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talks.html
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<!DOCTYPE html>
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<p class="tagline">
<b
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<a href="https://en.wikipedia.org/wiki/Unitarity_(physics)" target="_blank">unitary</a></b
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<p class="subtitle leading-arrow">Unitary Fund Community Calendar</p>
<p>
Want to keep up to date with all the cool stuff the Unitary Fund community is up to? Take a look at the
calendar below and add it to your favorite calendar app!
</p>
<div
class="ae-emd-cal"
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<p>
Interested in hosting a community call for your project on our Discord? Fill out the
<a href="https://airtable.com/shrWtBq9SQWwn4Rar">application form</a>, and we'll get back to you with
more details!
</p>
<p></p>
<p class="subtitle leading-arrow">Quantum Software Talks</p>
The Unitary Fund is pleased to host a online talk series that features open source quantum software
projects. All seminars will be hosted at
<a href="https://www.twitch.tv/unitaryfund">twitch.tv/unitaryfund</a>, and if you want to chat with the
speakers or the community more generally, check out the
<a href="https://discord.gg/JqVGmpkP96">Unitary Fund Discord</a>.
<p>
If you work on a open source quantum software and have a project you would like to speak about, please
<a href="mailto:[email protected]">drop us a line!</a>
</p>
<p class="subtitle leading-arrow">Upcoming talks</p>
<ul style="list-style-type: none"></ul>
<p class="subtitle leading-arrow">Previous talks</p>
<ul style="list-style-type: none">
<li class="leading-block">
<span class="blog-post-date"
>7 April, 2022 - 12pm EST/5pm GMT
<!-- <a title="Add to Calendar" class="addeventatc" data-id="jg13211859" href="https://www.addevent.com/event/jg13211859" target="_blank" rel="nofollow">Add to Calendar</a> -->
<script
type="text/javascript"
src="https://cdn.addevent.com/libs/atc/1.6.1/atc.min.js"
async
defer
></script>
</span>
<h4>
<a href="https://qutip.org/docs/latest/guide/guide-qip.html">qutip-qip</a>: Pulse-level circuits
simulation by Boxi Li
</h4>
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/-q5a38Pw7Rg"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<details>
<summary>About the talk</summary>
<p>
In quantum computing, a quantum circuit is often represented as a sequence of unitary gates.
However, when engineering quantum hardware, the physical qubits and their dynamics are usually
described by the Hamiltonians. The characterization of noise also varies in those two different
representations. Boxi will talk about quantum circuits represented by the control Hamiltonians and
introduce the qutip-qip package, which represents and simulates quantum circuits at the pulse
level. As a family package under the QuTiP organization, it leverages QuTiP's quantum dynamics
solvers to solve the continuous time evolution of the qubits with realistic physical models. The
package includes a few predefined physical models and provides the necessary compiling and
scheduling functionality. In addition, it allows the user to build custom models of physical
qubits and define various types of noise, such as environment-induced decoherence and noise in the
control pulses.
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
<strong>Boxi Li</strong>
is a PhD candidate at Forschungszentrum Jülich (Jülich research centre) in Germany, working on
quantum control and modelling for superconducting qubits. I did my Bachelors at the University of
Heidelberg and went to ETHZ for a master's degree, during which I also enjoyed a short stay at TU
Delft, exploring the magic of quantum networks. I started my contribution to QuTiP from a GSoC
project in 2019 and joined the development team thereafter, mainly maintaining the qutip-qip
repository.
</p>
</details>
<br />
</li>
<li class="leading-block">
<span class="blog-post-date">23 November, 2021 - 12pm EST/5pm GMT</span>
<h4>
<a href="https://github.com/pedrorrivero/qrand">qrand</a>: A multi-platform and multi-protocol
quantum random number generator for arbitrary probability distributions by Pedro Rivero
</h4>
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/srZddqGdVNE"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<details>
<summary>About the talk</summary>
<p>
Random numbers are everywhere. Computer algorithms, data encryption, physical simulations, and
even the arts use them all the time. There is one problem though: it turns out that they are
actually very difficult to produce in large amounts. Luckily, the probabilistic nature of quantum
computers makes these devices particularly useful for the task. QRAND introduces a versatile
interface layer between NumPy and several quantum computing platforms (qiskit, cirq, qsharp...),
along with some useful functionality that enables the production of quantum random numbers (QRN)
according to different quantum protocols, and for a wide variety of probability distributions.
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
<strong>Pedro Rivero</strong>
is an algorithm and quantum software developer at Argonne National Laboratory and is enrolled in a
a PhD course at the Illinois Institute of Technology.
