Related papers: Absolute zeta functions for zeta functions of quantum cellular automata

Absolute zeta functions for zeta functions of quantum cellular automata

URL: http://arxiv.org/abs/2307.07106v2
Date: Wed, 17 Jan 2024 08:45:11 GMT
Title: Absolute zeta functions for zeta functions of quantum cellular automata
Authors: Jir\^o Akahori, Norio Konno, Iwao Sato
Abstract summary: We prove that a new zeta function given by QCA is an absolute automorphic form of weight depending on the size of the configuration space. As an example, we calculate an absolute zeta function for a tensor-type QCA, and show that it is expressed as the multiple gamma function.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Our previous work dealt with the zeta function for the interacting particle system (IPS) including quantum cellular automaton (QCA) as a typical model in the study of ``IPS/Zeta Correspondence". On the other hand, the absolute zeta function is a zeta function over F_1 defined by a function satisfying an absolute automorphy. This paper proves that a new zeta function given by QCA is an absolute automorphic form of weight depending on the size of the configuration space. As an example, we calculate an absolute zeta function for a tensor-type QCA, and show that it is expressed as the multiple gamma function. In addition, we obtain its functional equation by the multiple sine function.

Related papers

Absolute zeta functions and periodicity of quantum walks on cycles [0.0]
The study presents a connection between quantum walks and absolute zeta functions. The Hadamard walks and $3$-state Grover walks are typical models of the quantum walks. It is shown that our zeta functions of quantum walks are absolute automorphic forms.
arXiv Detail & Related papers (2024-05-09T06:30:00Z)
A quantization of interacting particle systems [0.0]
We regard the interacting particle system as a Markov chain on a graph. We calculate the absolute zeta function of the quantized model for the Domany-Kinzel model.
arXiv Detail & Related papers (2024-02-01T02:13:47Z)
Denoising and Extension of Response Functions in the Time Domain [48.52478746418526]
Response functions of quantum systems describe the response of a system to an external perturbation. In equilibrium and steady-state systems, they correspond to a positive spectral function in the frequency domain.
arXiv Detail & Related papers (2023-09-05T20:26:03Z)
Quantum Entanglement & Purity Testing: A Graph Zeta Function Perspective [0.0]
We show that a recently developed pure state separability algorithm based on the symmetric group is equivalent to the condition that the coefficients in the exponential expansion of this zeta function are unity. There is a one-to-one correspondence between the nonzero eigenvalues of a density matrix and the singularities of its zeta function.
arXiv Detail & Related papers (2023-07-06T22:25:11Z)
On the relation between quantum walks and absolute zeta functions [0.0]
We deal with a zeta function determined by a time evolution matrix of the Grover walk on a graph. We prove that the zeta function given by the quantum walk is an absolute automorphic form of weight depending on the number of edges of the graph. We consider an absolute zeta function for the zeta function based on a quantum walk.
arXiv Detail & Related papers (2023-06-26T11:58:07Z)
A linear response framework for simulating bosonic and fermionic correlation functions illustrated on quantum computers [58.720142291102135]
Lehmann formalism for obtaining response functions in linear response has no direct link to experiment. Within the context of quantum computing, we make the experiment an inextricable part of the quantum simulation. We show that both bosonic and fermionic Green's functions can be obtained, and apply these ideas to the study of a charge-density-wave material.
arXiv Detail & Related papers (2023-02-20T19:01:02Z)
Special functions in quantum phase estimation [61.12008553173672]
We focus on two special functions. One is prolate spheroidal wave function, which approximately gives the maximum probability that the difference between the true parameter and the estimate is smaller than a certain threshold. The other is Mathieu function, which exactly gives the optimum estimation under the energy constraint.
arXiv Detail & Related papers (2023-02-14T08:33:24Z)
Neural Estimation of Submodular Functions with Applications to Differentiable Subset Selection [50.14730810124592]
Submodular functions and variants, through their ability to characterize diversity and coverage, have emerged as a key tool for data selection and summarization. We propose FLEXSUBNET, a family of flexible neural models for both monotone and non-monotone submodular functions.
arXiv Detail & Related papers (2022-10-20T06:00:45Z)
Learning PSD-valued functions using kernel sums-of-squares [94.96262888797257]
We introduce a kernel sum-of-squares model for functions that take values in the PSD cone. We show that it constitutes a universal approximator of PSD functions, and derive eigenvalue bounds in the case of subsampled equality constraints. We then apply our results to modeling convex functions, by enforcing a kernel sum-of-squares representation of their Hessian.
arXiv Detail & Related papers (2021-11-22T16:07:50Z)
IPS/Zeta Correspondence [0.0]
This paper introduces a new zeta function for multi-particle models with probabilistic or quantum interactions, called the interacting particle system (IPS) We compute the zeta function for some tensor-type IPSs.
arXiv Detail & Related papers (2021-05-10T00:36:21Z)
Automated and Sound Synthesis of Lyapunov Functions with SMT Solvers [70.70479436076238]
We synthesise Lyapunov functions for linear, non-linear (polynomial) and parametric models. We exploit an inductive framework to synthesise Lyapunov functions, starting from parametric templates.
arXiv Detail & Related papers (2020-07-21T14:45:23Z)

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