Your search keyword '"Sharma, Mrinank"' showing total 33 results

1. PoisonBench: Assessing Large Language Model Vulnerability to Data Poisoning

Author

Fu, Tingchen, Sharma, Mrinank, Torr, Philip, Cohen, Shay B., Krueger, David, and Barez, Fazl

Subjects

Computer Science - Cryptography and Security, Computer Science - Artificial Intelligence, Computer Science - Computation and Language

Abstract

Preference learning is a central component for aligning current LLMs, but this process can be vulnerable to data poisoning attacks. To address this concern, we introduce PoisonBench, a benchmark for evaluating large language models' susceptibility to data poisoning during preference learning. Data poisoning attacks can manipulate large language model responses to include hidden malicious content or biases, potentially causing the model to generate harmful or unintended outputs while appearing to function normally. We deploy two distinct attack types across eight realistic scenarios, assessing 21 widely-used models. Our findings reveal concerning trends: (1) Scaling up parameter size does not inherently enhance resilience against poisoning attacks; (2) There exists a log-linear relationship between the effects of the attack and the data poison ratio; (3) The effect of data poisoning can generalize to extrapolated triggers that are not included in the poisoned data. These results expose weaknesses in current preference learning techniques, highlighting the urgent need for more robust defenses against malicious models and data manipulation., Comment: Tingchen Fu and Fazl Barez are core research contributors

Published

2024

2. When Do Universal Image Jailbreaks Transfer Between Vision-Language Models?

Author

Schaeffer, Rylan, Valentine, Dan, Bailey, Luke, Chua, James, Eyzaguirre, Cristóbal, Durante, Zane, Benton, Joe, Miranda, Brando, Sleight, Henry, Hughes, John, Agrawal, Rajashree, Sharma, Mrinank, Emmons, Scott, Koyejo, Sanmi, and Perez, Ethan

Subjects

Computer Science - Computation and Language, Computer Science - Artificial Intelligence, Computer Science - Cryptography and Security, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

The integration of new modalities into frontier AI systems offers exciting capabilities, but also increases the possibility such systems can be adversarially manipulated in undesirable ways. In this work, we focus on a popular class of vision-language models (VLMs) that generate text outputs conditioned on visual and textual inputs. We conducted a large-scale empirical study to assess the transferability of gradient-based universal image "jailbreaks" using a diverse set of over 40 open-parameter VLMs, including 18 new VLMs that we publicly release. Overall, we find that transferable gradient-based image jailbreaks are extremely difficult to obtain. When an image jailbreak is optimized against a single VLM or against an ensemble of VLMs, the jailbreak successfully jailbreaks the attacked VLM(s), but exhibits little-to-no transfer to any other VLMs; transfer is not affected by whether the attacked and target VLMs possess matching vision backbones or language models, whether the language model underwent instruction-following and/or safety-alignment training, or many other factors. Only two settings display partially successful transfer: between identically-pretrained and identically-initialized VLMs with slightly different VLM training data, and between different training checkpoints of a single VLM. Leveraging these results, we then demonstrate that transfer can be significantly improved against a specific target VLM by attacking larger ensembles of "highly-similar" VLMs. These results stand in stark contrast to existing evidence of universal and transferable text jailbreaks against language models and transferable adversarial attacks against image classifiers, suggesting that VLMs may be more robust to gradient-based transfer attacks.

Published

2024

3. Sleeper Agents: Training Deceptive LLMs that Persist Through Safety Training

Author

Hubinger, Evan, Denison, Carson, Mu, Jesse, Lambert, Mike, Tong, Meg, MacDiarmid, Monte, Lanham, Tamera, Ziegler, Daniel M., Maxwell, Tim, Cheng, Newton, Jermyn, Adam, Askell, Amanda, Radhakrishnan, Ansh, Anil, Cem, Duvenaud, David, Ganguli, Deep, Barez, Fazl, Clark, Jack, Ndousse, Kamal, Sachan, Kshitij, Sellitto, Michael, Sharma, Mrinank, DasSarma, Nova, Grosse, Roger, Kravec, Shauna, Bai, Yuntao, Witten, Zachary, Favaro, Marina, Brauner, Jan, Karnofsky, Holden, Christiano, Paul, Bowman, Samuel R., Graham, Logan, Kaplan, Jared, Mindermann, Sören, Greenblatt, Ryan, Shlegeris, Buck, Schiefer, Nicholas, and Perez, Ethan

Subjects

Computer Science - Cryptography and Security, Computer Science - Artificial Intelligence, Computer Science - Computation and Language, Computer Science - Machine Learning, Computer Science - Software Engineering

Abstract

Humans are capable of strategically deceptive behavior: behaving helpfully in most situations, but then behaving very differently in order to pursue alternative objectives when given the opportunity. If an AI system learned such a deceptive strategy, could we detect it and remove it using current state-of-the-art safety training techniques? To study this question, we construct proof-of-concept examples of deceptive behavior in large language models (LLMs). For example, we train models that write secure code when the prompt states that the year is 2023, but insert exploitable code when the stated year is 2024. We find that such backdoor behavior can be made persistent, so that it is not removed by standard safety training techniques, including supervised fine-tuning, reinforcement learning, and adversarial training (eliciting unsafe behavior and then training to remove it). The backdoor behavior is most persistent in the largest models and in models trained to produce chain-of-thought reasoning about deceiving the training process, with the persistence remaining even when the chain-of-thought is distilled away. Furthermore, rather than removing backdoors, we find that adversarial training can teach models to better recognize their backdoor triggers, effectively hiding the unsafe behavior. Our results suggest that, once a model exhibits deceptive behavior, standard techniques could fail to remove such deception and create a false impression of safety., Comment: updated to add missing acknowledgements

