Top-10 AI Research Highlights of 2021

  1. AI4Science in the limelight: We developed AI methods for simulating complex multi-scale phenomena such as weather, materials, etc. with orders of magnitude speed-ups. Our core technique, Fourier Neural Operator (FNO), was recently featured as a highlight of math and computer science advances in 2021 by Quanta Magazine. It was also featured in the GTC Fall keynote and the  IamAI video, released by NVIDIA. In addition, we advanced drug discovery through Orbnet that predicts quantum-mechanical properties with thousands of times speedup. Both these techniques were part of publications that were finalists for the Gordon-Bell special prize for Covid-19 research.  
  1. Quantum ML research taking roots: Our foray into quantum research was aided by our research on tensor methods for deep learning, since tensor networks represent quantum systems efficiently. We developed a new algorithm for quantum optimization that halved the quantum resources needed to solve classical optimization such as maxcut, which implies an exponential reduction for simulating them on GPUs. We partnered with the NVIDIA cuQuantum team and established a world-record for large-scale simulation of a successful, nonlocal quantum optimization algorithm, and open-sourced Tensorly-Quantum.
  1. Trustworthy AI no longer just a wish list: Forbes predicts that trustworthy AI will be operationalized in the next year. Trustworthy AI has many facets: improving uncertainty calibration, auditing AI models and improving robustness. We improved the robustness of AI models through various approaches: certifying robustness, balancing diversity and hardness of data augmentations, and enhancing robustness of 3D vision. We demonstrated that language models can detect different kinds of social biases without any re-training, when supplied with a small number of labeled examples. 
  1. Metaverse calling: We continue to develop large-scale reinforcement and interactive  learning algorithms using efficient GPU-accelerated physically-valid simulations. We developed rapidly adaptive robot manipulation methods in NVIDIA Isaac Gym that combined physics and learning effectively. We developed efficient skill chaining methods, visual reinforcement learning, morphology co-design, uncertainty quantification and stability-aware RL methods.  
  1. No more supervision: 99% of computer vision teams have had a ML project canceled due to insufficient training data, according to a survey. We have made strides in weak and self-supervised learning (Discobox) that are competitive with supervised learning methods. We have also developed efficient controllable generation methods that can do zero-shot composition of attributes. Gartner predicts that by 2024, synthetic data will account for 60% of all data used in AI development. We also developed efficient methods for automatic camera calibration using neural radiance field (NERF) models.
  1. Transformers transforming vision and language: The Cambrian explosion of transformer architectures continued this year, with a focus on harder tasks and multimodal domains. We developed Segformer for semantic and panoptic segmentation with SOTA performance and efficiency, which is being used by multiple teams across the company. We enabled linear efficiency in self-attention layers using long-short decomposition and adaptive Fourier neural operator. 
  1. Bridging the gap with biological intelligence: Humans are capable of zero-shot generalization, and can handle long-tailed distributions. We developed efficient controllable generation methods that can do zero-shot composition of attributes. We showed that simple memory-recall strategies enable efficient long-tailed object detection. Such capabilities have been framed as formative AI intellect by Gartner.
  1. Hardware efficiency: We co-designed both a quantization scheme and an AI training method to obtain energy efficiency and accuracy. The logarithmic number system (LNS) provides a high dynamic range, but the non-linear quantization gaps make it challenging to train using standard methods such as SGD. Instead, we employed multiplicative updates that are able to train AI models directly in LNS using just 8 bits, without requiring any full-precision copies. This resulted in no accuracy loss and 90% reduction in energy. 
  1. Hub of collaborations: Grateful to be supported by an amazing network of collaborators across multiple institutions in a wide array of domains. We are excited about the announcement of Earth-2 that will enable NVIDIA to partner with researchers in climate science globally.
  1. Personal touch: 2021 has been a greatly fulfilling year on both personal and professional fronts. I spent the beginning of the year in Hawaii, a dream playground, where I got to swim every evening into the sunset after my meetings. I started weight training and was surprised at being able to lift my own body weight! Focusing on my physical and spiritual health has greatly enhanced my creativity and productivity. During the latter half of the year, I got to attend some events in person. A highlight was a trip to CERN where I got to tour the particle accelerator and the antimatter factory; my interview, Stealing theorist’s lunch, was published in the CERN Courier magazine. I got to participate in an unusual documentary that featured  our fishing trip at Jackson Hole where we collected snapshots of casts of fly fishing and trained AI to predict good casts. I also participated in latenightIT show, hosted by the Emmy nominated Baratunde Thurston. Here’s looking forward to new adventures in 2022! 

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