Events

May 28, 2019

The Complexity of Sampling from a Weak Quantum Computer

Saeed Mehraban

MIT CSAIL

10:00A

- 11:00A

Location

32-G575

Add to Calendar 2019-05-28 10:00:00 2019-05-28 11:00:00 America/New_York The Complexity of Sampling from a Weak Quantum Computer Abstract: This is an exciting time for quantum computing. Over the next few years, intermediate-scale quantum computers with ~50-100 qubits are expected to become practical. These computers are too small to do error correction and they may not even capture the full power of a universal quantum computer. A major theoretical challenge is to understand the capabilities and limitations of these devices. In order to approach this challenge, quantum supremacy experiments have been proposed as a near-term milestone. The objective of quantum supremacy is to find computational problems that are feasible on a small-scale quantum computer but are hard to simulate classically. Even though a quantum supremacy experiment may not have practical applications, achieving it will demonstrate that quantum computers can outperform classical ones on, at least, artificially designed computational problems. Among other proposals, over the recent years, two sampling based quantum supremacy experiments have been proposed:(1) The first one is based on sampling from the output of a random circuit applied to a square grid of qubits. The Google quantum AI group is planning to implement this task on a processor composed of a few (~50-100) superconducting qubits. In order to argue that this sampling task is hard, building on previous works of Aaronson, Arkhipov, and others, they conjectured that the output distribution of a low-depth (scaling asymptotically as the square root of the number of qubits) circuit is anti-concentrated meaning that it has nearly maximal entropy. This is known as the “anti-concentration” conjecture.(2) The second proposal, known as Boson Sampling (Aaronson Arkhipov ’10), is based on linear optical experiments. A baseline conjecture of Boson Sampling is that it is #P-hard to approximate the permanent of a Gaussian matrix with zero mean and unit variance with high probability. This is known as the permanent of Gaussians conjecture.The first part of this thesis proves the anti-concentration conjecture for random quantum circuits. The proof is an immediate consequence of our main result which settles a conjecture of Brandão-Harrow-Horodecki ’12 that short-depth random circuits are pseudo-random. These pseudo-random quantum processes have many applications in algorithms, communication, cryptography as well as theoretical physics e.g. the so-called black hole information problem. This result is based on joint work with Aram Harrow (QIP 2018).The second part of this thesis makes progress towards the permanent of Gaussians conjecture and shows that the permanent of Gaussian matrices can indeed be approximated in quasi-polynomial time with high probability if instead of zero mean one considers a nonzero but vanishing mean (~1/polyloglog in the size of the matrix). This result finds, to the best of our knowledge, the first example of a natural counting problem that is #P-hard to compute exactly on average and #P-hard to approximate in the worst case but becomes easy only when approximation and average case are combined. This result is based on joint work with Lior Eldar (FOCS 2018).Thesis Committee: Scott Aaronson, Ryan Williams, Aram Harrow. 32-G575 Belfer sarah_donahue@hks.harvard.edu

TEDxMIT

1:00P

- 6:00P

Location

Kirsch 32-123

Add to Calendar 2019-05-28 13:00:00 2019-05-28 18:00:00 America/New_York TEDxMIT TEDxMIT events will feature talks about important and impactful ideas by members of the broader MIT community.Join us for the inaugural TEDxMIT event at CSAIL between 1pm - 6pm on Tuesday, May 28, 2019 in the Stata Center, 32 Vassar Street, Cambridge, MA. This event is organized by Daniela Rus and John Werner, in collaboration with a team of undergraduate students led by Stephanie Fu and Rucha Keklar. Please register at https://tedxmit.org/ Registration is limited and will be allocated on a first come, first served basis. The Inaugural TEDxMIT event will include talks by amazing women technologists from MIT: Barbara Liskov, Dava Neuman, Hamsa Balakrishnan, Judy Brewer, Julie Shah, Krystyn Van Vliet, Nergis Mavalvala, Ronitt Rubinfeld, Vivienne Sze, and Hane Lee. At the end of the event there will be a reception. Agenda and more details are available at https://tedxmit.org/ Belfer sarah_donahue@hks.harvard.edu

May 29, 2019

Tensor Programs: A Swiss-Army Knife for Nonlinear Random Matrix Theory of Deep Learning and Beyond

