Abstract
Stochastic processes underlie a vast range of natural and social phenomena. Some processes such as atomic decay feature intrinsic randomness, whereas other complex processes, e.g. traffic congestion, are effectively probabilistic because we cannot track all relevant variables. To simulate a stochastic system's future behaviour, information about its past must be stored and thus memory is a key resource. Quantum information processing promises a memory advantage for stochastic simulation that has been validated in recent proof-of-concept experiments. Yet, in all past works, the memory saving would only become accessible in the limit of a large number of parallel simulations, because the memory registers of individual quantum simulators had the same dimensionality as their classical counterparts. Here, we report the first experimental demonstration that a quantum stochastic simulator can encode the relevant information in fewer dimensions than any classical simulator, thereby achieving a quantum memory advantage even for an individual simulator. Our photonic experiment thus establishes the potential of a new, practical resource saving in the simulation of complex systems.
Highlights
Stochastic processes are ubiquitous in science and technology [1,2]
The minimal memory registers of individual quantum simulators had the same dimensionality as their classical counterparts
We have shown that quantum information processing enables the simulation of a stochastic process with a memory that is smaller in terms of its dimensionality, as compared to any classical counterpart
Summary
Stochastic processes are ubiquitous in science and technology [1,2]. Quantum information reduces the required memory storage for simulating these processes [3,4,5,6,7,8,9,10,11,12,13,14,15,16]—a newly identified advantage [3] that complements other quantum information technological enhancements. Our quantum encoding is achievable with any number of simulators, rather than requiring an asymptotically large array of simulators [4,17] This encoding realizes the quantum advantage for stochastic simulation in its fullest sense. If the time step is 1, it outputs a 2; otherwise, it outputs a 0 Because of this dependence on future time steps, the classical memory for simulation is markedly increased: Instead of needing a single coin (1 bit), a three-level system is provably required [15]. This requirement does not apply to quantum simulators, which we implement using only a single qubit as the memory
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