Related papers: Efficient explicit circuit for quantum state preparation of piece-wise continuous functions

Efficient explicit circuit for quantum state preparation of piece-wise continuous functions

URL: http://arxiv.org/abs/2411.01131v1
Date: Sat, 02 Nov 2024 04:20:31 GMT
Title: Efficient explicit circuit for quantum state preparation of piece-wise continuous functions
Authors: Nikita Guseynov, Nana Liu,
Abstract summary: We introduce an explicit algorithm for uploading functions using four real paritys that meet specific and boundedness conditions. Our method achieves efficient quantum circuit implementation and we present detailed gate counting and resource analysis.
Score: 0.6906005491572401
License:
Abstract: The ability to effectively upload data onto quantum states is an important task with broad applications in quantum computing. Numerous quantum algorithms heavily rely on the ability to efficiently upload information onto quantum states, without which those algorithms cannot achieve quantum advantage. In this paper, we address this challenge by proposing a method to upload a polynomial function $f(x)$ on the interval $x \in (a, b)$ onto a pure quantum state consisting of qubits, where a discretised $f(x)$ is the amplitude of this state. The preparation cost has quadratic scaling in the number of qubits $n$ and linear scaling with the degree of the polynomial $Q$. This efficiency allows the preparation of states whose amplitudes correspond to high-degree polynomials, enabling the approximation of almost any continuous function. We introduce an explicit algorithm for uploading such functions using four real polynomials that meet specific parity and boundedness conditions. We also generalize this approach to piece-wise polynomial functions, with the algorithm scaling linearly with the number of piecewise parts. Our method achieves efficient quantum circuit implementation and we present detailed gate counting and resource analysis.

Related papers

Parallel Quantum Computing Simulations via Quantum Accelerator Platform Virtualization [44.99833362998488]
We present a model for parallelizing simulation of quantum circuit executions. The model can take advantage of its backend-agnostic features, enabling parallel quantum circuit execution over any target backend.
arXiv Detail & Related papers (2024-06-05T17:16:07Z)
A quantum implementation of high-order power method for estimating geometric entanglement of pure states [39.58317527488534]
This work presents a quantum adaptation of the iterative higher-order power method for estimating the geometric measure of entanglement of multi-qubit pure states. It is executable on current (hybrid) quantum hardware and does not depend on quantum memory. We study the effect of noise on the algorithm using a simple theoretical model based on the standard depolarising channel.
arXiv Detail & Related papers (2024-05-29T14:40:24Z)
Calculating response functions of coupled oscillators using quantum phase estimation [40.31060267062305]
We study the problem of estimating frequency response functions of systems of coupled, classical harmonic oscillators using a quantum computer. Our proposed quantum algorithm operates in the standard $s-sparse, oracle-based query access model. We show that a simple adaptation of our algorithm solves the random glued-trees problem in time.
arXiv Detail & Related papers (2024-05-14T15:28:37Z)
Variational-quantum-eigensolver-inspired optimization for spin-chain work extraction [39.58317527488534]
Energy extraction from quantum sources is a key task to develop new quantum devices such as quantum batteries. One of the main issues to fully extract energy from the quantum source is the assumption that any unitary operation can be done on the system. We propose an approach to optimize the extractable energy inspired by the variational quantum eigensolver (VQE) algorithm.
arXiv Detail & Related papers (2023-10-11T15:59:54Z)
Non-Linear Transformations of Quantum Amplitudes: Exponential Improvement, Generalization, and Applications [0.0]
Quantum algorithms manipulate the amplitudes of quantum states to find solutions to computational problems. We present a framework for applying a general class of non-linear functions to the amplitudes of quantum states. Our work provides an important and efficient building block with potentially numerous applications in areas such as optimization, state preparation, quantum chemistry, and machine learning.
arXiv Detail & Related papers (2023-09-18T14:57:21Z)
Calculating the many-body density of states on a digital quantum computer [58.720142291102135]
We implement a quantum algorithm to perform an estimation of the density of states on a digital quantum computer. We use our algorithm to estimate the density of states of a non-integrable Hamiltonian on the Quantinuum H1-1 trapped ion chip for a controlled register of 18bits.
arXiv Detail & Related papers (2023-03-23T17:46:28Z)
Extracting a function encoded in amplitudes of a quantum state by tensor network and orthogonal function expansion [0.0]
We present a quantum circuit and its optimization procedure to obtain an approximating function of $f$ that has a number of degrees of freedom with respect to $d$. We also conducted a numerical experiment to approximate a finance-motivated function to demonstrate that our method works.
arXiv Detail & Related papers (2022-08-31T04:10:24Z)
Quantum State Preparation with Optimal Circuit Depth: Implementations and Applications [10.436969366019015]
We show that any $Theta(n)$-depth circuit can be prepared with a $Theta(log(nd)) with $O(ndlog d)$ ancillary qubits. We discuss applications of the results in different quantum computing tasks, such as Hamiltonian simulation, solving linear systems of equations, and realizing quantum random access memories.
arXiv Detail & Related papers (2022-01-27T13:16:30Z)
Quantum algorithms for approximate function loading [0.0]
We introduce two approximate quantum-state preparation methods for the NISQ era inspired by the Grover-Rudolph algorithm. A variational algorithm capable of loading functions beyond the aforementioned smoothness conditions is proposed.
arXiv Detail & Related papers (2021-11-15T17:36:13Z)
Efficient Quantum Circuits for Accurate State Preparation of Smooth, Differentiable Functions [0.8315657895474382]
We show that there exist families of quantum states that can be prepared to high precision with circuits of linear size and depth. We further develop an algorithm that requires only linear classical time to generate accurate linear-depth circuits.
arXiv Detail & Related papers (2020-05-09T02:31:44Z)
Quantum Gram-Schmidt Processes and Their Application to Efficient State Read-out for Quantum Algorithms [87.04438831673063]
We present an efficient read-out protocol that yields the classical vector form of the generated state. Our protocol suits the case that the output state lies in the row space of the input matrix. One of our technical tools is an efficient quantum algorithm for performing the Gram-Schmidt orthonormal procedure.
arXiv Detail & Related papers (2020-04-14T11:05:26Z)

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