The paper presents a unified approach to constructing efficient unitary t-designs and pseudorandom unitaries (PRUs) by introducing the "PFC ensemble".
Key highlights:
The PFC ensemble - the product of a random computational basis permutation (P), a random binary phase operator (F), and a random Clifford unitary (C) - is shown to approximate the Haar measure up to exponentially high moments.
By replacing the random permutation and phase operators in the PFC ensemble with their t-wise independent counterparts, the authors construct the first linear-depth t-designs. This improves upon prior constructions that required quadratic depth in t.
By replacing the random permutation and phase operators in the PFC ensemble with pseudorandom counterparts, the authors construct the first non-adaptive PRUs, where the distinguisher can make parallel queries to the unitary on arbitrary entangled states. Prior work only allowed restricted classes of input states.
For the case of isometries (rather than unitaries), the authors show that a small modification of the PRU construction achieves adaptive security, giving the first construction of adaptive pseudorandom isometries.
The authors also discuss potential applications of PRUs in quantum cryptography and modeling chaotic quantum systems.
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by Tony Metger,... klo arxiv.org 04-22-2024
https://arxiv.org/pdf/2404.12647.pdfSyvällisempiä Kysymyksiä