Google AI Blog

An Inside Look at Flood Forecasting

Wednesday, September 18, 2019

Sella Nevo, Senior Software Engineer, Google Research, Tel Avivflood forecasting pilotexpanded our flood forecasting coverageAI for Social GoodThe Inundation Model

A 3D visualization of a hydraulic model simulating various river conditions.

Real-time Water Level MeasurementsIndian Central Water Commissionstream gauges

CWC employees measuring water level and discharge near Lucknow, India.

Elevation Map Creationdigital elevation modelsembankmentsHydraulic ModelingSaint-Venant equationsTensor Processing Unitsdata-driven discretization

A snapshot of a TPU-based simulation of flooding in Goalpara, mid-event.

European Space AgencySentinel-1Synthetic-Aperture Radar

Flood warnings across Google’s interfaces.

Looking Forward

The core processes of a hydrologic model. Designed by Daniel Klotz, JKU Institute for Machine Learning.

multi-task learningJKU Institute For Machine LearningKratzert et al.LSTMs

The distribution of NSE scores on basins across the United States for various models, showing the proposed EA-LSTM consistently outperforming a wide range of commonly used models.

AcknowledgementsThere are many people who contributed to this large effort, and we’d like to highlight some of the key contributors: Aaron Yonas, Adi Mano, Ajai Tirumali, Avinatan Hassidim, Carla Bromberg, Damien Pierce, Gal Elidan, Guy Shalev, John Anderson, Karan Agarwal, Kartik Murthy, Manan Singhi, Mor Schlesinger, Ofir Reich, Oleg Zlydenko, Pete Giencke, Piyush Poddar, Ruha Devanesan, Slava Salasin, Varun Gulshan, Vova Anisimov, Yossi Matias, Yi-fan Chen, Yotam Gigi, Yusef Shafi, Zach Moshe and Zvika Ben-Haim.

Project Ihmehimmeli: Temporal Coding in Spiking Neural Networks

Wednesday, September 18, 2019

Posted by Iulia-Maria Comșa and Krzysztof Potempa, Research Engineers, Google Research, Zürichvideogamesfine-grained understanding of videoartificial spiking neural networks

The Ihmehimmeli project team holding a himmeli, a symbol for the aim to build recurrent neural network architectures with temporal encoding of information.

publishedopen-sourcedbiologically-inspiredtransfer functionMNIST

A slow (“deliberative”) network (top) and a fast (“impulsive”) network (bottom) classifying the same MNIST digit. The figures show a raster plot of spike times of individual neurons in individual layers, with synchronization pulses shown in orange. In this example, both networks classify the digit correctly; overall, the “slow” network achieves better accuracy than the “fast” network.

recover representations

How the network “imagines” the digits 0, 1, 3 and 7.

AcknowledgementsThe work described here was authored by Iulia Comsa, Krzysztof Potempa, Luca Versari, Thomas Fischbacher, Andrea Gesmundo and Jyrki Alakuijala. We are grateful for all discussions and feedback on this work that we received from our colleagues at Google.

