Related papers: Pauli-based model of quantum computation with higher-dimensional systems

Pauli-based model of quantum computation with higher-dimensional systems

URL: http://arxiv.org/abs/2302.13702v2
Date: Thu, 14 Sep 2023 08:34:06 GMT
Title: Pauli-based model of quantum computation with higher-dimensional systems
Authors: Filipa C. R. Peres
Abstract summary: Pauli-based computation (PBC) is a universal model for quantum computation with qubits. We generalize PBC for odd-prime-dimensional systems and demonstrate its universality.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Pauli-based computation (PBC) is a universal model for quantum computation with qubits where the input state is a magic (resource) state and the computation is driven by a sequence of adaptively chosen and compatible multiqubit Pauli measurements. Here we generalize PBC for odd-prime-dimensional systems and demonstrate its universality. Additionally, we discuss how any qudit-based PBC can be implemented on actual, circuit-based quantum hardware. Our results show that we can translate a PBC on $n$ $p$-dimensional qudits to adaptive circuits on $n+1$ qudits with $O\left( pn^2/2 \right)$ $\mathrm{SUM}$ gates and depth. Alternatively, we can carry out the same computation with $O\left( pn/2\right)$ depth at the expense of an increased circuit width. Finally, we show that the sampling complexity associated with simulating a number $k$ of virtual qudits is related to the robustness of magic of the input states. Computation of this magic monotone for qutrit and ququint states leads to sampling complexity upper bounds of, respectively, $O\left( 3^{ 1.0848 k} \epsilon^{-2}\right)$ and $O\left( 5^{ 1.4022 k} \epsilon^{-2}\right)$, for a desired precision $\epsilon$. We further establish lower bounds to this sampling complexity for qubits, qutrits, and ququints: $\Omega \left( 2^{0.5431 k} \epsilon^{-2} \right)$, $\Omega \left( 3^{0.7236 k} \epsilon^{-2} \right)$, and $\Omega \left( 5^{0.8544 k} \epsilon^{-2} \right)$, respectively.

Related papers

Measuring quantum relative entropy with finite-size effect [53.64687146666141]
We study the estimation of relative entropy $D(rho|sigma)$ when $sigma$ is known. Our estimator attains the Cram'er-Rao type bound when the dimension $d$ is fixed.
arXiv Detail & Related papers (2024-06-25T06:07:20Z)
Incompressibility and spectral gaps of random circuits [2.359282907257055]
reversible and quantum circuits form random walks on the alternating group $mathrmAlt (2n)$ and unitary group $mathrmSU (2n)$, respectively. We prove that the gap for random reversible circuits is $Omega(n-3)$ for all $tgeq 1$, and the gap for random quantum circuits is $Omega(n-3)$ for $t leq Theta(2n/2)$.
arXiv Detail & Related papers (2024-06-11T17:23:16Z)
On the average-case complexity of learning output distributions of quantum circuits [55.37943886895049]
We show that learning the output distributions of brickwork random quantum circuits is average-case hard in the statistical query model. This learning model is widely used as an abstract computational model for most generic learning algorithms.
arXiv Detail & Related papers (2023-05-09T20:53:27Z)
Exponential Separation between Quantum and Classical Ordered Binary Decision Diagrams, Reordering Method and Hierarchies [68.93512627479197]
We study quantum Ordered Binary Decision Diagrams($OBDD$) model. We prove lower bounds and upper bounds for OBDD with arbitrary order of input variables. We extend hierarchy for read$k$-times Ordered Binary Decision Diagrams ($k$-OBDD$) of width.
arXiv Detail & Related papers (2022-04-22T12:37:56Z)
A Law of Robustness beyond Isoperimetry [84.33752026418045]
We prove a Lipschitzness lower bound $Omega(sqrtn/p)$ of robustness of interpolating neural network parameters on arbitrary distributions. We then show the potential benefit of overparametrization for smooth data when $n=mathrmpoly(d)$. We disprove the potential existence of an $O(1)$-Lipschitz robust interpolating function when $n=exp(omega(d))$.
arXiv Detail & Related papers (2022-02-23T16:10:23Z)
Optimal (controlled) quantum state preparation and improved unitary synthesis by quantum circuits with any number of ancillary qubits [20.270300647783003]
Controlled quantum state preparation (CQSP) aims to provide the transformation of $|irangle |0nrangle to |irangle |psi_irangle $ for all $iin 0,1k$ for the given $n$-qubit states. We construct a quantum circuit for implementing CQSP, with depth $Oleft(n+k+frac2n+kn+k+mright)$ and size $Oleft(2n+kright)$
arXiv Detail & Related papers (2022-02-23T04:19:57Z)
On quantum algorithms for the Schr\"odinger equation in the semi-classical regime [27.175719898694073]
We consider Schr"odinger's equation in the semi-classical regime. Such a Schr"odinger equation finds many applications, including in Born-Oppenheimer molecular dynamics and Ehrenfest dynamics.
arXiv Detail & Related papers (2021-12-25T20:01:54Z)
Asymptotically Optimal Circuit Depth for Quantum State Preparation and General Unitary Synthesis [24.555887999356646]
The problem is of fundamental importance in quantum algorithm design, Hamiltonian simulation and quantum machine learning, yet its circuit depth and size complexity remain open when ancillary qubits are available. In this paper, we study efficient constructions of quantum circuits with $m$ ancillary qubits that can prepare $psi_vrangle$ in depth. Our circuits are deterministic, prepare the state and carry out the unitary precisely, utilize the ancillary qubits tightly and the depths are optimal in a wide range of parameter regime.
arXiv Detail & Related papers (2021-08-13T09:47:11Z)
Quantum supremacy and hardness of estimating output probabilities of quantum circuits [0.0]
We prove under the theoretical complexity of the non-concentration hierarchy that approximating the output probabilities to within $2-Omega(nlogn)$ is hard. We show that the hardness results extend to any open neighborhood of an arbitrary (fixed) circuit including trivial circuit with identity gates.
arXiv Detail & Related papers (2021-02-03T09:20:32Z)
An Optimal Separation of Randomized and Quantum Query Complexity [67.19751155411075]
We prove that for every decision tree, the absolute values of the Fourier coefficients of a given order $ellsqrtbinomdell (1+log n)ell-1,$ sum to at most $cellsqrtbinomdell (1+log n)ell-1,$ where $n$ is the number of variables, $d$ is the tree depth, and $c>0$ is an absolute constant.
arXiv Detail & Related papers (2020-08-24T06:50:57Z)
Fixed-Support Wasserstein Barycenters: Computational Hardness and Fast Algorithm [100.11971836788437]
We study the fixed-support Wasserstein barycenter problem (FS-WBP) We develop a provably fast textitdeterministic variant of the celebrated iterative Bregman projection (IBP) algorithm, named textscFastIBP.
arXiv Detail & Related papers (2020-02-12T03:40:52Z)

This list is automatically generated from the titles and abstracts of the papers in this site.