Published

2024

4. Towards Understanding Sycophancy in Language Models

Author

Sharma, Mrinank, Tong, Meg, Korbak, Tomasz, Duvenaud, David, Askell, Amanda, Bowman, Samuel R., Cheng, Newton, Durmus, Esin, Hatfield-Dodds, Zac, Johnston, Scott R., Kravec, Shauna, Maxwell, Timothy, McCandlish, Sam, Ndousse, Kamal, Rausch, Oliver, Schiefer, Nicholas, Yan, Da, Zhang, Miranda, and Perez, Ethan

Subjects

Computer Science - Computation and Language, Computer Science - Artificial Intelligence, Computer Science - Machine Learning, Statistics - Machine Learning, I.2.6

Abstract

Human feedback is commonly utilized to finetune AI assistants. But human feedback may also encourage model responses that match user beliefs over truthful ones, a behaviour known as sycophancy. We investigate the prevalence of sycophancy in models whose finetuning procedure made use of human feedback, and the potential role of human preference judgments in such behavior. We first demonstrate that five state-of-the-art AI assistants consistently exhibit sycophancy across four varied free-form text-generation tasks. To understand if human preferences drive this broadly observed behavior, we analyze existing human preference data. We find that when a response matches a user's views, it is more likely to be preferred. Moreover, both humans and preference models (PMs) prefer convincingly-written sycophantic responses over correct ones a non-negligible fraction of the time. Optimizing model outputs against PMs also sometimes sacrifices truthfulness in favor of sycophancy. Overall, our results indicate that sycophancy is a general behavior of state-of-the-art AI assistants, likely driven in part by human preference judgments favoring sycophantic responses., Comment: 32 pages, 20 figures

Published

2023

5. Understanding and Controlling a Maze-Solving Policy Network

Author

Mini, Ulisse, Grietzer, Peli, Sharma, Mrinank, Meek, Austin, MacDiarmid, Monte, and Turner, Alexander Matt

Subjects

Computer Science - Artificial Intelligence

Abstract

To understand the goals and goal representations of AI systems, we carefully study a pretrained reinforcement learning policy that solves mazes by navigating to a range of target squares. We find this network pursues multiple context-dependent goals, and we further identify circuits within the network that correspond to one of these goals. In particular, we identified eleven channels that track the location of the goal. By modifying these channels, either with hand-designed interventions or by combining forward passes, we can partially control the policy. We show that this network contains redundant, distributed, and retargetable goal representations, shedding light on the nature of goal-direction in trained policy networks., Comment: 46 pages

Published

2023

6. Incorporating Unlabelled Data into Bayesian Neural Networks

Author

Sharma, Mrinank, Rainforth, Tom, Teh, Yee Whye, and Fortuin, Vincent

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Statistics - Machine Learning

Abstract

Conventional Bayesian Neural Networks (BNNs) are unable to leverage unlabelled data to improve their predictions. To overcome this limitation, we introduce Self-Supervised Bayesian Neural Networks, which use unlabelled data to learn models with suitable prior predictive distributions. This is achieved by leveraging contrastive pretraining techniques and optimising a variational lower bound. We then show that the prior predictive distributions of self-supervised BNNs capture problem semantics better than conventional BNN priors. In turn, our approach offers improved predictive performance over conventional BNNs, especially in low-budget regimes., Comment: Published in the Transactions on Machine Learning Research

Published

2023

7. Do Bayesian Neural Networks Need To Be Fully Stochastic?

Author

Sharma, Mrinank, Farquhar, Sebastian, Nalisnick, Eric, and Rainforth, Tom

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Statistics - Machine Learning

Abstract

We investigate the benefit of treating all the parameters in a Bayesian neural network stochastically and find compelling theoretical and empirical evidence that this standard construction may be unnecessary. To this end, we prove that expressive predictive distributions require only small amounts of stochasticity. In particular, partially stochastic networks with only $n$ stochastic biases are universal probabilistic predictors for $n$-dimensional predictive problems. In empirical investigations, we find no systematic benefit of full stochasticity across four different inference modalities and eight datasets; partially stochastic networks can match and sometimes even outperform fully stochastic networks, despite their reduced memory costs., Comment: Published at AISTATS2023 (Oral)

Published

2022

8. Prioritized Training on Points that are Learnable, Worth Learning, and Not Yet Learnt

Author

Mindermann, Sören, Brauner, Jan, Razzak, Muhammed, Sharma, Mrinank, Kirsch, Andreas, Xu, Winnie, Höltgen, Benedikt, Gomez, Aidan N., Morisot, Adrien, Farquhar, Sebastian, and Gal, Yarin

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Computation and Language, Computer Science - Computer Vision and Pattern Recognition

Abstract

Training on web-scale data can take months. But most computation and time is wasted on redundant and noisy points that are already learnt or not learnable. To accelerate training, we introduce Reducible Holdout Loss Selection (RHO-LOSS), a simple but principled technique which selects approximately those points for training that most reduce the model's generalization loss. As a result, RHO-LOSS mitigates the weaknesses of existing data selection methods: techniques from the optimization literature typically select 'hard' (e.g. high loss) points, but such points are often noisy (not learnable) or less task-relevant. Conversely, curriculum learning prioritizes 'easy' points, but such points need not be trained on once learned. In contrast, RHO-LOSS selects points that are learnable, worth learning, and not yet learnt. RHO-LOSS trains in far fewer steps than prior art, improves accuracy, and speeds up training on a wide range of datasets, hyperparameters, and architectures (MLPs, CNNs, and BERT). On the large web-scraped image dataset Clothing-1M, RHO-LOSS trains in 18x fewer steps and reaches 2% higher final accuracy than uniform data shuffling., Comment: ICML 2022

Published

2022

9. Prioritized training on points that are learnable, worth learning, and not yet learned (workshop version)

Author

Mindermann, Sören, Razzak, Muhammed, Xu, Winnie, Kirsch, Andreas, Sharma, Mrinank, Morisot, Adrien, Gomez, Aidan N., Farquhar, Sebastian, Brauner, Jan, and Gal, Yarin

Subjects

Computer Science - Machine Learning, Computer Science - Information Theory

Abstract

We introduce Goldilocks Selection, a technique for faster model training which selects a sequence of training points that are "just right". We propose an information-theoretic acquisition function -- the reducible validation loss -- and compute it with a small proxy model -- GoldiProx -- to efficiently choose training points that maximize information about a validation set. We show that the "hard" (e.g. high loss) points usually selected in the optimization literature are typically noisy, while the "easy" (e.g. low noise) samples often prioritized for curriculum learning confer less information. Further, points with uncertain labels, typically targeted by active learning, tend to be less relevant to the task. In contrast, Goldilocks Selection chooses points that are "just right" and empirically outperforms the above approaches. Moreover, the selected sequence can transfer to other architectures; practitioners can share and reuse it without the need to recreate it.

