Book contents
- Frontmatter
- Contents
- Introduction
- Part I Quantum information
- 1 Quantum bits and quantum gates
- 2 An atom in a laser field
- 3 Spins in magnetic fields
- 4 Photon techniques
- 5 Two qubits and beyond
- 6 Measurement and entanglement
- Part II Quantum computation
- Part III Quantum communication
- Appendix: Quantum mechanics
- References
- Index
1 - Quantum bits and quantum gates
from Part I - Quantum information
Published online by Cambridge University Press: 05 August 2012
- Frontmatter
- Contents
- Introduction
- Part I Quantum information
- 1 Quantum bits and quantum gates
- 2 An atom in a laser field
- 3 Spins in magnetic fields
- 4 Photon techniques
- 5 Two qubits and beyond
- 6 Measurement and entanglement
- Part II Quantum computation
- Part III Quantum communication
- Appendix: Quantum mechanics
- References
- Index
Summary
Classical information processing is performed using bits, which are just two-state systems, with the two states called 0 and 1. By grouping bits togetherwe can represent arbitrary pieces of information, and by manipulating these bits we can perform arbitrary computations. The corresponding basic element used in quantum information is the quantum bit, or qubit. This is simply a quantum system with two orthonormal basis states, which we shall call |0⧽ and |1⧽.
There are many possible physical implementations of a qubit, such as spin states of electrons or atomic nuclei, charge states of quantum dots, atomic energy levels, vibrational states of groups of atoms, polarization states of photons, or paths in an interferometer. At this stage the physical implementation is not important: the idea of a qubit is to abstract the discussion away from physical details. Taking the standard approach of quantum information theory, we shall begin by not worrying too much about the properties of these states, or even what their energies are; we shall simply assume that they are eigenstates of the system's Hamiltonian with known eigenvalues (that is, known energies). This approach allows us to concentrate on the fundamental properties of the system, without considering all the tedious details.
We can in principle perform classical information processing on our quantum system by using the two states |0⧽ and |1⧽ as our logical states 0 and 1 and proceeding in the usual fashion, giving rise to the field of reversible computing, which will be explored briefly in Part II. This, however, misses the point.
- Type
- Chapter
- Information
- Quantum Information, Computation and Communication , pp. 5 - 18Publisher: Cambridge University PressPrint publication year: 2012