Waldemir Cambiucci

Waldemir Cambiucci
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  • PhD
  • PhD Candidate at University of São Paulo

PhD candidate in quantum computing, with focus on distributed quantum computing and quantum circuits partitioning.

About

10
Publications
285
Reads
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15
Citations
Introduction
In the context of NISQ computers - Noise Intermediate Scale Quantum, it is a consensus that the distribution of circuits among processing agents is a viable approach to get greater scalability with small machines. This approach can increase the combined computational power at the cost of dedicating qubits to get the communication between partitions. In this context, my research aims to reduce the communication cost of qubits generated during the physical partitioning of quantum circuits.
Skills and Expertise
Quantum Algorithms
Quantum Computing
Quantum Communication
Quantum Information Theory
Current institution
University of São Paulo
University of São Paulo
  • Departamento de Engenharia de Computação e Sistemas Digitais (PCS) (POLI)
  • São Paulo, Brazil
Current position
  • PhD Candidate
LARC - Laboratório de Arquitetura e Redes de Computadores

Publications

Publications (10)
Figure 3. Static circuit for example illustration.
Figure 7. Total quantum gates vs. Number of qubits for adaptive and...
Hypergraphic representation for adaptive quantum circuits
Preprint
Full-text available
  • Apr 2025
Adaptive quantum circuits enhance flexibility and efficiency over traditional static circuits by dynamically adjusting their structure and parameters in real-time based on intermediate measurement outcomes. This paper introduces a novel hypergraph representation for adaptive quantum circuits, where groups of gates are considered as participants of...
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Figure 4. Quantum circuit (a) and primary hypergraphic representation...
Figure 7. Transformation of primal hypergraph H (a) into its equivalent...
Figure 8. Dual hypergraphic partitioning using Fiduccia-Mattheyses In...
Figure 9. The temporal approach was applied to the quantum circuit,...
+4 Figure 10. Quantum circuit example with binary ('cx') and ternary...
Spatial and temporal circuit cutting with hypergraphic partitioning
Preprint
Full-text available
  • Apr 2025
Quantum computing promises to revolutionize problem-solving through quantum mechanics, but current NISQ devices face limitations in qubit count and error rates, hindering the execution of large-scale quantum circuits. To address these challenges and improve scalability, two main circuit cutting strategies have emerged: the gate-cut approach, which...
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Figura 2. Representação hipergráfica de circuitos quânticos e possíveis...
Arquitetura para sistema de computação quântica distribuída multi-QPU com particionamento de circuitos
Conference Paper
Full-text available
  • May 2024
É consenso que a distribuição de circuitos quânticos entre agentes de processamento é uma abordagem viável para se obter maior escalabilidade com as tecnologias de hardware atuais, de dispositivos ruidosos de escala intermediária. Assim, novas arquitetura de computadores quânticos com múltiplas unidades de processamento devem considerar etapas adic...
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Figure 2 -Dedicated qubits for communication between QPUs, an expensive...
Figure 3 -Distributed quantum computer architecture. Source: elaborated...
Figure 4 -Shows quantum teleportation consuming communication qubits,...
Hypergraphic partitioning of quantum circuits for distributed quantum computing
Preprint
Full-text available
  • Jan 2023
In the context of NISQ computers - Noise Intermediate Scale Quantum, it is a consensus that the distribution of circuits among processing agents is a viable approach to get greater scalability with small machines. This approach can increase the combined computational power at the cost of dedicating qubits to get the communication between partitions...
View
FIGURA 2.2.1 -Monitor transacional e classes de servidores.
Monitores transacionais : construção de um servidor Web com enfoque transacional.
Article
Full-text available
Cliente/Servidor é um dos termos mais usados na área de engenharia de computação no momento e pode ser sucintamente definido como um sistema de computação que utiliza três componentes básicos para o compartilhamento de recursos: um computador-cliente, um computador-servidor e uma rede para conectá-los. Este tipo de arquitetura ainda apresenta diver...
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