Published

2021

10. How Robust are the Estimated Effects of Nonpharmaceutical Interventions against COVID-19?

Author

Sharma, Mrinank, Mindermann, Sören, Brauner, Jan Markus, Leech, Gavin, Stephenson, Anna B., Gavenčiak, Tomáš, Kulveit, Jan, Teh, Yee Whye, Chindelevitch, Leonid, and Gal, Yarin

Subjects

Statistics - Applications, Computer Science - Machine Learning, Quantitative Biology - Populations and Evolution, Quantitative Biology - Quantitative Methods, Statistics - Machine Learning

Abstract

To what extent are effectiveness estimates of nonpharmaceutical interventions (NPIs) against COVID-19 influenced by the assumptions our models make? To answer this question, we investigate 2 state-of-the-art NPI effectiveness models and propose 6 variants that make different structural assumptions. In particular, we investigate how well NPI effectiveness estimates generalise to unseen countries, and their sensitivity to unobserved factors. Models that account for noise in disease transmission compare favourably. We further evaluate how robust estimates are to different choices of epidemiological parameters and data. Focusing on models that assume transmission noise, we find that previously published results are remarkably robust across these variables. Finally, we mathematically ground the interpretation of NPI effectiveness estimates when certain common assumptions do not hold.

Published

2020

11. Differentially Private Federated Variational Inference

Author

Sharma, Mrinank, Hutchinson, Michael, Swaroop, Siddharth, Honkela, Antti, and Turner, Richard E.

Subjects

Statistics - Machine Learning, Computer Science - Machine Learning

Abstract

In many real-world applications of machine learning, data are distributed across many clients and cannot leave the devices they are stored on. Furthermore, each client's data, computational resources and communication constraints may be very different. This setting is known as federated learning, in which privacy is a key concern. Differential privacy is commonly used to provide mathematical privacy guarantees. This work, to the best of our knowledge, is the first to consider federated, differentially private, Bayesian learning. We build on Partitioned Variational Inference (PVI) which was recently developed to support approximate Bayesian inference in the federated setting. We modify the client-side optimisation of PVI to provide an (${\epsilon}$, ${\delta}$)-DP guarantee. We show that it is possible to learn moderately private logistic regression models in the federated setting that achieve similar performance to models trained non-privately on centralised data., Comment: Privacy in Machine Learning Workshop (PriML 2019) at the 33rd Conference in Neural Information and Processing Systems (NeurIPS)

Published

2019

12. A dataset of non-pharmaceutical interventions on SARS-CoV-2 in Europe

Author

Altman, George, Ahuja, Janvi, Monrad, Joshua Teperowski, Dhaliwal, Gurpreet, Rogers-Smith, Charlie, Leech, Gavin, Snodin, Benedict, Sandbrink, Jonas B., Finnveden, Lukas, Norman, Alexander John, Oehm, Sebastian B., Sandkühler, Julia Fabienne, Kulveit, Jan, Flaxman, Seth, Gal, Yarin, Mishra, Swapnil, Bhatt, Samir, Sharma, Mrinank, Mindermann, Sören, and Brauner, Jan Markus

Published

2022

13. Changing composition of SARS-CoV-2 lineages and rise of Delta variant in England

Author

Mishra, Swapnil, Mindermann, Sören, Sharma, Mrinank, Whittaker, Charles, Mellan, Thomas A, Wilton, Thomas, Klapsa, Dimitra, Mate, Ryan, Fritzsche, Martin, Zambon, Maria, Ahuja, Janvi, Howes, Adam, Miscouridou, Xenia, Nason, Guy P, Ratmann, Oliver, Semenova, Elizaveta, Leech, Gavin, Sandkühler, Julia Fabienne, Rogers-Smith, Charlie, Vollmer, Michaela, Unwin, H Juliette T, Gal, Yarin, Chand, Meera, Gandy, Axel, Martin, Javier, Volz, Erik, Ferguson, Neil M, Bhatt, Samir, Brauner, Jan M, and Flaxman, Seth

Published

2021

14. Understanding the effectiveness of government interventions against the resurgence of COVID-19 in Europe

Author

Sharma, Mrinank, Mindermann, Sören, Rogers-Smith, Charlie, Leech, Gavin, Snodin, Benedict, Ahuja, Janvi, Sandbrink, Jonas B., Monrad, Joshua Teperowski, Altman, George, Dhaliwal, Gurpreet, Finnveden, Lukas, Norman, Alexander John, Oehm, Sebastian B., Sandkühler, Julia Fabienne, Aitchison, Laurence, Gavenčiak, Tomáš, Mellan, Thomas, Kulveit, Jan, Chindelevitch, Leonid, Flaxman, Seth, Gal, Yarin, Mishra, Swapnil, Bhatt, Samir, and Brauner, Jan Markus

Published

2021

15. Effectiveness assessment of non-pharmaceutical interventions: lessons learned from the COVID-19 pandemic

Author

Lison, Adrian, primary, Banholzer, Nicolas, additional, Sharma, Mrinank, additional, Mindermann, Sören, additional, Unwin, H Juliette T, additional, Mishra, Swapnil, additional, Stadler, Tanja, additional, Bhatt, Samir, additional, Ferguson, Neil M, additional, Brauner, Jan, additional, and Vach, Werner, additional

