Physics:State space
In physics, a state space is an abstract space in which different "positions" represent, not literal locations, but rather states of some physical system. This makes it a type of phase space.
Quantum Mechanics
Specifically, in quantum mechanics a state space is a complex Hilbert space in which each unit vector represents a different state that could come out of a measurement. Each unit vector specifies a different dimension, so the numbers of dimensions in this Hilbert space depends on the system we choose to describe.[1] Any state vector in this space can be written as a linear combination of unit vectors. Having an nonzero component along multiple dimensions is called a superposition. These state vectors, using Dirac's bra–ket notation, can often be treated like coordinate vectors and operated on using the rules of linear algebra. This Dirac formalism of quantum mechanics can replace calculation of complicated integrals with simpler vector operations.
See also
- Configuration space for the space of possible positions that a physical system may attain
- Configuration space (mathematics) for the space of positions of particles in a topological space
- State space (controls) for information about state space in control engineering
- State space for information about discrete state space in computer science
Notes
- ↑ McIntyre, David (2012). Quantum Mechanics: A Paradigms Approach (1st ed.). Pearson. ISBN 978-0321765796.
References
- Claude Cohen-Tannoudji (1977). Quantum Mechanics. John Wiley & Sons. Inc.. ISBN 0-471-16433-X.
- David J. Griffiths (1995). Introduction to Quantum Mechanics. Prentice Hall. ISBN 0-13-124405-1.
- David H. McIntyre (2012). Quantum Mechanics: A Paradigms Approach. Pearson. ISBN 978-0321765796.
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