Google AI Blog

Google’s Next Generation Music Recognition

Friday, September 14, 2018

Posted by James Lyon, Google AI, ZürichNow Playingdeep neural networksSound SearchWhat’s this song?Hey Google, what’s this song?

Now Playing versus Sound SearchNow Playing miniaturized music recognitionThe Core Matching Process of Now Playing

Matching, phase 1: Finding good candidates: For every embedding, Now Playing performs a nearest neighbor search on the on-device database of songs for similar embeddings. The database uses a hybrid of spatial partitioning and vector quantization to efficiently search through millions of embedding vectors. Because the audio buffer is noisy, this search is approximate, and not every embedding will find a nearby match in the database for the correct song. However, over the whole clip, the chances of finding several nearby embeddings for the correct song are very high, so the search is narrowed to a small set of songs which got multiple hits.

Matching, phase 2: Final matching: Because the database search used above is approximate, Now Playing may not find song embeddings which are nearby to some embeddings in our query. Therefore, in order to calculate an accurate similarity score, Now Playing retrieves all embeddings for each song in the database which might be relevant to fill in the “gaps”. Then, given the sequence of embeddings from the audio buffer and another sequence of embeddings from a song in the on-device database, Now Playing estimates their similarity pairwise and adds up the estimates to get the final matching score.

Scaling up Now Playing for the Sound Search server

We quadrupled the size of the neural network used, and increased each embedding from 96 to 128 dimensions, which reduces the amount of work the neural network has to do to pack the high-dimensional input audio into a low-dimensional embedding. This is critical in improving the quality of phase two, which is very dependent on the accuracy of the raw neural network output.

We doubled the density of our embeddings — it turns out that fingerprinting audio every 0.5s instead of every 1s doesn’t reduce the quality of the individual embeddings very much, and gives us a huge boost by doubling the number of embeddings we can use for the match.

Conclusion

AcknowledgementsWe would like to thank Micha Riser, Mihajlo Velimirovic, Marvin Ritter, Ruiqi Guo, Sanjiv Kumar, Stephen Wu, Diego Melendo Casado‎, Katia Naliuka, Jason Sanders, Beat Gfeller, Julian Odell, Christian Frank, Dominik Roblek, Matt Sharifi and Blaise Aguera y Arcas‎.

Introducing the Unrestricted Adversarial Examples Challenge

Thursday, September 13, 2018

Posted by Tom B. Brown and Catherine Olsson, Research Engineers, Google Brain Teammedicinechemistryagricultureadversarial examplesprevious research on adversarial examplesimproved modelsnot subject to the “small modification” constraintconfident errors when faced with an adversaryanyUnrestricted Adversarial Examples Challenge

Adversarial examples can be generated through a variety of means, including by making small modifications to the input pixels, but also using spatial transformations, or simple guess-and-check to find misclassified inputs.

Structure of the Challengedefenderattackerfull two-sided challenge with prizes for both attacks and defenses

Is this an unambiguous picture of a bird, a bicycle, or is it ambiguous / not obvious?defender's goalattacker's goal

Examples of ambiguous and unambiguous images. Defenders must make no confident mistakes on unambiguous bird or bicycle images. We discard all images that humans find ambiguous or not obvious. All images under CC licenses 1, 2, 3, 4.

our paperHow to Participatethe project on githubleaderboardAcknowledgementsThe team behind the Unrestricted Adversarial Examples Challenge includes Tom Brown, Catherine Olsson, Nicholas Carlini, Chiyuan Zhang, and Ian Goodfellow from Google, and Paul Christiano from OpenAI.

The What-If Tool: Code-Free Probing of Machine Learning Models

Tuesday, September 11, 2018

Posted by James Wexler, Software Engineer, Google AIHow would changes to a datapoint affect my model’s prediction? Does it perform differently for various groups–for example, historically marginalized people? How diverse is the dataset I am testing my model on?Google AI PAIR initiativeWhat-If ToolTensorBoard

The What-If Tool, showing a set of 250 face pictures and their results from a model that detects smiles.

Facets

Exploring what-if scenarios on a datapoint.

CounterfactualsUCI census dataset

Comparing counterfactuals.

Analysis of Performance and Algorithmic Fairnessnumerical fairness criteriaCelebA datasetROC curveconfusion matrixequal opportunity

Comparing the performance of two slices of data on a smile detection model, with their classification thresholds set to satisfy the “equal opportunity” constraint.

Demos

Detecting misclassifications: A multiclass classification model, which predicts plant type from four measurements of a flower from the plant. The tool is helpful in showing the decision boundary of the model and what causes misclassifications. This model is trained with the UCI iris dataset.

Assessing fairness in binary classification models: The image classification model for smile detection mentioned above. The tool is helpful in assessing algorithmic fairness across different subgroups. The model was purposefully trained without providing any examples from a specific subset of the population, in order to show how the tool can help uncover such biases in models. Assessing fairness requires careful consideration of the overall context — but this is a useful quantitative starting point.

Investigating model performance across different subgroups: A regression model that predicts a subject’s age from census information. The tool is helpful in showing relative performance of the model across subgroups and how the different features individually affect the prediction. This model is trained with the UCI census dataset.

