Companion site for the textbook Quantum Computing: An Applied Approach

Quantum Computing Guide

Slide decks and Jupyter notebooks for training on Rigetti's quantum software stack at the Creative Destruction Lab 2018.

⚛️ 💥 ⚙️ A project based in Quantum Computing. This project was built using IBM Q Experience/QisKit (Jupyter Notebook/Python Environment Framework from IBM), PyQuil (Python Environment Framework from Rigetti Computing/Rigetti Forest SDK), ProjectQ (Python Environment Open-Source Framework from ETH Zurich), Q# (Q Sharp Programming Language from Microsoft Quantum SDK) and TeX (LaTeX). The project will present some kind of Introductory Course of Quantum Physics/Mechanics and Quantum Computing, and also, some basic tutorials, exercises and papers about it.

📚 A series of jupyter notebooks dedicated to introduction to Quantum Computing

In this work, we use LR-QAOA protocol as an easy-to-implement scalable benchmarking methodology that assesses quantum processing units (QPUs) at different widths (number of qubits) and 2-qubit gate depths.

⚛ Quantum Computing, for Humans.

Solutions for the Jupyter notebook exercises for the training on Rigetti's quantum software stack at the Creative Destruction Lab 2018.

QASM256: A groundbreaking quantum-classical hybrid programming language designed for AI, secure systems, and real-time optimization, pushing the boundaries of innovation across industries.

No description provided.

Open-source noise models for Rigetti quantum processors (Novera 9Q, Cepheus-1 36Q). Dual PyQuil/Qiskit implementations.

Quantum mechanical 8-sided dice

Hybrid quantum-classical solver for large-scale weighted Max-Cut using QAOA, quantum preconditioning, and classical refinement, with real hardware validation on Rigetti Ankaa-3.

Quantum Programming

Learning Forest Quantum