Google at Interspeech 2019

Sunday, September 15, 2019

Andrew Helton, Editor, Google Research Communications20th Annual Conference of the International Speech Communication AssociationParrotronblueOrganizing Committee Michiel BacchianiTechnical Program Committee Tara SainathTutorialsNeural Machine TranslationWolfgang Macherey, Yuan Cao
Accepted Publications(link to appear soon)Manasa Prasad, Daan van Esch, Sandy Ritchie, Jonas Fromseier Mortensen(link to appear soon)Yiteng Huang, Turaj Shabestary, Alexander Gruenstein, Li WanDirect Speech-to-Speech Translation with a Sequence-to-Sequence ModelYe Jia, Ron Weiss, Fadi Biadsy, Wolfgang Macherey, Melvin Johnson, Zhifeng Chen, Yonghui Wu(link to appear soon)Hanna Mazzawi, Javier Gonzalvo, Aleks Kracun, Prashant Sridhar, Niranjan Subrahmanya, Ignacio Lopez Moreno, Hyun Jin Park, Patrick Violette(link to appear soon)Ding Zhao, Tara Sainath, David Rybach, Pat Rondon, Deepti Bhatia, Bo Li, Ruoming Pang
VoiceFilter: Targeted Voice Separation by Speaker-Conditioned Spectrogram MaskingQuan Wang, Hannah Muckenhirn, Kevin Wilson, Prashant Sridhar, Zelin Wu, John Hershey, Rif Saurous, Ron Weiss, Ye Jia, Ignacio Lopez Moreno
SpecAugment: A Simple Data Augmentation Method for Automatic Speech RecognitionDaniel Park, William Chan, Yu Zhang, Chung-Cheng Chiu, Barret Zoph, Ekin Dogus Cubuk, Quoc LeTwo-Pass End-to-End Speech RecognitionRuoming Pang, Tara Sainath, David Rybach, Yanzhang He, Rohit Prabhavalkar, Mirko Visontai, Qiao Liang, Trevor Strohman, Yonghui Wu, Ian McGraw, Chung-Cheng ChiuOn the Choice of Modeling Unit for Sequence-to-Sequence Speech RecognitionKazuki Irie, Rohit Prabhavalkar, Anjuli Kannan, Antoine Bruguier, David Rybach, Patrick Nguyen(link to appear soon)Jack Serrino, Leonid Velikovich, Petar Aleksic, Cyril AllauzenJoint Speech Recognition and Speaker Diarization via Sequence TransductionLaurent El Shafey, Hagen Soltau, Izhak ShafranPersonalizing ASR for Dysarthric and Accented Speech with Limited DataJoel Shor, Dotan Emanuel, Oran Lang, Omry Tuval, Michael Brenner, Julie Cattiau, Fernando Vieira, Maeve McNally, Taylor Charbonneau, Melissa Nollstadt, Avinatan Hassidim, Yossi Matias(link to appear soon)Khe Chai Sim, Petr Zadrazil, Francoise BeaufaysSalient Speech Representations Based on Cloned NetworksBastiaan Kleijn, Felicia Lim, Michael Chinen, Jan Skoglund(link to appear soon)Cibu Johny, Alexander Gutkin, Martin JanscheLibriTTS: A Corpus Derived from LibriSpeech for Text-to-SpeechHeiga Zen, Viet Dang, Robert Clark, Yu Zhang, Ron Weiss, Ye Jia, Zhifeng Chen, Yonghui WuImproving Performance of End-to-End ASR on Numeric SequencesCal Peyser, Hao Zhang, Tara Sainath, Zelin Wu(link to appear soon)Harry Bleyan, Sandy Ritchie, Jonas Fromseier Mortensen, Daan van EschPhoneme-Based Contextualization for Cross-Lingual Speech Recognition in End-to-End ModelsKe Hu, Antoine Bruguier, Tara Sainath, Rohit Prabhavalkar, Golan PundakFréchet Audio Distance: A Reference-free Metric for Evaluating Music Enhancement AlgorithmsKevin Kilgour, Mauricio Zuluaga, Dominik Roblek, Matthew SharifiLearning to Speak Fluently in a Foreign Language: Multilingual Speech Synthesis and Cross-Language Voice CloningYu Zhang, Ron Weiss, Heiga Zen, Yonghui Wu, Zhifeng Chen, RJ Skerry-Ryan, Ye Jia, Andrew Rosenberg, Bhuvana RamabhadranSampling from Stochastic Finite Automata with Applications to CTC DecodingMartin Jansche, Alexander Gutkin(link to appear soon)Anjuli Kannan, Arindrima Datta, Tara Sainath, Eugene Weinstein, Bhuvana Ramabhadran, Yonghui Wu, Ankur Bapna, Zhifeng Chen, SeungJi LeeA Real-Time Wideband Neural Vocoder at 1.6 kb/s Using LPCNetJean-Marc Valin, Jan SkoglundLow-Dimensional Bottleneck Features for On-Device Continuous Speech RecognitionDavid Ramsay, Kevin Kilgour, Dominik Roblek, Matthew Sharif(link to appear soon)Sandy Ritchie, Richard Sproat, Kyle Gorman, Daan van Esch, Christian Schallhart, Nikos Bampounis, Benoit Brard, Jonas Mortensen, Amelia Holt, Eoin Mahon(link to appear soon)Dravyansh Sharma, Melissa Wilson, Antoine BruguierDual Encoder Classifier Models as Constraints in Neural Text NormalizationAjda Gokcen, Hao Zhang, Richard SproatLarge-Scale Visual Speech RecognitionBrendan Shillingford, Yannis Assael, Matthew Hoffman, Thomas Paine, Cían Hughes, Utsav Prabhu, Hank Liao, Hasim Sak, Kanishka Rao, Lorrayne Bennett, Marie Mulville, Ben Coppin, Ben Laurie, Andrew Senior, Nando de FreitasParrotron: An End-to-End Speech-to-Speech Conversion Model and its Applications to Hearing-Impaired Speech and Speech SeparationFadi Biadsy, Ron Weiss, Pedro Moreno, Dimitri Kanevsky, Ye Jia

