degree in Electrical Engineering from IIT Kanpur, India, in 2002, and the S.M. Prior to joining the University of Arizona, he was a Lead Scientist with the Quantum Information Processing group at Raytheon BBN Technologies, Cambridge, MA, where he worked from 2008 to 2017. He is the Director of the National Science Foundation ERC, Center for Quantum Networks. Saikat Guha is a Professor at the College of Optical Sciences, jointly appointed with the ECE Department at The University of Arizona, Tucson. I will also mention how CQN engages disciplines such as law and policy, social and behavioral sciences and economics through a research thrust focusing on societal impacts of the quantum internet. CQN is a highly interdisciplinary effort with research ranging material-science theory to design high-coherence time quantum memories, quantum memory design and fabrication, building efficient interfaces between matter and photon qubits, cryogenic compatible packaging capabilities, quantum error correction theory to design codes for quantum communication and entanglement distillation, repeater architecture design and analysis, the entire network protocol stack up to the application layer, and finally network control, tomography and management protocols. In this lecture, I will describe the underlying theory of quantum networking and quantum repeaters, allude to a few important applications, and give a glimpse of a large effort underway as part of an NSF-funded 10-year engineering research center called the Center for Quantum Networks (CQN). Supporting long-distance quantum communications at high rates and fidelities will require scalable quantum repeaters and quantum-capable satellites for continental-scale quantum connectivity. Just like the internet's classical data communications service, the quantum communications service must reliably support many simultaneous user groups, and support diverse and dynamic applications-each with its unique requirements on the quality of service for transmission of qubits, e.g., rate, latency, fidelity etc. Many organized efforts across the world are racing to realize the "Quantum Internet" - the internet of the future that has been upgraded to provide an additional service: that of reliably transmitting qubits between distant users. (You must have a current Columbia ID card and a green pass to attend in person) Want to learn more about processing information by harnessing and using the laws of quantum mechanics? Check out the Quantum computing hub on IBM Developer.Davis Auditorium OR Live stream - REGISTER HERE In this demo, you will see how you can use OpenShift to build an application that accesses the IBM Quantum service using Qiskit and Jupyter Notebooks. Demonstration of program integration with Qiskit and quantum See what exactly the Red Hat OpenShift Qiskit Operator is and how it can be integrated with a Jupyter Notebook for running quantum circuits using Qiskit. Setting up the connection from OpenShift to the IBM Q resources #Quantum event recorder software#Understand the software stack behind the IBM Quantum API and the class of hard problems that quantum has the opportunity to solve. In this session, learn how quantum is at the core of the future of computing, how you can access quantum acceleration on the cloud through an open source co-processor model, and the quantum computing packages available for OpenShift and IBM Quantum. Introduction to using OpenShift and Qiskit We then review basic quantum theory and how it applies in quantum circuits and current quantum devices. The Qiskit operator launches an integrated Jupyter Notebook with Qiskit and all the necessary Python packages for visualizing the results. First, we use the Qiskit operator to quickly create a development environment for implementing quantum circuits. By Yin Chen, Travis Jeanneret, Kelvin LuiĮxplore the steps required to enable quantum computing workflows on a Kubernetes cluster using the IBM Quantum system as a back end.
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