In quantum physics, a quantum instrument is a mathematical description of a quantum measurement, capturing both the classical and quantum outputs.[1] It can be equivalently understood as a quantum channel that takes as input a quantum system and has as its output two systems: a classical system containing the outcome of the measurement and a quantum system containing the post-measurement state.[2]
Let be a countable set describing the outcomes of a quantum measurement, and let denote a collection of trace-non-increasing completely positive maps, such that the sum of all is trace-preserving, i.e. for all positive operators
Now for describing a measurement by an instrument , the maps are used to model the mapping from an input state to the output state of a measurement conditioned on a classical measurement outcome . Therefore, the probability that a specific measurement outcome occurs on a state is given by[3][4]
The state after a measurement with the specific outcome is given by[3][4]
If the measurement outcomes are recorded in a classical register, whose states are modeled by a set of orthonormal projections , then the action of an instrument is given by a quantum channel with[2]
Here and are the Hilbert spaces corresponding to the input and the output systems of the instrument.
Just as a completely positive trace preserving (CPTP) map can always be considered as the reduction of unitary evolution on a system with an initially unentangled auxiliary, quantum instruments are the reductions of projective measurement with a conditional unitary, and also reduce to CPTP maps and POVMs when ignore measurement outcomes and state evolution, respectively.[4] In John Smolin's terminology, this is an example of "going to the Church of the Larger Hilbert space".
Any quantum instrument on a system can be modeled as a projective measurement on and (jointly) an uncorrelated auxiliary followed by a unitary conditional on the measurement outcome.[3][4] Let (with and ) be the normalized initial state of , let (with and ) be a projective measurement on , and let (with ) be unitaries on . Then one can check that
defines a quantum instrument.[4] Furthermore, one can also check that any choice of quantum instrument can be obtained with this construction for some choice of and .[4]
In this sense, a quantum instrument can be thought of as the reduction of a projective measurement combined with a conditional unitary.
Any quantum instrument immediately induces a CPTP map, i.e., a quantum channel:[4]
This can be thought of as the overall effect of the measurement on the quantum system if the measurement outcome is thrown away.
Any quantum instrument immediately induces a positive operator-valued measurement (POVM):
where are any choice of Kraus operators for ,[4]
The Kraus operators are not uniquely determined by the CP maps , but the above definition of the POVM elements is the same for any choice.[4] The POVM can be thought of as the measurement of the quantum system if the information about how the system is affected by the measurement is thrown away.