Using Deep Learning to Inform Differential Diagnoses of Skin Diseases

Thursday, September 12, 2019

Posted by Yuan Liu, PhD, Software Engineer and Peggy Bui, MD, Technical Program Manager, Google Health37%more than half of those patients are seen by non-dermatologists24%70%7796malignant or benignwhether a lesion is melanomaare not malignantA Deep Learning System for Differential Diagnosis of Skin DiseasesDLS Designstasis dermatitiscellulitisdifferential diagnosisInception-v4teledermatology

Schematic of the DLS and how the reference standard (ground truth) was derived via the voting of three board-certified dermatologists for each case in the validation set.

Comparison to Professional Evaluations

The DLS’s leading (top-1) differential diagnosis is substantially higher than PCPs and NPs, and on par with dermatologists. This accuracy increases substantially when we look at the DLS’s top-3 accuracy, suggesting that in the majority of cases the DLS’s ranked list of diagnoses contains the correct ground truth answer for the case.

Assessing Demographic PerformanceFitzpatrick skin type

Left: An example of a case with hair loss that was challenging for non-specialists to arrive at the specific diagnosis, which is necessary for determining appropriate treatment. Right: An image with regions highlighted in green showing the areas that the DLS identified as important and used to make its prediction. Center: The combined image, which indicates that the DLS mostly focused on the area with hair loss to make this prediction, instead of on forehead skin color, for example, which may indicate potential bias.

Incorporating Multiple Data Types

The DLS performance improves when more images (blue line) or metadata (blue compared with red line) are present. In the absence of metadata as input, training a separate DLS using images alone leads to a marginal improvement compared to the current DLS (green line).

Future Work and ApplicationsAcknowledgementsThis work involved the efforts of a multidisciplinary team of software engineers, researchers, clinicians and cross functional contributors. Key contributors to this project include Yuan Liu, Ayush Jain, Clara Eng, David H. Way, Kang Lee, Peggy Bui, Kimberly Kanada, Guilherme de Oliveira Marinho, Jessica Gallegos, Sara Gabriele, Vishakha Gupta, Nalini Singh, Vivek Natarajan, Rainer Hofmann-Wellenhof, Greg S. Corrado, Lily H. Peng, Dale R. Webster, Dennis Ai, Susan Huang, Yun Liu, R. Carter Dunn and David Coz. The authors would like to acknowledge William Chen, Jessica Yoshimi, Xiang Ji and Quang Duong for software infrastructure support for data collection. Thanks also go to Genevieve Foti, Ken Su, T Saensuksopa, Devon Wang, Yi Gao and Linh Tran. Last but not least, this work would not have been possible without the participation of the dermatologists, primary care physicians, nurse practitioners who reviewed cases for this study, Sabina Bis who helped to establish the skin condition mapping and Amy Paller who provided feedback on the manuscript.

Learning Cross-Modal Temporal Representations from Unlabeled Videos

Wednesday, September 11, 2019

Posted by Chen Sun and Cordelia Schmid, Research Scientists, Google Researchtemporal localizationaction detectionself-driving carsnaturally resides in the data itselfVideoBERT: A Joint Model for Video and Language Representation LearningContrastive Bidirectional Transformer for Temporal Representation Learningautomatic speech recognitioncross-modal learning

Image frames and human speech from the same video locations are often semantically aligned. The alignment is non-exhaustive and sometimes noisy, which we hope to mitigate by pretraining on larger datasets. For the left example, the ASR output is, “Keep rolling tight and squeeze the air out to its side and you can kind of pull a little bit.”, where the actions are captured by speech but the objects are not. For the right example, the ASR output is, “This is where you need to be patient patient patient,” which is not related to the visual content at all.