Published

2023

16. Effectiveness assessment of non-pharmaceutical interventions:lessons learned from the COVID-19 pandemic

Author

Lison, Adrian, Banholzer, Nicolas, Sharma, Mrinank, Mindermann, Sören, Unwin, H. Juliette T., Mishra, Swapnil, Stadler, Tanja, Bhatt, Samir, Ferguson, Neil M., Brauner, Jan, Vach, Werner, Lison, Adrian, Banholzer, Nicolas, Sharma, Mrinank, Mindermann, Sören, Unwin, H. Juliette T., Mishra, Swapnil, Stadler, Tanja, Bhatt, Samir, Ferguson, Neil M., Brauner, Jan, and Vach, Werner

Abstract

Effectiveness of non-pharmaceutical interventions (NPIs), such as school closures and stay-at-home orders, during the COVID-19 pandemic has been assessed in many studies. Such assessments can inform public health policies and contribute to evidence-based choices of NPIs during subsequent waves or future epidemics. However, methodological issues and no standardised assessment practices have restricted the practical value of the existing evidence. Here, we present and discuss lessons learned from the COVID-19 pandemic and make recommendations for standardising and improving assessment, data collection, and modelling. These recommendations could contribute to reliable and policy-relevant assessments of the effectiveness of NPIs during future epidemics.

Published

2023

17. Seasonal variation in SARS-CoV-2 transmission in temperate climates: A Bayesian modelling study in 143 European regions

Author

Gavenčiak, Tomáš, primary, Monrad, Joshua Teperowski, additional, Leech, Gavin, additional, Sharma, Mrinank, additional, Mindermann, Sören, additional, Bhatt, Samir, additional, Brauner, Jan, additional, and Kulveit, Jan, additional

Published

2022

18. Mask wearing in community settings reduces SARS-CoV-2 transmission

Author

Leech, Gavin, Rogers-Smith, Charlie, Monrad, Joshua Teperowski, Sandbrink, Jonas B., Snodin, Benedict, Zinkov, Robert, Rader, Benjamin, Brownstein, John S., Gal, Yarin, Bhatt, Samir, Sharma, Mrinank, Mindermann, Sören, Brauner, Jan M., Aitchison, Laurence, Leech, Gavin, Rogers-Smith, Charlie, Monrad, Joshua Teperowski, Sandbrink, Jonas B., Snodin, Benedict, Zinkov, Robert, Rader, Benjamin, Brownstein, John S., Gal, Yarin, Bhatt, Samir, Sharma, Mrinank, Mindermann, Sören, Brauner, Jan M., and Aitchison, Laurence

Abstract

The effectiveness of mask wearing at controlling severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) transmission has been unclear. While masks are known to substantially reduce disease transmission in healthcare settings [D. K. Chu et al., Lancet 395, 1973–1987 (2020); J. Howard et al., Proc. Natl. Acad. Sci. U.S.A. 118, e2014564118 (2021); Y. Cheng et al., Science eabg6296 (2021)], studies in community settings report inconsistent results [H. M. Ollila et al., medRxiv (2020); J. Brainard et al., Eurosurveillance 25, 2000725 (2020); T. Jefferson et al., Cochrane Database Syst. Rev. 11, CD006207 (2020)]. Most such studies focus on how masks impact transmission, by analyzing how effective government mask mandates are. However, we find that widespread voluntary mask wearing, and other data limitations, make mandate effectiveness a poor proxy for mask-wearing effectiveness. We directly analyze the effect of mask wearing on SARS-CoV-2 transmission, drawing on several datasets covering 92 regions on six continents, including the largest survey of wearing behavior (n= 20 million) [F. Kreuter et al., https://gisumd.github.io/COVID-19-API-Documentation (2020)]. Using a Bayesian hierarchical model, we estimate the effect of mask wearing on transmission, by linking reported wearing levels to reported cases in each region, while adjusting for mobility and nonpharmaceutical interventions (NPIs), such as bans on large gatherings. Our estimates imply that the mean observed level of mask wearing corresponds to a 19% decrease in the reproduction number R. We also assess the robustness of our results in 60 tests spanning 20 sensitivity analyses. In light of these results, policy makers can effectively reduce transmission by intervening to increase mask wearing., The effectiveness of mask wearing at controlling severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) transmission has been unclear. While masks are known to substantially reduce disease transmission in healthcare settings [D. K. Chu et al., Lancet 395, 1973–1987 (2020); J. Howard et al., Proc. Natl. Acad. Sci. U.S.A. 118, e2014564118 (2021); Y. Cheng et al., Science eabg6296 (2021)], studies in community settings report inconsistent results [H. M. Ollila et al., medRxiv (2020); J. Brainard et al., Eurosurveillance 25, 2000725 (2020); T. Jefferson et al., Cochrane Database Syst. Rev. 11, CD006207 (2020)]. Most such studies focus on how masks impact transmission, by analyzing how effective government mask mandates are. However, we find that widespread voluntary mask wearing, and other data limitations, make mandate effectiveness a poor proxy for mask-wearing effectiveness. We directly analyze the effect of mask wearing on SARS-CoV-2 transmission, drawing on several datasets covering 92 regions on six continents, including the largest survey of wearing behavior (n = 20 million) [F. Kreuter et al., https://gisumd.github.io/COVID-19-API-Documentation (2020)]. Using a Bayesian hierarchical model, we estimate the effect of mask wearing on transmission, by linking reported wearing levels to reported cases in each region, while adjusting for mobility and nonpharmaceutical interventions (NPIs), such as bans on large gatherings. Our estimates imply that the mean observed level of mask wearing corresponds to a 19% decrease in the reproduction number R. We also assess the robustness of our results in 60 tests spanning 20 sensitivity analyses. In light of these results, policy makers can effectively reduce transmission by intervening to increase mask wearing.

