superposition  and entanglement, to perform operations on data .

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QUANTUM COMPUTING

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  1. QUANTUM COMPUTING By SandeepNeeli

  2. What is a Quantum Computer? • Aquantum computer is a device for computation that makes direct use • of quantum mechanical phenomena, such as superposition and • entanglement, to perform operations on data. • A theoretical model is the quantum Turing machine, also known as the • universal quantum computer. 

  3. Past and Present • 1965, Intel’s co-founder Gordon Moore saw that the number of transistors and the speed of computer chips were doubling about every 18 months. • If technology followed Moore’s Law, then the shrinking size of circuitry packed into silicon chips would eventually reach a point where individual elements would be no larger than a few atoms. • Here, a problem arises because at the atomic scale of physical laws that govern the behavior and properties of the circuit are inherently quantum in nature, not classical. The limits of classical computers and its computations brought up the idea of computers based on quantum mechanics. • 1970s and 1980s: Theorists proposed idea of quantum computers. • 1985:Deutsh of Oxford University wrote paper on quantum computers that went unnoticed. No one doubted quantum computer would work, but no point to this difficult and expensive task.

  4. 1994, A computer scientist at AT&T Bell Labs suggested that the strange, almost spooky way that a quantum computer could go about its business made it the perfect code-breaking machine. • 1996: first quantum computer by IBM’s Chuang. This computer and others to follow look more like chemistry experiments than computers, but then, they are! • 2001:First working 7-qubit NMR computer demonstrated at IBM's Almaden Research Center. First execution of Shor's algorithm. The number 15 was factored using 1018 identical molecules, each containing 7 atoms. • 2009: Researchers at Yale University created the first rudimentary solid-state quantum processor. The two-qubit superconducting chip was able to run elementary algorithms. Each of the two artificial atoms (or qubits) were made up of a billion aluminum atoms but they acted like a single one that could occupy two different energy states. • 2011:  D-Wave Systems announced the first commercial quantum annealer on the market by the name D-Wave One. The company claims this system uses a 128 qubit processor chipset

  5. Classical Vs Quantum • A classical computer has a memory made up of bits, where each bit represents either a one or a zero. • A quantum computer maintains a sequence of qubits. A single qubit can represent a one, a zero, or, crucially, any quantum superposition of these. • Put another way, a traditional memory register with eight bits can store only one of a possible 256 digital “words”, but a quantum register with eight qubits can represent and compute all 256 words at once. • In traditional computer architecture, the expressions and or and not are • embodied in the electrical circuits. To manipulate qubits, quantum circuits use nuclear magnetic resonance (NMR) or laser pulses to obtain these operations

  6.  In general a quantum computer with n qubits can be in an arbitrary superposition of up to 2n different states simultaneously (this compares to a normal computer that can only be in one of these 2n states at any one time).

  7. Shor’s Algorithm • Shor’s Algorithm is one of the quantum algorithm developed in 1994 named after mathematician Peter Shor. • This is used for integer Factorization which finds the prime factors if given an integer N. • On a quantum computer, to factor an integer N, Shor's algorithm runs in polynomial time. • Specifically it takes time O((log N)3), demonstrating that the integer factorization problem can be efficiently solved on a quantum computer. • Given a quantum computer with a sufficient number of qubits, Shor's algorithm can be used to break public-key cryptography schemes such as the widely used RSA scheme • http://www.doc.ic.ac.uk/~nd/surprise_97/journal/vol4/spb3/

  8. How likely it is to happen in near future • With classical computers gradually approaching their limit, the quantum computer promises to deliver a new level of computational power. With them comes a whole new theory of computation that incorporates the strange effects of quantum mechanics and considers every physical object to be some kind of quantum computer. • This power can only be unleashed with the correct type of algorithm, a type of algorithm that is extremely difficult to formulate. Some algorithms have already been invented; they are proving to have huge implications on the world of cryptography. • This is because they enable the most commonly used cryptography techniques to be broken in a matter of seconds. http://www.bbc.co.uk/news/science-environment-12811199

  9. Quantum computing vs Cryptography • We all use cryptography every day, and most of us do so without knowing it. If we rely on it so much, is there any danger that the security of current cryptosystems could be compromised? • Although still many years away, it turns out that there is such a threat. Current cryptographic techniques are all based around advanced mathematics, but the cryptography of the future is likely to pass to the realm of the physicists. • Physicists have come up with the theoretical notion of a quantum computer which could break virtually all known cryptographic algorithms. • It turns out that most of the mathematical problems that are at the heart of our current cryptographic systems are perfectly suited to being tackled by quantum computers.

  10. The first, Shor's algorithm, can be adapted to crack virtually all • existing public key cryptographic algorithms that are considered to • be secure today. • Shor's algorithm would allow a quantum computer to solve factoring • problems (used by the RSA algorithm), the discrete logarithm • problem (used by the El Gamal algorithm) and even certain versions • of the elliptic curve discrete logarithm problem (used in elliptic curve • cryptography). • A second algorithm known as Grover's algorithm provides a way for • a quantum computer to search an unsorted list, a method which could • be used to crack symmetric ciphers.

  11. Conclusion Much effort is being expended into building a working Quantum computer, but it is likely to be many years before it becomes a reality. Although the advent of quantum computers would be the nail in the coffin for many of the cryptographic algorithms in use today, there are other algorithms and technologies ready to take their place. I believe we can look forward to an age of quantum computers rather than needing to fear that they will make our computing insecure.

  12. References • http://en.wikipedia.org/wiki/Quantum_computer • http://www.bbc.co.uk/news/science-environment-12811199 • http://computer.howstuffworks.com/quantum-computer1.htm • http://alumni.imsa.edu/~matth/quant/299/paper/node21.html

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