</p>
</details>
</li>
<li class="leading-block">
<span class="blog-post-date">11 November, 2021 - 11:30 PST/19:30 GMT</span>
<h4>
<a href="http://www.pygsti.info/">pyGSTi</a>: A toolkit for quantum characterization by Erik Nielsen
and Kenneth Rudinger
</h4>
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/45YXL49MSx4"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<p>
<a href="https://zenodo.org/record/5715199"> Sample Jupyter notebooks from the talk</a>
</p>
<details>
<summary>About the talk</summary>
<p>
In this talk, we will present pyGSTi, a python package for generating and analyzing quantum
characterization, verification, and validation experiments, with particular focus on gate set
tomography and scalable forms of randomized benchmarking. pyGSTi has been used to characterize and
improve quantum hardware performance across a wide variety of platforms, including trapped ion,
superconducting transmon, and silicon spin qubit devices. We will discuss the motivation behind
pyGSTi, explore the functionality of and interplay between its basic objects, and provide several
demonstrations of the code in action. These demonstrations will span a variety of examples, from
high-level analyses which require minimal pyGSTi knowledge to more complex use cases which can
fully leverage pyGSTi’s broad capabilities.
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
Erik and Kenneth both are researchers and developers working on pyGSTi at Sandia National Labs.
</p>
</details>
</li>
<li class="leading-block">
<span class="blog-post-date">19 August, 2021 - 12pm EST/5pm GMT</span>
<h4>
Intro to
<a href="https://github.com/xvzcf/VeriFrodo">VeriFrodo</a>: The post-quantum cryptographic software
ecosystem by Goutam Tamvada
</h4>
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/rVMcplTyPpg"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<details>
<summary>About the talk</summary>
<p>
Verifrodo is an open-source package implementing a lattice-based quantum-resistant cryptographic
algorithms in Jasmin within the Open Quantum Safe project. This talk will provide an overview of
post-quantum cryptography and its use in internet protocols and software applications, as well as
place our Unitary Fund project, VeriFrodo, in this context.
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
<strong>Goutam Tamvada</strong>
has a Bachelor of Applied Science in Computer Engineering from the University of Waterloo, and has
been working on open source software for the Open Quantum Safe project for the past 2 years.
</p>
</details>
</li>
<li class="leading-block">
<span class="blog-post-date">20 May, 2021 - 12pm EST/5pm GMT</span>
<h4>
Intro to
<a href="https://github.com/pasqal-io/Pulser">Pulser</a>: Pulse simulation and design for neutral
atoms by Loïc Henriet
</h4>
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/Y4aM9G21tXk"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<br />
<details>
<summary>About the talk</summary>
<p>
The manipulation of neutral atoms by light is at the heart of countless scientific discoveries in
the field of quantum physics in the last three decades. The level of control that has been
achieved at the single particle level within arrays of optical traps, while preserving the
fundamental properties of quantum matter (coherence, entanglement, superposition), makes these
technologies prime candidates to implement disruptive computation paradigms. In this talk, I will
present
<a href="https://github.com/pasqal-io/Pulser">pulser</a>, a recently developed open-source python
framework enabling practitioners to control those devices at the pulse level.
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
<strong>Loïc Henriet</strong>
holds an engineering degree and a PhD in theoretical physics from Ecole Polytechnique, in France.
He subsequently worked as a researcher at the Institute for Photonic Sciences (ICFO) in Barcelona,
Spain. His research interests lied in the description of collective effects in light-matter
systems. In June 2019, he joined Pasqal, a Paris-based quantum computing startup manufacturing
quantum processors powered by arrays of single atoms. Since then, he has been heading the quantum
software developments.
</p>
</details>
</li>
<li class="leading-block">
<span class="blog-post-date">18 March, 2021 - 12pm EST/5pm GMT</span>
<h4>
Intro to
<a href="http://github.com/tqsd/QuNetSim">QuNetSim</a>: A Software Framework for Quantum Networks by
Stephen DiAdamo
</h4>
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/MmdRLYh1_mI"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<br />
<br />
<details>
<summary>About the talk</summary>
<p>
<a href="http://github.com/tqsd/QuNetSim">QuNetSim</a>
is a quantum-enabled network simulator that adds common quantum networking tasks like
teleportation, superdense coding, sharing EPR pairs, etc, to aid in the develop of quantum
networking protocols. With QuNetSim, one can design and test robust quantum network protocols
under various network conditions. In this presentation I will give an overview of what QuNetSim
does and demonstrate some examples of how it can be used.
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
<strong>Stephen DiAdamo</strong>
is an electrical engineering PhD student from TU Munich. After completing his bachelor's in
computer science from the University of Toronto, he moved to Munich, Germany to complete a
mathematics master's degree at TU Munich and continued after as a PhD student. His research
involves applications of entanglement in quantum networks as well as quantum simulation
development.
</p>
</details>
</li>
<li class="leading-block">
<span class="blog-post-date">28 January, 2021 - 12pm EST/5pm GMT</span>
<h4>
Intro to
<a href="http://qutip.org/">QuTiP</a>: A Quantum Toolbox in Python by Shahnawaz Ahmed
</h4>
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/2tF_4ZJAuYY"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<br />
<br />
<details>
<summary>About the talk</summary>
<p>
<a href="http://qutip.org/">QuTiP</a>: A quantum toolbox in Python, is one of the most popular
tools to simulate open quantum systems – but it has expanded beyond that over the years. It is a
simple but powerful library that, used by students, researchers, engineers, is having a tremendous
impact on quantum science research. QuTiP is also Unitary Fund’s first affiliated project. In this
talk, I will introduce the library and take the example of some new developments in QuTiP to show
the ease with which one can simulate open quantum systems as well as contribute to the development
of such open-source software tools to promote reproducibility and therefore accelerate the
adoption of a particular simulation technique across the research community.