What-If in PracticeAcknowledgmentsThe What-If Tool was a collaborative effort, with UX design by Mahima Pushkarna, Facets updates by Jimbo Wilson, and input from many others. We would like to thank the Google teams that piloted the tool and provided valuable feedback and the TensorBoard team for all their help.

Text-to-Speech for Low-Resource Languages (Episode 4): One Down, 299 to Go

Friday, September 7, 2018

Posted by Alexander Gutkin, Software Engineer, Google AIThis is the fourth episode in the series of posts reporting on the work we are doing to build text-to-speech (TTS) systems for low resource languages. In the first episode, we described the crowdsourced acoustic data collection effort for Project Unison. In the second episode, we described how we built parametric voices based on that data. In the third episode, we described the compilation of a pronunciation lexicon for a TTS system. In this episode, we describe how to make a single TTS system speak many languages.multiple languagesmultilingualinitial investigationnew modelInternational Phonetic AlphabetExploring the Closely Related Languages of Indonesialanguages of IndonesiaStandard IndonesianJavaneseSundanesephonologies

Joint phoneme inventory of Indonesian, Javanese, and Sundanese in International Phonetic Alphabet notation.

Google TranslateAndroidExpanding to the More Diverse Language Families of South Asiavery differentIndo-AryanDravidianSanskritculture

Descendants of Sanskrit word for “culture” across languages.

TeluguKannadaWest BengaliOdiaGujaratiMarathiphonologyorthographyin our recent paper

Diagram illustrating our multilingual text-to-speech approach. The input text queries are processed by language-specific linguistic front-ends to generate pronunciations in a shared phonemic representation serving as input to the language-agnostic acoustic model. The model then generates audio for the respective queries.

Indian BengaliGujaratiKannadaMalayalamMarathiTamilTeluguUrduNepaliSinhalaHindiBangladeshi BengaliGoogle for IndiaNepaliSinhalaBengaliKhmerJavaneseSundaneseSLTUInterspeech

Introducing the Inclusive Images Competition

Thursday, September 6, 2018

Posted by Tulsee Doshi, Product Manager, Google AIImageNetOpen ImagesConceptual Captionsfound to be geographically skewedwedding

Wedding photographs (donated by Googlers), labeled by a classifier trained on the Open Images dataset. The classifier’s label predictions are recorded below each image.

Inclusive Images Competition on KaggleConference on Neural Information Processing Systems Competition TrackOpen Images

The three geographical distributions of data in this competition. Competitors will train their models on Open Images, a widely used publicly available benchmark dataset for image classification which happens to be drawn mostly from North America and Western Europe. Models are then evaluated first on Challenge Stage 1 and finally on Challenge Stage 2, each with different un-revealed geographical distributions. In this way, models are stress-tested for their ability to operate inclusively beyond their training data.

Crowdsource project

Examples of labeled images from the challenge dataset. Clockwise from top left, image donation by Peter Tester, Mukesh Kumhar, HeeYoung Moon, Sudipta Pramanik, jaturan amnatbuddee, Tomi Familoni and Anu Subhi

September 5thMonday, November 5thTuesday, November 6thInclusive Images Competition websiteConference on Neural Information Processing Systemsthis pageAcknowledgementsWe would like to thank the following individuals for making the Inclusive Image Competition and dataset possible: James Atwood, Pallavi Baljekar, Parker Barnes, Anurag Batra, Eric Breck, Peggy Chi, Tulsee Doshi, Julia Elliott, Gursheesh Kour, Akshay Gaur, Yoni Halpern, Henry Jicha, Matthew Long, Jigyasa Saxena, Richa Singh and D. Sculley.

Conceptual Captions: A New Dataset and Challenge for Image Captioning

Wednesday, September 5, 2018

Posted by Piyush Sharma, Software Engineer and Radu Soricut, Research Scientist, Google AIAlt-text HTMLtext-to-speech systemsautomatic image captioning

Image captioning can help millions with visual impairments by converting images captions to text. Image by Francis Vallance (Heritage Warrior), used under CC BY 2.0 license.

Conceptual Captionsa paperACL 2018MS-COCO datasetConceptual Captions Challenge

Illustration of images and captions in the Conceptual Captions dataset.
Clockwise from top left, images by Jonny Hunter, SigNote Cloud, Tony Hisgett, ResoluteSupportMedia. All images used under CC BY 2.0 license

Generating the Datasetour paperimage classification modelsword variationsFrom Specific Names to General Concepts¹Former Miss World Priyanka Chopraactorin Los AngelesItalianartist and artist

Illustration of text modification. Image by Rockoleando used under CC BY 2.0 license.