A BERT Model for VideosBidirectional Encoder Representations from Transformersnatural language processingTransformercloze testtokens

Illustration of VideoBERT in the context of a video and text masked token prediction, or cloze, task. Bottom: visual and text (ASR) tokens from the same locations of videos are concatenated to form the inputs to VideoBERT. Some visual and text tokens are masked out. Middle: VideoBERT applies the Transformer architecture to jointly encode bidirectional visual-text context. Yellow and pink boxes correspond to the input and output embeddings, respectively. Top: the training objective is to recover the correct tokens for the masked locations.

Inspecting the VideoBERT Model

Qualitative results from VideoBERT, pretrained on cooking videos. Top: Given some recipe text, we generate a sequence of visual tokens. Bottom: Given a visual token, we show the top three future tokens forecast by VideoBERT at different time scales. In this case, the model predicts that a bowl of flour and cocoa powder may be baked in an oven, and may become a brownie or cupcake. We visualize the visual tokens using the images from the training set closest to the tokens in feature space.

“zero-shot” classificationTransfer Learning with Contrastive Bidirectional TransformersContrastive Bidirectional Transformerstransfer learningcontrastive lossmutual informationaverage poolingLSTMs

Action anticipation accuracy with the CBT approach from untrimmed videos with 200 activity classes. We compare with AvgPool and LSTM, and report performance when the observation time is 15, 30, 45 and 72 seconds.

Conclusion & future workAcknowledgementsThe core team includes Chen Sun, Fabien Baradel, Austin Myers, Carl Vondrick, Kevin Murphy and Cordelia Schmid. We would like to thank Jack Hessel, Bo Pang, Radu Soricut, Baris Sumengen, Zhenhai Zhu, and the BERT team for sharing amazing tools that greatly facilitated our experiments. We also thank Justin Gilmer, Abhishek Kumar, Ben Poole, David Ross, and Rahul Sukthankar for helpful discussions.

Recursive Sketches for Modular Deep Learning

Tuesday, September 10, 2019

Posted by Badih Ghazi and Joshua R. Wang, Research Scientists, Google Researchsmallefficientrobustthe foundational work of Alon, Matias, and SzegedyRecursive Sketches for Modular Deep LearningICML 2019how a machine learning model understands its inputBasic Sketching AlgorithmsxlinearxAxAwidexvariety of efficient algorithmsquantilesinterquartile rangefrequent elementssupport sizenormsentropy estimation

A simple method to sketch the vector x is to multiply it by a wide matrix A to produce a lower-dimensional vector y.

linear regressiondeep neural networksWord2VecImage EmbeddingsGloveDeepWalkBERTmodularNeural Network Modularitymodular deep networkNeural Modular NetworksCapsule Neural NetworksPathNetconvolutional neural networksconvolution kernels

This is a cartoon depiction of a modular network for image processing. Data flows from the bottom of the figure to the top through the modules represented with blue boxes. Note that modules in the lower layers correspond to basic objects, such as edges in an image, while modules in upper layers correspond to more complex objects, like humans or cats. Also notice that in this imaginary modular network, the output of the face module is generic enough to be used by both the human and cat modules.

Sketch Requirements

Sketch-to-Sketch Similarity: The sketches of two unrelated network operations (either in terms of the present modules or in terms of the attribute vectors) should be very different; on the other hand, the sketches of two similar network operations should be very close.

Attribute Recovery: The attribute vector, e.g., the activations of any node of the graph can be approximately recovered from the top-level sketch.

Summary Statistics: If there are multiple similar objects, we can recover summary statistics about them. For example, if an image has multiple cats, we can count how many there are. Note that we want to do this without knowing the questions ahead of time.

Graceful Erasure: Erasing a suffix of the top-level sketch maintains the above properties (but would smoothly increase the error).

Network Recovery: Given sufficiently many (input, sketch) pairs, the wiring of the edges of the network as well as the sketch function can be approximately recovered.

This is a 2D cartoon depiction of the sketch-to-sketch similarity property. Each vector represents a sketch and related sketches are more likely to cluster together.