Published

2022

19. Seasonal variation in SARS-CoV-2 transmission in temperate climates:A Bayesian modelling study in 143 European regions

Author

Gavenciak, Tomas, Monrad, Joshua Teperowski, Leech, Gavin, Sharma, Mrinank, Mindermann, Soren, Bhatt, Samir, Brauner, Jan, Kulveit, Jan, Gavenciak, Tomas, Monrad, Joshua Teperowski, Leech, Gavin, Sharma, Mrinank, Mindermann, Soren, Bhatt, Samir, Brauner, Jan, and Kulveit, Jan

Abstract

Although seasonal variation has a known influence on the transmission of several respiratory viral infections, its role in SARS-CoV-2 transmission remains unclear. While there is a sizable and growing literature on environmental drivers of COVID-19 transmission, recent reviews have highlighted conflicting and inconclusive findings. This indeterminacy partly owes to the fact that seasonal variation relates to viral transmission by a complicated web of causal pathways, including many interacting biological and behavioural factors. Since analyses of specific factors cannot determine the aggregate strength of seasonal forcing, we sidestep the challenge of disentangling various possible causal paths in favor of a holistic approach. We model seasonality as a sinusoidal variation in transmission and infer a single Bayesian estimate of the overall seasonal effect. By extending two state-of-the-art models of non-pharmaceutical intervention (NPI) effects and their datasets covering 143 regions in temperate Europe, we are able to adjust our estimates for the role of both NPIs and mobility patterns in reducing transmission. We find strong seasonal patterns, consistent with a reduction in the time-varying reproduction number R(t) (the expected number of new infections generated by an infectious individual at time t) of 42.1% (95% CI: 24.7%—53.4%) from the peak of winter to the peak of summer. These results imply that the seasonality of SARS-CoV-2 transmission is comparable in magnitude to the most effective individual NPIs but less than the combined effect of multiple interventions., Although seasonal variation has a known influence on the transmission of several respiratory viral infections, its role in SARS-CoV-2 transmission remains unclear. While there is a sizable and growing literature on environmental drivers of COVID-19 transmission, recent reviews have highlighted conflicting and inconclusive findings. This indeterminacy partly owes to the fact that seasonal variation relates to viral transmission by a complicated web of causal pathways, including many interacting biological and behavioural factors. Since analyses of specific factors cannot determine the aggregate strength of seasonal forcing, we sidestep the challenge of disentangling various possible causal paths in favor of a holistic approach. We model seasonality as a sinusoidal variation in transmission and infer a single Bayesian estimate of the overall seasonal effect. By extending two state-of-the-art models of non-pharmaceutical intervention (NPI) effects and their datasets covering 143 regions in temperate Europe, we are able to adjust our estimates for the role of both NPIs and mobility patterns in reducing transmission. We find strong seasonal patterns, consistent with a reduction in the time-varying reproduction number R(t) (the expected number of new infections generated by an infectious individual at time t) of 42.1% (95% CI: 24.7%-53.4%) from the peak of winter to the peak of summer. These results imply that the seasonality of SARS-CoV-2 transmission is comparable in magnitude to the most effective individual NPIs but less than the combined effect of multiple interventions.

Published

2022

20. Mask wearing in community settings reduces SARS-CoV-2 transmission

Author

Leech, Gavin, primary, Rogers-Smith, Charlie, additional, Monrad, Joshua Teperowski, additional, Sandbrink, Jonas B., additional, Snodin, Benedict, additional, Zinkov, Robert, additional, Rader, Benjamin, additional, Brownstein, John S., additional, Gal, Yarin, additional, Bhatt, Samir, additional, Sharma, Mrinank, additional, Mindermann, Sören, additional, Brauner, Jan M., additional, and Aitchison, Laurence, additional

Published

2022

21. Is the cure really worse than the disease? The health impacts of lockdowns during COVID-19

Author

Meyerowitz-Katz, Gideon, primary, Bhatt, Samir, additional, Ratmann, Oliver, additional, Brauner, Jan Markus, additional, Flaxman, Seth, additional, Mishra, Swapnil, additional, Sharma, Mrinank, additional, Mindermann, Sören, additional, Bradley, Valerie, additional, Vollmer, Michaela, additional, Merone, Lea, additional, and Yamey, Gavin, additional

Published

2021

22. Mass mask-wearing notably reduces COVID-19 transmission

Author

Leech, Gavin, primary, Rogers-Smith, Charlie, additional, Sandbrink, Jonas B., additional, Snodin, Benedict, additional, Zinkov, Robert, additional, Rader, Benjamin, additional, Brownstein, John S., additional, Gal, Yarin, additional, Bhatt, Samir, additional, Sharma, Mrinank, additional, Mindermann, Sören, additional, Brauner, Jan M., additional, and Aitchison, Laurence, additional

Published

2021

23. Seasonal variation in SARS-CoV-2 transmission in temperate climates

Author

Gavenčiak, Tomáš, primary, Monrad, Joshua Teperowski, additional, Leech, Gavin, additional, Sharma, Mrinank, additional, Mindermann, Sören, additional, Brauner, Jan Markus, additional, Bhatt, Samir, additional, and Kulveit, Jan, additional

Published

2021

24. Is the cure really worse than the disease? The health impacts of lockdowns during COVID-19

Author

Meyerowitz-Katz, Gideon, Bhatt, Samir, Ratmann, Oliver, Brauner, Jan Markus, Flaxman, Seth, Mishra, Swapnil, Sharma, Mrinank, Mindermann, Søren, Bradley, Valerie, Vollmer, Michaela, Merone, Lea, Yamey, Gavin, Meyerowitz-Katz, Gideon, Bhatt, Samir, Ratmann, Oliver, Brauner, Jan Markus, Flaxman, Seth, Mishra, Swapnil, Sharma, Mrinank, Mindermann, Søren, Bradley, Valerie, Vollmer, Michaela, Merone, Lea, and Yamey, Gavin