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
<strong>Shahnawaz Ahmed</strong>
is a graduate student at the Wallenberg Center for Quantum Technology at Chalmers University,
Sweden. His research interest lies in the intersection of machine learning and quantum computing.
He also works on numerical approaches to solve problems in open quantum systems and is a member of
the QuTiP development team.
</p>
</details>
</li>
</ul>
<ul style="list-style-type: none">
<li class="leading-block">
<span class="blog-post-date">03 December, 2020 - 12pm EST/5pm GMT</span>
<h4>
Intro to
<a href="https://qcor.ornl.gov/">qcor</a>: Extending C++ for Heterogeneous Quantum-Classical
Computing by Alex McCaskey
</h4>
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/GzslhEnHUHI"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<br />
<br />
<details>
<summary>About the talk</summary>
<p>
We present
<strong><a href="https://qcor.ornl.gov/">qcor</a></strong>
- a language extension to C++ and compiler implementation that enables heterogeneous
quantum-classical programming, compilation, and execution in a single-source context. Our work
provides a first-of-its-kind C++ compiler enabling high-level quantum kernel (function) expression
in a quantum-language agnostic manner, as well as a hardware-agnostic, retargetable compiler
workflow targeting a number of physical and virtual quantum computing backends. qcor leverages
novel Clang plugin interfaces and builds upon the
<a href="https://github.com/eclipse/xacc"> XACC</a>
system-level quantum programming framework to provide a state-of-the-art integration mechanism for
quantum-classical compilation that leverages the best from the community at-large. qcor translates
quantum kernels ultimately to the XACC intermediate representation, and provides user-extensible
hooks for quantum compilation routines like circuit optimization, analysis, and placement. This
work details the overall architecture and compiler workflow for qcor, and provides a number of
illuminating programming examples demonstrating its utility for near-term variational tasks,
quantum algorithm expression, and feed-forward error correction schemes.
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
<strong>Alex McCaskey</strong>
is a research scientist in the Computer Science and Mathematics Division at Oak Ridge National
Laboratory. He serves as the Software Lead for the Quantum Computing Institute at ORNL and is the
Project Lead for the XACC quantum framework and the QCOR quantum-classical C++ compiler. He
received his Masters in Physics from Virginia Tech and BS degrees in Physics and Mathematics from
the University of Tennessee.
</p>
</details>
</li>
<li class="leading-block">
<span class="blog-post-date">12 November, 2020 - 12pm EST/5pm GMT</span>
<h4>
Intro to
<a href="https://github.com/vm6502q/qrack">qrack</a>: a framework for fast quantum simulation by
Daniel Strano
</h4>
<!-- <h4><a href="https://www.youtube.com/watch?v=yxyqJDC4SUo" >YouTube Recording</a></h4> -->
<iframe
class="video"
src="https://www.youtube-nocookie.com/embed/yxyqJDC4SUo"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
<br />
<br />
<details>
<summary>About the talk</summary>
<p>
<strong><a href="https://github.com/vm6502q/qrack">vm6502q/qrack</a></strong>
is a quantum computer simulation framework designed for the highest performance on the widest
possible range of consumer-grade "classical" hardware platforms. It has 0 required external
software dependencies besides C++11 standard, it optionally supports OpenCL accelerators back to
the v1.1 standard, including multi-accelerator operation, and it prides itself on its "novel
optimization layer." The speaker will outline the many features of the framework, including the
theory behind the novel optimization layer, culminating in a simulator stack whose general use
case is also its highest performance "Swiss Army knife" simulator, which has been integrated with
a much wider developing quantum open source stack via plugins. Quantitative benchmarks will also
be discussed, including performance on the quantum Fourier transform and an example of a "quantum
volume"-type random universal circuit. Check out the project
<a href="https://discordapp.com/invite/Gj3CHDy">Discord</a>
for more info!
</p>
</details>
<br />
<details>
<summary>About the speaker</summary>
<p>
<strong>Daniel Strano</strong>
is senior software developer for PDHI (Basking Ridge, NJ). He holds a B.A. in physics and has
worked as a data scientist or software engineer for companies including Pacific Northwest National
Laboratories (Richland, WA) and S&A Technologies, LLC (Newark, NJ). For the past three years, he
is the lead developer of the vm6502q/qrack quantum computing simulation framework, along with Benn
Bollay, which has received a Unitary Fund grant. His personal research and literary blog is at
ultraphrenia.com, including information and videos about his open source extensions to the
OpenRelativity physics module for Unity3D, by the MIT Game Lab, to which he is a community
contributor via a personal fork on GitHub.
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