The Sketching Mechanismsingle top-level sketchrecover the attributessummary statisticssketch-to-sketch similarityrecursive sketchingdictionary learningFuture Directionsmodel interpretabilityknowledge graphnewarchitecture searchAcknowledgementsThis work was the joint effort of Badih Ghazi, Rina Panigrahy and Joshua R. Wang.

Assessing the Quality of Long-Form Synthesized Speech

Monday, September 9, 2019

Posted by Tom Kenter, Google Research, London assistantssmart speaker devicesgenerating speech for low-resource languagescreating human-like speech with Tacotron 2Evaluating Long-form Text-to-Speech: Comparing the Ratings of Sentences and ParagraphsSSW10the same sentenceEvaluating Automatically Generated Speechpresenting the sentence in isolationprovide the full context for the sentenceprovide a context-stimulus paireven when applied to natural speech

MOS results for natural speech from a dataset consisting of news articles. Though the differences appear small, they are significant between all conditions (two-tailed t-test with α=0.05).

MOS results for synthesized speech on the same news article dataset used above. All lines are synthesized speech, unless indicated otherwise.

Predicting Paragraph ScoreConclusionAcknowledgmentsMany thanks to all authors of the paper: Rob Clark, Hanna Silen, Ralph Leith.

Announcing Two New Natural Language Dialog Datasets

Friday, September 6, 2019

Posted by Bill Byrne and Filip Radlinski, Research Scientists, Google ResearchCoached Conversational Preference ElicitationTaskmaster-1Wizard-of-Ozresearch paper2019 Annual Conference of the Special Interest Group on Discourse and Dialogueresearch paper2019 Conference on Empirical Methods in Natural Language ProcessingPreference ElicitationCCPETask-Oriented Dialog Taskmaster-1AcknowledgementsWe would like to thank our co-authors and collaborators whose hard work and insights made the release of these datasets possible: Karthik Krishnamoorthi, Krisztian Balog, Chinnadhurai Sankar, Arvind Neelakantan, Amit Dubey, Kyu-Young Kim, Andy Cedilnik, Scott Roy, Muqthar Mohammed, Mohd Majeed, Ashwin Kakarla and Hadar Shemtov.

Announcement of the 2019 Fellowship Awardees and Highlights from the Google PhD Fellowship Summit

Thursday, September 5, 2019

Posted by Susie Kim, Program Manager, University RelationsPhD Fellowship ProgramSummit HighlightsFLIPPeter NorvigPeggy ChiJeff DeanVinodkumar Prabhakaranhere

Google and FLIP Alliance Fellows attending the 2019 PhD Fellowship Summit

Poster session in full swing

2019 Google PhD Fellows Algorithms, Optimizations and MarketsEPFL Ecole Polytechnique Fédérale de LausanneColumbia UniversityTata Institute of Fundamental ResearchUniversity of Maryland at College ParkHarvard UniversityComputational NeuroscienceNew York UniversityGerman University in CairoHuman Computer InteractionStanford UniversityAustralian National UniversityUniversity of MelbourneMachine LearningAfrican University of Science and Technology AbujaColumbia UniversityIIT DelhiToyota Technological Institute at ChicagoPrinceton UniversityETH ZurichInternational University Of Rabat, MoroccoSeoul National UniversityCarnegie Mellon UniversityAlioune Diop University of BambeyUniversity of JohannesburgMassachusetts Institute of TechnologyUniversity of TokyoMachine Perception, Speech Technology and Computer VisionJohns Hopkins UniversityStellenbosch UniversityThe University of Texas at AustinUniversity of California San DiegoUniversity of Technology SydneyChinese University of Hong KongUniversity of AdelaideMobile ComputingUniversity of TokyoNatural Language ProcessingStanford UniversityIIT MadrasSeoul National UniversityUC BerkeleyUniversity of WashingtonUniversity of EdinburghKorea Advanced Institute of Science and TechnologyPrivacy and SecurityIndian Institute of ScienceInria NancyUniversity of Massachusetts AmherstBoston UniversityProgramming Technology and Software EngineeringUC BerkeleyUniversity of CambridgeUniversity of Illinois at Urbana-ChampaignQuantum ComputingMassachusetts Institute of TechnologyUniversity College LondonUniversity of Maryland at College ParkStructured Data and Database ManagementTel Aviv UniversityTechnionUniversity of UtahSystems and NetworkingUniversity of UtahUniversity of EdinburghCornell University

Blog