Published

2021

25. Understanding the effectiveness of government interventions in Europe’s second wave of COVID-19

Author

Sharma, Mrinank, primary, Mindermann, Sören, additional, Rogers-Smith, Charlie, additional, Leech, Gavin, additional, Snodin, Benedict, additional, Ahuja, Janvi, additional, Sandbrink, Jonas B., additional, Monrad, Joshua Teperowski, additional, Altman, George, additional, Dhaliwal, Gurpreet, additional, Finnveden, Lukas, additional, Norman, Alexander John, additional, Oehm, Sebastian B., additional, Sandkühler, Julia Fabienne, additional, Mellan, Thomas, additional, Kulveit, Jan, additional, Chindelevitch, Leonid, additional, Flaxman, Seth, additional, Gal, Yarin, additional, Mishra, Swapnil, additional, Brauner, Jan Markus, additional, and Bhatt, Samir, additional

Published

2021

26. The effectiveness and perceived burden of nonpharmaceutical interventions against COVID-19 transmission:a modelling study with 41 countries

Author

Brauner, Jan Markus, Mindermann, Soren, Sharma, Mrinank, Stephenson, Anna, Gavenciak, Tomas, Johnston, David W, Salvatier, John, Leech, Gavin, Besiroglu, Tamay, Altman, George, Ge, Hong, Mikulik, Vladamir, Hartwick, Meghan, Whye Teh, Yee, Chindelevitch, Leonid, Gal, Yarin, and Kulveit, Jan

Subjects

Covid19, Interactive Artificial Intelligence CDT

Abstract

Background: Existing analyses of nonpharmaceutical interventions (NPIs) against COVID19 transmission have focussed on the joint effectiveness of large-scale NPIs. With increasing data, we can move beyond estimating aggregate effects, to understanding the effects of individual interventions. In addition to effectiveness, policy decisions ought to reflect the burden different NPIs put on the population. Methods: To our knowledge, this is the largest data-driven study of NPI effectiveness to date. We collected chronological data on 9 NPIs in 41 countries between January and April 2020, using extensive fact-checking to ensure high data quality. We infer NPI effectiveness with a novel semi-mechanistic Bayesian hierarchical model, modelling both confirmed cases and deaths to increase the signal from which NPI effects can be inferred. Finally, we study the burden imposed by different NPIs with an online survey of preferences using the MaxDiff method. Results: Six NPIs had a >97.5% posterior probability of being effective: closing schools (mean reduction in R: 58%; 95% credible interval: 50% - 64%), limiting gatherings to 10 people or less (24%; 6% - 39%), closing nonessential businesses (23%; 5% - 38%), closing high-risk businesses (19%; 1% - 34%), testing patients with respiratory symptoms (18%; 8% - 26%), and stay-at-home orders (17%; 5% - 28%). These results show low sensitivity to 12 forms of varying the model and the data. The model makes sensible forecasts for countries and periods not seen during training. We combine the effectiveness and preference results to estimate effectiveness-to-burden ratios. Conclusions: Our results suggest a surprisingly large role for schools in COVID-19 transmission, a contribution to the ongoing debate about the relevance of asymptomatic carriers in disease spreading. We identify additional interventions with good effectiveness-burden tradeoffs, namely symptomatic testing, closing high-risk businesses, and limiting gathering size. Closing most nonessential businesses and issuing stay-at-home orders impose a high burden while having a limited additional effect.

Published

2020

27. Inferring the effectiveness of government interventions against COVID-19

Author

Brauner, Jan M., primary, Mindermann, Sören, additional, Sharma, Mrinank, additional, Johnston, David, additional, Salvatier, John, additional, Gavenčiak, Tomáš, additional, Stephenson, Anna B., additional, Leech, Gavin, additional, Altman, George, additional, Mikulik, Vladimir, additional, Norman, Alexander John, additional, Monrad, Joshua Teperowski, additional, Besiroglu, Tamay, additional, Ge, Hong, additional, Hartwick, Meghan A., additional, Teh, Yee Whye, additional, Chindelevitch, Leonid, additional, Gal, Yarin, additional, and Kulveit, Jan, additional

Published

2021

28. The effectiveness of eight nonpharmaceutical interventions against COVID-19 in 41 countries

Author

Brauner, Jan M., primary, Mindermann, Sören, additional, Sharma, Mrinank, additional, Stephenson, Anna B., additional, Gavenčiak, Tomáš, additional, Johnston, David, additional, Leech, Gavin, additional, Salvatier, John, additional, Altman, George, additional, Norman, Alexander John, additional, Monrad, Joshua Teperowski, additional, Besiroglu, Tamay, additional, Ge, Hong, additional, Mikulik, Vladimir, additional, Hartwick, Meghan A., additional, Teh, Yee Whye, additional, Chindelevitch, Leonid, additional, Gal, Yarin, additional, and Kulveit, Jan, additional

Published

2020

29. Seasonal variation in SARS-CoV-2 transmission in temperate climates: a Bayesian modelling study in 143 European regions

Author

Gavenčiak, Tomáš, Monrad, Joshua Teperowski, Leech, Gavin, Sharma, Mrinank, Mindermann, Sören, Bhatt, Samir, Brauner, Jan, Kulveit, Jan, Gavenčiak, Tomáš, Monrad, Joshua Teperowski, Leech, Gavin, Sharma, Mrinank, Mindermann, Sören, Bhatt, Samir, Brauner, Jan, and Kulveit, Jan

Abstract

Although seasonal variation has a known influence on the transmission of several respiratory viral infections, its role in SARS-CoV-2 transmission remains unclear. While there is a sizable and growing literature on environmental drivers of COVID-19 transmission, recent reviews have highlighted conflicting and inconclusive findings. This indeterminacy partly owes to the fact that seasonal variation relates to viral transmission by a complicated web of causal pathways, including many interacting biological and behavioural factors. Since analyses of specific factors cannot determine the aggregate strength of seasonal forcing, we sidestep the challenge of disentangling various possible causal paths in favor of a holistic approach. We model seasonality as a sinusoidal variation in transmission and infer a single Bayesian estimate of the overall seasonal effect. By extending two state-of-the-art models of non-pharmaceutical intervention (NPI) effects and their datasets covering 143 regions in temperate Europe, we are able to adjust our estimates for the role of both NPIs and mobility patterns in reducing transmission. We find strong seasonal patterns, consistent with a reduction in the time-varying reproduction number R(t) (the expected number of new infections generated by an infectious individual at time t) of 42.1% (95% CI: 24.7%—53.4%) from the peak of winter to the peak of summer. These results imply that the seasonality of SARSCoV-2 transmission is comparable in magnitude to the most effective individual NPIs but less than the combined effect of multiple interventions.