Greg Yang

Microsoft Research

4:00P

- 5:00P

Location

32-G575

Add to Calendar 2019-05-29 16:00:00 2019-05-29 17:00:00 America/New_York Tensor Programs: A Swiss-Army Knife for Nonlinear Random Matrix Theory of Deep Learning and Beyond Abstract: The resurgence of neural networks has revolutionized artificial intelligence since 2010. Luckily for mathematicians and statistical physicists, the study of large random network scaling limits, which can be thought of as *nonlinear* random matrix theory, is both practically important and mathematically interesting. We describe several problems in this setting and develop a new comprehensive framework, called “tensorprograms,” for solving these problems. This framework can be thought of as an automatic tool to derive the behavior of computation graphs with large matrices, as used in neural network computation. It is very general, and from it we also obtain new proofs of the semicircle and the Marchenko-Pastur laws. Thus, “tensor programs” is broadly useful to linearand nonlinear random matrix theory alike, and we hope it will be adopted as a standard tool.This talk presents the work arXiv:1902.04760. 32-G575 Belfer sarah_donahue@hks.harvard.edu

May 31, 2019

Nadia Heninger: Lattice Attacks against Weak ECDSA Signatures in Cryptocurrencies

Nadia Heninger

10:30A

- 12:00P

Location

Hewlett, G882

Add to Calendar 2019-05-31 10:30:00 2019-05-31 12:00:00 America/New_York Nadia Heninger: Lattice Attacks against Weak ECDSA Signatures in Cryptocurrencies AbstractWe compute hundreds of Bitcoin private keys and dozens of Ethereum, Ripple, SSH, and HTTPS private keys by carrying out cryptanalytic attacks against digital signatures contained in public blockchains and Internet-wide scans. The ECDSA signature algorithm requires the generation of a per-message secret nonce. This nonce must be generated perfectly uniformly, or else an attacker can exploit the nonce biases to compute the long-term signing key. We use a lattice-based algorithm for solving the hidden number problem to efficiently compute private ECDSA keys that were used with biased signature nonces due to multiple apparent implementation vulnerabilities. Hewlett, G882 Belfer sarah_donahue@hks.harvard.edu

Towards a general-purpose homomorphically encrypted microprocessor

Michail (Mihalis) Maniatakos

New York University (NYU) Abu Dhabi

1:00P

- 2:00P

Location

32-G825

Add to Calendar 2019-05-31 13:00:00 2019-05-31 14:00:00 America/New_York Towards a general-purpose homomorphically encrypted microprocessor Abstract: Following Spectre and Meltdown joint announcement in 2018, the security world was holding its breath for the revelation of the new heir to the microarchitectural attacks throne. No one was prepared, however, for the birth of triplets: Fallout, RIDL, and ZombieLoad. The triplets serve as a painful reminder that all these years of performance gains through microarchitectural improvements were not exactly “free lunch”. Evidently, end-points cannot be trusted; as long as data gets decrypted to be processed in the CPU pipeline, it can leak. While cryptography has been successfully used to solve data-in-transit (e.g., HTTPS) and data-at-rest (e.g., AES encrypted hard disks) concerns, data-in-use protection in regular CPUs remains unsolved. Fully homomorphic encryption has emerged as a prominent solution, but its performance and applicability render it unsuitable for an across the board solution. In this talk, we will present the major challenges towards developing a homomorphically encrypted processor, starting from the development of a minimal abstract machine that can compute on encrypted data, to an ASIC implementation of partially homomorphic encrypted microprocessor and the introduction of a framework for compiling C++ programs to their homomorphically encrypted counterparts.Short bio: Michail (Mihalis) Maniatakos is an Assistant Professor of Electrical and Computer Engineering at New York University (NYU) Abu Dhabi. He is the Director of the MoMA Laboratory (nyuad.nyu.edu/momalab). He received his Ph.D. in Electrical Engineering from Yale University. His research interests include encrypted data computation and industrial control systems security, and has been funded by various industry partners, DARPA, and ONR. 32-G825 Belfer sarah_donahue@hks.harvard.edu

June 03, 2019

Mercedes-Benz Tech Talk: Visions and Methods for Human-Machine-Interaction

Zachary Butko , AI Project Manager at Mercedes-Benz Research & Development North America

