Lower Bounds for Function Inversion with Quantum Advice
Function inversion is the problem that given a random function $f: [M] \to [N]$, we want to find pre-image of any image $f^{-1}(y)$ in time $T$. In this work, we revisit this problem under the preprocessing model where we can compute some auxiliary information or advice of size $S$ that only depends...
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Main Authors | , , |
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Format | Journal Article |
Language | English |
Published |
20.11.2019
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Subjects | |
Online Access | Get full text |
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Summary: | Function inversion is the problem that given a random function $f: [M] \to
[N]$, we want to find pre-image of any image $f^{-1}(y)$ in time $T$. In this
work, we revisit this problem under the preprocessing model where we can
compute some auxiliary information or advice of size $S$ that only depends on
$f$ but not on $y$. It is a well-studied problem in the classical settings,
however, it is not clear how quantum algorithms can solve this task any better
besides invoking Grover's algorithm, which does not leverage the power of
preprocessing.
Nayebi et al. proved a lower bound $ST^2 \ge \tilde\Omega(N)$ for quantum
algorithms inverting permutations, however, they only consider algorithms with
classical advice. Hhan et al. subsequently extended this lower bound to fully
quantum algorithms for inverting permutations. In this work, we give the same
asymptotic lower bound to fully quantum algorithms for inverting functions for
fully quantum algorithms under the regime where $M = O(N)$.
In order to prove these bounds, we generalize the notion of quantum random
access code, originally introduced by Ambainis et al., to the setting where we
are given a list of (not necessarily independent) random variables, and we wish
to compress them into a variable-length encoding such that we can retrieve a
random element just using the encoding with high probability. As our main
technical contribution, we give a nearly tight lower bound (for a wide
parameter range) for this generalized notion of quantum random access codes,
which may be of independent interest. |
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DOI: | 10.48550/arxiv.1911.09176 |