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2016:program:dubravko_horvat [2016/06/29 21:51] berislav |
2016:program:dubravko_horvat [2016/07/01 21:47] (current) berislav |
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| ====== Time-evolution and Quantum Computing ====== | ====== Time-evolution and Quantum Computing ====== | ||
| - | <blockquote>**Dubravko Horvat** | + | **Dubravko Horvat** |
| + | \\ //Faculty of Electrical Engineering and Computing// (FER), University of Zagreb | ||
| + | <blockquote> | ||
| Quantum circuits are one possibility to implement quantum computation. Stemming from the adiabatic theorem in quantum mechanics where a time-changing Hamiltonian will remain in the same energy level over time as long as the evolution time, the adiabatic computing opens another possibility to implement time-dependent quantum computation. In this way time evolution is introduced in a formal way in quantum computation. Here the basic ideas of quantum computation will be given and the mimicking of the time evolution within a quantum ground state will be introduced. Some features of the adiabatic quantum computers will be given and open questions will be posed.</blockquote> | Quantum circuits are one possibility to implement quantum computation. Stemming from the adiabatic theorem in quantum mechanics where a time-changing Hamiltonian will remain in the same energy level over time as long as the evolution time, the adiabatic computing opens another possibility to implement time-dependent quantum computation. In this way time evolution is introduced in a formal way in quantum computation. Here the basic ideas of quantum computation will be given and the mimicking of the time evolution within a quantum ground state will be introduced. Some features of the adiabatic quantum computers will be given and open questions will be posed.</blockquote> | ||