30. A dataset of non-pharmaceutical interventions on SARS-CoV-2 in Europe

Author

Altman, George, Ahuja, Janvi, Monrad, Joshua Teperowski, Dhaliwal, Gurpreet, Rogers-Smith, Charlie, Leech, Gavin, Snodin, Benedict, Sandbrink, Jonas B., Finnveden, Lukas, Norman, Alexander John, Oehm, Sebastian B., Sandkühler, Julia Fabienne, Kulveit, Jan, Flaxman, Seth, Gal, Yarin, Mishra, Swapnil, Bhatt, Samir, Sharma, Mrinank, Mindermann, Sören, Brauner, Jan Markus, Altman, George, Ahuja, Janvi, Monrad, Joshua Teperowski, Dhaliwal, Gurpreet, Rogers-Smith, Charlie, Leech, Gavin, Snodin, Benedict, Sandbrink, Jonas B., Finnveden, Lukas, Norman, Alexander John, Oehm, Sebastian B., Sandkühler, Julia Fabienne, Kulveit, Jan, Flaxman, Seth, Gal, Yarin, Mishra, Swapnil, Bhatt, Samir, Sharma, Mrinank, Mindermann, Sören, and Brauner, Jan Markus

Abstract

During the second half of 2020, many European governments responded to the resurging transmission of SARS-CoV-2 with wide-ranging non-pharmaceutical interventions (NPIs). These efforts were often highly targeted at the regional level and included fine-grained NPIs. This paper describes a new dataset designed for the accurate recording of NPIs in Europe’s second wave to allow precise modelling of NPI effectiveness. The dataset includes interventions from 114 regions in 7 European countries during the period from the 1st August 2020 to the 9th January 2021. The paper includes NPI definitions tailored to the second wave following an exploratory data collection. Each entry has been extensively validated by semi-independent double entry, comparison with existing datasets, and, when necessary, discussion with local epidemiologists. The dataset has considerable potential for use in disentangling the effectiveness of NPIs and comparing the impact of interventions across different phases of the pandemic.

31. Understanding the effectiveness of government interventions against the resurgence of COVID-19 in Europe

Author

Sharma, Mrinank, Mindermann, Sören, Rogers-Smith, Charlie, Leech, Gavin, Snodin, Benedict, Ahuja, Janvi, Sandbrink, Jonas B., Monrad, Joshua Teperowski, Altman, George, Dhaliwal, Gurpreet, Finnveden, Lukas, Norman, Alexander John, Oehm, Sebastian B., Sandkühler, Julia Fabienne, Aitchison, Laurence, Gavenčiak, Tomáš, Mellan, Thomas, Kulveit, Jan, Chindelevitch, Leonid, Flaxman, Seth, Gal, Yarin, Mishra, Swapnil, Bhatt, Samir, Brauner, Jan Markus, Sharma, Mrinank, Mindermann, Sören, Rogers-Smith, Charlie, Leech, Gavin, Snodin, Benedict, Ahuja, Janvi, Sandbrink, Jonas B., Monrad, Joshua Teperowski, Altman, George, Dhaliwal, Gurpreet, Finnveden, Lukas, Norman, Alexander John, Oehm, Sebastian B., Sandkühler, Julia Fabienne, Aitchison, Laurence, Gavenčiak, Tomáš, Mellan, Thomas, Kulveit, Jan, Chindelevitch, Leonid, Flaxman, Seth, Gal, Yarin, Mishra, Swapnil, Bhatt, Samir, and Brauner, Jan Markus

Abstract

European governments use non-pharmaceutical interventions (NPIs) to control resurging waves of COVID-19. However, they only have outdated estimates for how effective individual NPIs were in the first wave. We estimate the effectiveness of 17 NPIs in Europe’s second wave from subnational case and death data by introducing a flexible hierarchical Bayesian transmission model and collecting the largest dataset of NPI implementation dates across Europe. Business closures, educational institution closures, and gathering bans reduced transmission, but reduced it less than they did in the first wave. This difference is likely due to organisational safety measures and individual protective behaviours—such as distancing—which made various areas of public life safer and thereby reduced the effect of closing them. Specifically, we find smaller effects for closing educational institutions, suggesting that stringent safety measures made schools safer compared to the first wave. Second-wave estimates outperform previous estimates at predicting transmission in Europe’s third wave.

32. Inferring the effectiveness of government interventions against COVID-19

Author

Brauner, Jan M., Mindermann, Sören, Sharma, Mrinank, Johnston, David, Salvatier, John, Gavenčiak, Tomáš, Stephenson, Anna B., Leech, Gavin, Altman, George, Mikulik, Vladimir, Norman, Alexander John, Monrad, Joshua Teperowski, Besiroglu, Tamay, Ge, Hong, Hartwick, Meghan A., Teh, Yee Whye, Chindelevitch, Leonid, Gal, Yarin, Kulveit, Jan, Brauner, Jan M., Mindermann, Sören, Sharma, Mrinank, Johnston, David, Salvatier, John, Gavenčiak, Tomáš, Stephenson, Anna B., Leech, Gavin, Altman, George, Mikulik, Vladimir, Norman, Alexander John, Monrad, Joshua Teperowski, Besiroglu, Tamay, Ge, Hong, Hartwick, Meghan A., Teh, Yee Whye, Chindelevitch, Leonid, Gal, Yarin, and Kulveit, Jan

Abstract

Governments are attempting to control the COVID-19 pandemic with nonpharmaceutical interventions (NPIs). However, the effectiveness of different NPIs at reducing transmission is poorly understood. We gathered chronological data on the implementation of NPIs for several European and non-European countries between January and the end of May 2020. We estimated the effectiveness of these NPIs, which range from limiting gathering sizes and closing businesses or educational institutions to stay-at-home orders. To do so, we used a Bayesian hierarchical model that links NPI implementation dates to national case and death counts and supported the results with extensive empirical validation. Closing all educational institutions, limiting gatherings to 10 people or less, and closing face-to-face businesses each reduced transmission considerably. The additional effect of stay-at-home orders was comparatively small.

