Quantum Uncertainty Principles for Measurements with Interventions
ORAL
Abstract
Heisenberg's uncertainty principle encapsulates an iconic difference
between classical and quantum mechanics. Whereas any two observable
properties of a classical system may be probed simultaneously, the uncertainty
principle predicts the existence of incompatible observables – observables
whose measurement outcomes cannot be both known to arbitrary precision.
Yet, these observables generally represent a choice of what to measure at a
single time point – and do not represent the most powerful means of probing
unknown environments. To do that, we need interventions. Interactive
measurements permeate diverse sciences. Whether using reinforcement
learning to explore optimal strategies in competitive games or sending data
packets to probe network characteristics – intervention is critical. Can
interactive measurements also be mutually non-compatible, and if so, what are
the fundamental limits in simultaneously predicting their outcomes? Our work
addresses these questions by formulating an entropy uncertainty relation for
general interactive measurements. We then present a case study in causal
inference, illustrating a causal uncertainty relation that predicts an entropic
trade-off in learning the outcomes of measurements compatible with different
causal structures.
between classical and quantum mechanics. Whereas any two observable
properties of a classical system may be probed simultaneously, the uncertainty
principle predicts the existence of incompatible observables – observables
whose measurement outcomes cannot be both known to arbitrary precision.
Yet, these observables generally represent a choice of what to measure at a
single time point – and do not represent the most powerful means of probing
unknown environments. To do that, we need interventions. Interactive
measurements permeate diverse sciences. Whether using reinforcement
learning to explore optimal strategies in competitive games or sending data
packets to probe network characteristics – intervention is critical. Can
interactive measurements also be mutually non-compatible, and if so, what are
the fundamental limits in simultaneously predicting their outcomes? Our work
addresses these questions by formulating an entropy uncertainty relation for
general interactive measurements. We then present a case study in causal
inference, illustrating a causal uncertainty relation that predicts an entropic
trade-off in learning the outcomes of measurements compatible with different
causal structures.
*This work is supported by the Singapore Ministry of Education Tier 1 Grants RG146/20 and RG77/22 (S), the NRF2021-QEP2-02-P06 from the Singapore ResearchFoundation and the Singapore Ministry of Education Tier 2 Grant T2EP50221-0014, the FQXi R-710-000-146-720 Grant “Are quantum agents more energetically efficient atmaking predictions?”
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Publication: Yunlong Xiao, Yuxiang Yang, Ximing Wang,Qing Liu,and Mile Gu, "Quantum Uncertainty Principles for Measurements with Interventions", In preparation
Presenters
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Yunlong Xiao
- Institute of High Performance Computing