A quantum Z-transform
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BRAC University
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Abstract
We investigate a quantum analog of the classical Z-transform with the aim of making
it implementable on quantum computers, potentially offering a speedup over
the classical method. Unlike the discrete Fourier transform, which is limited to
frequency analysis, the Z-transform allows for versatile exploration of properties
within the complex plane. Since the quantum Fourier transform underpins Shor’s
factoring algorithm and serves as a subroutine in many other quantum algorithms, a
quantum Z-transform promises broad applicability in quantum simulation, quantum
machine learning, and quantum signal processing. This is especially relevant because
Z-transforms generalize Fourier transforms in certain aspects. Given that quantum
computers are particularly adept at performing unitary operations, we discretize
the classical definition of the Z-transform and unitarize its matrix formulation to
make it amenable for quantum computation. Our approach involves introducing
a discrete Z-transform, mapping the input sequence to a discrete set of values to
represent them as quantum states, and redefining the Z-transform as a finite summation
to effectively handle the infinite summation of the classical definition. We
then develop a matrix formulation for our redefined discrete Z-transform and extend
our approach by unitarizing this matrix formulation through block-encoding,
constructing unitary operators that meet the criteria for efficient quantum operations
using standard quantum gates and subroutines. Our approach establishes the
groundwork by fulfilling the mathematical foundations for the potential discovery of
a quantum Z-transform and opens avenues for further exploration and implementation
in quantum computing.
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Description
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 62-65).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2019.
Includes bibliographical references (pages 62-65).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2019.
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Thesis