Daimler Mercedes-Benz Research & Development

3:00P

- 4:00P

Location

Hewlett Seminar Room @CSAIL (32-G882)

Add to Calendar 2019-06-03 15:00:00 2019-06-03 16:00:00 America/New_York Mercedes-Benz Tech Talk: Visions and Methods for Human-Machine-Interaction Abstract:The advances in technology and artificial intelligence lead to more sophisticated system functionalities and automation. The more complex these functionalities may become, the more emphasis has to be placed on intelligible systems and understandable user interactions. In this talk, we share the vision of “Shaper Autonomy” that enables a new active role for humans and turns robot cars into personalized robot cars. We also discuss how explanations support AI-driven systems, e.g., for transparency of machine learning model predictions.Presenters:Zachary Butko is an AI Project Manager at Mercedes-Benz Research & Development North America, Inc, Sunnyvale, CA, USA.Kai Jardner is a Futurist at Daimler AG, Sindelfingen, Germany. Belfer sarah_donahue@hks.harvard.edu

June 07, 2019

CSAIL Commencement Reception

1:30P

- 3:00P

Location

R&D Commons

G401

Add to Calendar 2019-06-07 13:30:00 2019-06-07 15:00:00 America/New_York CSAIL Commencement Reception Congratulations CSAIL graduates! Please join us for some cake and light refreshments following the commencement exercises on Friday, June 7, 2019 in the R&D Commons. R&D Commons Belfer sarah_donahue@hks.harvard.edu

June 20, 2019

Weakly Supervised Machine Learning at Industrial Scale

Stephen Bach

Brown University

7:00P

- 9:00P

Location

Seminar Room G449 (Patil/Kiva)

Kiva

Add to Calendar 2019-06-20 19:00:00 2019-06-20 21:00:00 America/New_York Weakly Supervised Machine Learning at Industrial Scale IEEE Computer Society and GBC/ACM7:00 PM, Thursday, 20 June 2019MIT Room 32-G449 (Kiva)This talk will be webcast on the MIT CSAIL Youtube channelhttp://www.youtube.com/channel/UCYs2iUgksAhgoidZwEAimmg/live beginning at7pm.Weakly Supervised Machine Learning at Industrial ScaleStephen Bach, Brown Labeling training data is one of the most costly bottlenecks in developing machine learning-based applications. Weak supervision, using less expensive but noisier sources of supervision than hand-labeled data, has the potential to relax this bottleneck but introduces new challenges around managing these sources. In this talk, I'll describe a new system, Snorkel DryBell, in production at Google for weakly supervised machine learning at industrial scale. Snorkel DryBell builds on the Snorkel framework ( snorkel.stanford.edu), extending it in three critical aspects: flexible, template-based ingestion of diverse organizational knowledge, cross-feature production serving, and scalable, sampling-free execution. On three classification tasks at Google, we find that Snorkel DryBell creates classifiers of comparable quality to ones trained with tens of thousands of hand-labeled examples, converts non-servable organizational resources to servable models for an average 52% performance improvement, and scales to millions of training examples.Stephen Bach is an assistant professor in the computer science department at Brown University. Previously, he was a visiting scholar at Google, and a postdoctoral scholar in the computer science department at Stanford University advised by Christopher Re. He received his Ph.D. in computer science from the University of Maryland, where he was advised by Lise Getoor. His research focuses on statistical machine learning methods that exploit high-level knowledge like rules and programs. Stephen's thesis on probabilistic soft logic was recognized with the University of Maryland's Larry S. Davis Doctoral Dissertation Award. His work on the Snorkel project for weakly supervised machine learning was recognized with a Best of VLDB 2018 selection.This joint meeting of the Boston Chapter of the IEEE Computer Society and GBC/ACM will be held in MIT Room 32-G449 (the Kiva conference room on the 4th floor of the Stata Center, building 32 on MIT maps). You can see it on this map of the MIT campus: Up-to-date information about this and other talks is available online at http://ewh.ieee.org/r1/boston/computer/. You can sign up to receive updated status information about this talk and informational emails about future talks at http://mailman.mit.edu/mailman/listinfo/ieee-cs, our self-administered mailing list. Seminar Room G449 (Patil/Kiva) Belfer sarah_donahue@hks.harvard.edu