about-mathematicians.md

layout	title
slides	OpenDreamKit: the mathematician's perspective

# OpenDreamKit

The mathematician's perspective

---

Some fundamental trends

Long standing and booming role of computers in pure mathematics

• Computer exploration
• Conjecture verification
• Mechanized proofs
• Proof assistants and certified proofs
• Collaborative work
• Education

--

Open Science getting momentum

Open science is the movement to make scientific research, data and dissemination accessible to all levels of an inquiring society, amateur or professional

• Open Knowledge (Access, Educational Ressources)
• Open Source or better Free Software
• Open Data
• Open Peer Review, Methodology, ...

At the core of science for centuries. Finally getting recognition as viable and necessary, even by funding agencies!

--

Emergence of a vibrant ecosystem of free software for pure mathematics

• Specialized libraries: LinBox, PARI/GP, MPIR, Singular, ...

• General purpose systems: GAP, SageMath, ...

• Online databases: OEIS, LMFDB, ...

• Interactive computing environments:
  IPython/Jupyter, SageMathCloud, ...

• Together with the wider Scientific Python ecosystem

Viable alternatives to Maple, Mathematica, Matlab, ...

For research and education (and the industry?)

---

Virtual Research Environments (VRE)?

Definition from the call of the H2020 European Research Infrastructures Work Programme:

Groups of researchers, typically widely dispersed who are working together through ubiquitous, trusted and easy access to services for scientific data, computing, and networking, in a collaborative virtual environment

--

VRE for mathematics?

Mathematicians are already immersed in a multitude of virtual environments to collaborate on

• Software

• Data

• Knowledge

--

---

The next frontier?

• Improve the productivity of researchers in pure mathematics and applications by further promoting collaborations on Data, Knowledge, and Software

• Make it easy for teams of researchers of any size to set up custom, collaborative Virtual Research Environments tailored to their specific needs, resources and workflows

• Support the entire life-cycle of computational work in mathematical research, from initial exploration to publication, teaching, and outreach

--

A tension:

• Mathematicicans want a seamless user experience while interacting with mathematics

• Implementing a one-size-fits-all VRE is intractable

---

An approach

Building a math VRE toolkit based on:

• The ecosystem of open source math software

• Open collaborative tools and models

Architecture:

• Collaborative workspaces (e.g. JupyterHub, SageMathCloud)
• User interfaces (e.g Jupyter notebook)
• Computational components (e.g. Linbox, PARI/GP, GAP, Sage, Singular, ...)
• Data / knowledge bases (e.g. OEIS)
• Physical resources (e.g. cloud infrastructure)

--

Added values

• Customizability for a variety of use cases:

  • A single person installation on a laptop
  • A collaborative VRE between three researchers, running on their lab's server
  • A university wide VRE for teaching
  • Service provided by a european grid infrastructure

• Joining forces with the wider scientific computing community

• Lowering the software barrier between pure and applied maths

• Modularity, sustainability

---

How to get there?

--

Component architecture (WP3)

• Goal: ease of deployment. Requires:

  • Modularity, packaging, portability, distribution
  • For individual components and combinations thereof

• Development workflows in ecosystems of software

--

User interfaces (WP4)

• Jupyter as uniform notebook interface

• Improving Jupyter (collaboration, 3D, ...)

• Coordination SageMathCloud / JupyterHub

• Collaborative, reproducible, active documents

--

Performance (WP5)

• Goal: Make the most of available hardware

  • multicore
  • HPC
  • cloud

• For individual computational components and combinations thereof

--

Data/Knowledge/Software (WP6)

• Goal: enable rich and robust interaction between

  • computational components
  • data bases
  • knowledge bases
  • users

• This requires:

  • explicit common semantic spaces
  • a language to express them
  • tools to leverage them

--

Community building and dissemination (WP2)

• Developer Workshops

• Training workshops

• Conferences

--

Social aspects (WP7)

• Analysis of user needs

• Research on collaborative software development in mathematics

---

OpenDreamKit (2015-2019)

Open Digital Research Environment Toolkit for the Advancement of Mathematics

OpenDreamKit.org

• H2020 European Research Infrastructures Work Programme

  Call: Virtual Research Environments

• Budget: 7.6M€

• 15 sites, 50 participants

  In close collaboration with the international community!

--

A user-driven consortium

European power users and core developers of the ecosystem of open source software for Mathematics:

• GAP (St Andrews, Oxford)
• Linbox (Grenoble)
• PARI/GP (Bordeaux, Versailles)
• Sage (Bordeaux, Grenoble, Paris Sud, Oxford, Versailles)
• Singular (Kaiserslautern)
• LMFDB (Warwick, Zürich)
• MathHub, MMT/OpenMath (Bremen)
• Jupyter (Simula)
• Scientific Python (SouthHampton, Sheffield, Silesia)

-- Supported by:

• Research engineers
• An open source based company (Logilab)

---

How are we doing?

--

The bad news

• Some tasks harder than expected

• We expected recruitment to be hard. It really was.

• We exected the admistrative overhead to be high. It really is.

--

The good news

• Intensive work started on all fronts

  • Current deliverables not representative

• Some really good recruitement

• Joint workshops are very effective

• Interesting technology raising

  • Windows support for Linux apps

--

Ways to improve?

• There could be more interactions in certain areas

• Some workpackages could benefit from more animation

• More workshops / joint visits / online meetings?

---

More reading

• The developer's perspective on OpenDreamKit

• About OpenDreamKit

• The OpenDreamKit proposal