Dataset ImpactRNNTransformerTensor2TensorMS-COCOour paperFlickr30K

Get InvolvedConceptual Captions ChallengeAcknowledgementsThanks to Nan Ding, Sebastian Goodman and Bo Pang for training models with Conceptual Captions dataset, and to Amol Wankhede for driving the public release efforts for the dataset.
1 In our paper, we posit that if automatic determination of names, locations, brands, etc. from the image is needed, it should be done as a separate task that may leverage image meta-information (e.g. GPS info), or complementary techniques such as OCR.^↩

Understanding Performance Fluctuations in Quantum Processors

Friday, August 31, 2018

Posted by Paul V. Klimov, Research Scientist, Google AI Quantum TeamGoogle AI Quantum teamsuperconducting electrical circuitsquantum bitsmodest processor sizesFluctuations of Energy-Relaxation Times in Superconducting QubitsPhysical Review Letters energy relaxation timesT1T1

Left: A quantum processor similar to the one that was used to investigate qubit performance fluctuations. One qubit is highlighted in blue. Right: One qubit’s energy-relaxation time “T1” plotted as a function of it’s operating frequency and time. We see energy-relaxation hotspots, which our data suggest are due to material defects (black arrowheads). The motion of these hotspots into and out-of resonance with the qubit are responsible for the most significant energy-relaxation fluctuations. Note that these data were taken over a frequency band with an above-average density of defects.

still puzzles researchersthermodynamics arguments

Teaching the Google Assistant to be Multilingual

Thursday, August 30, 2018

Posted by Johan Schalkwyk, VP and Ignacio Lopez Moreno, Engineer, Google Speech123launching

The Google Assistant is now able to identify the language, interpret the query and provide a response using the right language without the user having to touch the Assistant settings.

Identifying Multiple LanguagesUnderstanding Multiple LanguagesOptimizing Multilingual RecognitionIdentifying Multiple Languages¹45recurrent neural networksUnderstanding Multiple Languagesset an alarm for 6pmset an alarm6pmany given pairspeech recognition systems

Schematic of our multilingual speech recognition system used by the Google Assistant versus the standard monolingual speech recognition system. A ranking algorithm is used to select the best recognition hypotheses from two monolingual speech recognizer using relevant information about the user and the incremental langID results.

Optimizing Multilingual Recognitionrandom forestBilingual to Trilingualall
1 It is typically acknowledged that spoken language recognition is remarkably more challenging than text-based language identification where, relatively simple techniques based on dictionaries can do a good job. The time/frequency patterns of spoken words are difficult to compare, spoken words can be more difficult to delimit as they can be spoken without pause and at different paces and microphones may record background noise in addition to speech.^↩

Introducing a New Framework for Flexible and Reproducible Reinforcement Learning Research

Monday, August 27, 2018

Posted by Pablo Samuel Castro, Research Software Developer and Marc G. Bellemare, Research Scientist, Google Brain TeamReinforcement learningDQNAlphaGoAlphaGo ZeroOpen AI Fivelarge-scale distributed trainindistributional methodsrobotic manipulationteaching robots to visually self-adaptTensorflow-based frameworkreward-motivated behaviour in the brainset of colabsEase of Usewell-documentedArcade Learning EnvironmentDQNC51Rainbow agentImplicit Quantile Network agentInternational Conference on Machine LearningReproducibilityMachado et al. (2018)Benchmarkingfull training dataJSON data filesa website

The training runs for our 4 agents on Seaquest. The x-axis represents iterations, where each iteration is 1 million game frames (4.5 hours of real-time play); the y-axis is the average score obtained per play. The shaded areas show confidence intervals from 5 independent runs.

Tensorboarddownloads sectiongithub repoAcknowledgementsThis project was only possible thanks to several collaborations at Google. The core team includes Marc G. Bellemare, Pablo Samuel Castro, Carles Gelada, Subhodeep Moitra and Saurabh Kumar. We also extend a special thanks to Sergio Guadamarra, Ofir Nachum, Yifan Wu, Clare Lyle, Liam Fedus, Kelvin Xu, Emilio Parisoto, Hado van Hasselt, Georg Ostrovski and Will Dabney, and the many people at Google who helped us test it out.

Moving Beyond Translation with the Universal Transformer

Wednesday, August 15, 2018

Posted by Stephan Gouws, Research Scientist, Google Brain Team and Mostafa Dehghani, University of Amsterdam PhD student and Google Research Internthe Transformerrecurrent neural networkssequentiallyrecurrenceabcabcabcNeural GPUNeural Turing MachineUniversal TransformersTuring completeparallel-in-time recurrence

The Universal Transformer repeatedly refines a series of vector representations (shown as h₁ to h_m) for each position of the sequence in parallel, by combining information from different positions using self-attention and applying a recurrent transition function. Arrows denote dependencies between operations.

adaptive computation mechanismI arrived at the bank after crossing the riverbankIriverbanksinglesequencedifferent transformationsbAbI linguistic reasoning taskLAMBADA language modeling taskBLEU¹hereAcknowledgementsThis research was conducted by Mostafa Dehghani, Stephan Gouws, Oriol Vinyals, Jakob Uszkoreit, and Łukasz Kaiser. Additional thanks go to Ashish Vaswani, Douglas Eck, and David Dohan for their fruitful comments and inspiration.
1 A translation quality benchmark widely used in the machine translation community, computed on the standard WMT newstest2014 English to German translation test data set.^↩

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