33. Understanding the effectiveness of government interventions against the resurgence of COVID-19 in Europe

Author

Joshua Teperowski Monrad, Lukas Finnveden, Charlie Rogers-Smith, Julia Fabienne Sandkühler, Thomas A. Mellan, Janvi Ahuja, Jan Markus Brauner, Mrinank Sharma, Seth Flaxman, Gavin Leech, Gurpreet Dhaliwal, Jan Kulveit, Sören Mindermann, Yarin Gal, Sebastian B. Oehm, Laurence Aitchison, Benedict E. K. Snodin, Samir Bhatt, George T. Altman, Jonas B. Sandbrink, Leonid Chindelevitch, Swapnil Mishra, Tomáš Gavenčiak, Alexander John Norman, Sharma, Mrinank [0000-0002-4304-7963], Mindermann, Sören [0000-0002-0315-9821], Leech, Gavin [0000-0002-9298-1488], Monrad, Joshua Teperowski [0000-0002-7377-2074], Oehm, Sebastian B [0000-0002-7099-0578], Flaxman, Seth [0000-0002-2477-4217], Gal, Yarin [0000-0002-2733-2078], Mishra, Swapnil [0000-0002-8759-5902], Bhatt, Samir [0000-0002-0891-4611], Brauner, Jan Markus [0000-0002-1588-5724], Apollo - University of Cambridge Repository, Medical Research Council (MRC), Imperial College Healthcare NHS Trust- BRC Funding, The Academy of Medical Sciences, National Institute for Health Research, UK Research and Innovation, and Oehm, Sebastian B. [0000-0002-7099-0578]

Subjects

141, Time Factors, Coronavirus disease 2019 (COVID-19), Epidemiology, Science, media_common.quotation_subject, Control (management), Psychological intervention, Basic Reproduction Number, General Physics and Astronomy, HM, Educational institution, HV Social pathology. Social and public welfare. Criminology, General Biochemistry, Genetics and Molecular Biology, RA0421 Public health. Hygiene. Preventive Medicine, SAFER, Humans, 692/308/174, media_common, Government, Science & Technology, Multidisciplinary, Public economics, SARS-CoV-2, Closing (real estate), article, COVID-19, General Chemistry, Wirtschaftswissenschaften, JN Political institutions (Europe), Models, Theoretical, Public life, 692/700/478/174, Interactive Artificial Intelligence CDT, Multidisciplinary Sciences, MODEL, Europe, Science & Technology - Other Topics, Business, 119, RA

Abstract

Funder: European and Developing Countries Clinical Trials Partnership (EDCTP); doi: https://doi.org/10.13039/501100001713, Funder: MRC Centre for Global Infectious Disease Analysis (MR/R015600/1), jointly funded by the U.K. Medical Research Council (MRC) and the U.K. Foreign, Commonwealth and Development Office (FCDO), under the MRC/FCDO Concordat agreement. Community Jameel. The UK Research and Innovation (MR/V038109/1), the Academy of Medical Sciences Springboard Award (SBF004/1080), The MRC (MR/R015600/1), The BMGF (OPP1197730), Imperial College Healthcare NHS Trust- BRC Funding (RDA02), The Novo Nordisk Young Investigator Award (NNF20OC0059309) and The NIHR Health Protection Research Unit in Modelling Methodology. S. Bhatt thanks Microsoft AI for Health and Amazon AWS for computational credits., Funder: EA Funds, Funder: University of Oxford (Oxford University); doi: https://doi.org/10.13039/501100000769, Funder: DeepMind, Funder: OpenPhilanthropy, Funder: UKRI Centre for Doctoral Training in Interactive Artificial Intelligence (EP/S022937/1), Funder: Augustinus Fonden (Augustinus Foundation); doi: https://doi.org/10.13039/501100004954, Funder: Knud Højgaards Fond (Knud Højgaard Fund); doi: https://doi.org/10.13039/501100009938, Funder: Kai Lange og Gunhild Kai Langes Fond (Kai Lange and Gunhild Kai Lange Foundation); doi: https://doi.org/10.13039/501100008206, Funder: Aage og Johanne Louis-Hansens Fond (Aage and Johanne Louis-Hansen Foundation); doi: https://doi.org/10.13039/501100010344, Funder: William Demant Foundation, Funder: Boehringer Ingelheim Fonds (Stiftung für medizinische Grundlagenforschung); doi: https://doi.org/10.13039/501100001645, Funder: Imperial College COVID-19 Research Fund, Funder: Cancer Research UK (CRUK); doi: https://doi.org/10.13039/501100000289, European governments use non-pharmaceutical interventions (NPIs) to control resurging waves of COVID-19. However, they only have outdated estimates for how effective individual NPIs were in the first wave. We estimate the effectiveness of 17 NPIs in Europe’s second wave from subnational case and death data by introducing a flexible hierarchical Bayesian transmission model and collecting the largest dataset of NPI implementation dates across Europe. Business closures, educational institution closures, and gathering bans reduced transmission, but reduced it less than they did in the first wave. This difference is likely due to organisational safety measures and individual protective behaviours—such as distancing—which made various areas of public life safer and thereby reduced the effect of closing them. Specifically, we find smaller effects for closing educational institutions, suggesting that stringent safety measures made schools safer compared to the first wave. Second-wave estimates outperform previous estimates at predicting transmission in Europe’s third wave.

Published

2021