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1 Poomipat Phusayangkul
Quantum Computing Presented by: Poomipat Phusayangkul Monsit Pornnumpa

2 History of QuanTum Computer
The idea of a computational by physicists and computer scientists like: Charles H. Bennett Charles H. Bennett Paul A. Benioff David Deutsch Richard P. Feynman 1982: Feynman explained how such quantum computer would be able to act as a simulator for quantum physics. 1985: Deutsch realized that Feynman's assertion could eventually lead to a general purpose quantum computer and published a crucial theoretical paper. David Deutsch Richard P. Feynman 1994: Unfortunately, all that could be found were a few rather contrived mathematical problems.

3 WHAT is QUANTUM COMPUTER?
Device for computation that makes direct use of superposition and entanglement, to perform operations on data. In a quantum computer, the amount of data is measured by qubits. Quantum properties of particles can be used to represent and structure data.

4 Coherent Superposition
A qubit can exist in states corresponding to a blend or superposition of these classical states. A qubit can exist simultaneously as both 0 and 1. Experiment of Coherent Superposition:

5 Entanglement A quantum mechanical phenomenon in which of two or more objects reference to each other. It is possible to prepare two particles in a single quantum state such when one is spin-up, another one will always spin-down and vice versa. As a result, measurements performed on one system seem to be instantaneously influencing other systems entangled with it. Closely concerned with the emerging technologies of quantum computing, cryptography, and teleportation.

6 Classical VS Quantum Consider first a classical computer that operates on a 3 bit register. Qubits can be in a superposition of all the classically allowed states. For an n qubit quantum register, recording the state of the register requires 2n complex numbers. Number of classical states encoded in a quantum register grows exponentially with the number of qubits.

7 ! QUANTUM POWER ! Quantum computer could solve Integer factorization problem easily. Most of the popular public key ciphers could be much more quickly broken, including forms of RSA, ElGamal and Diffie-Hellman. The time for a quantum computer to solve a problem will, reducing from years to seconds. Quantum chip Consider a problem that has these four properties: The only way to solve it is to guess answers repeatedly and check them. There are n possible answers to check. Every possible answer takes the same amount of time to check. There are no clues about which answers might be better: generating possibilities randomly is just as good as checking them in some special order.

8 Obstacle in building Quantum Computer
The field of quantum information processing has made numerous promising advancements since its conception, However, a few potentially large obstacles still remain that prevent us from just building one. an ion-trap the core of a quantum computer Below are the list of requirements for a practical quantum computer: scalable physically to increase the number of qubits qubits can be initialized to arbitrary values quantum gates faster than decoherence time Turing-complete gate set qubits can be read easily What errors need correction? To date, the designs of quantum computer involved ion traps, cavity quantum electrodynamics (QED), and NMR.

9 THE END Reference http://en.wikipedia.org/wiki/Quantum_computer
In Thai Reference


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