Your search keyword '"Dwivedi, Raaz"' showing total 13 results

1. Did we personalize? Assessing personalization by an online reinforcement learning algorithm using resampling

Author

Ghosh, Susobhan, Kim, Raphael, Chhabria, Prasidh, Dwivedi, Raaz, Klasnja, Predrag, Liao, Peng, Zhang, Kelly, and Murphy, Susan

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Applications (stat.AP), Machine Learning (stat.ML), Statistics - Applications, Statistics - Methodology, Machine Learning (cs.LG)

Abstract

There is a growing interest in using reinforcement learning (RL) to personalize sequences of treatments in digital health to support users in adopting healthier behaviors. Such sequential decision-making problems involve decisions about when to treat and how to treat based on the user's context (e.g., prior activity level, location, etc.). Online RL is a promising data-driven approach for this problem as it learns based on each user's historical responses and uses that knowledge to personalize these decisions. However, to decide whether the RL algorithm should be included in an ``optimized'' intervention for real-world deployment, we must assess the data evidence indicating that the RL algorithm is actually personalizing the treatments to its users. Due to the stochasticity in the RL algorithm, one may get a false impression that it is learning in certain states and using this learning to provide specific treatments. We use a working definition of personalization and introduce a resampling-based methodology for investigating whether the personalization exhibited by the RL algorithm is an artifact of the RL algorithm stochasticity. We illustrate our methodology with a case study by analyzing the data from a physical activity clinical trial called HeartSteps, which included the use of an online RL algorithm. We demonstrate how our approach enhances data-driven truth-in-advertising of algorithm personalization both across all users as well as within specific users in the study., The first two authors contributed equally

Published

2023

2. Compress Then Test: Powerful Kernel Testing in Near-linear Time

Author

Domingo-Enrich, Carles, Dwivedi, Raaz, and Mackey, Lester

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, FOS: Mathematics, Machine Learning (stat.ML), Mathematics - Statistics Theory, Statistics Theory (math.ST), Statistics - Methodology, Machine Learning (cs.LG)

Abstract

Kernel two-sample testing provides a powerful framework for distinguishing any pair of distributions based on $n$ sample points. However, existing kernel tests either run in $n^2$ time or sacrifice undue power to improve runtime. To address these shortcomings, we introduce Compress Then Test (CTT), a new framework for high-powered kernel testing based on sample compression. CTT cheaply approximates an expensive test by compressing each $n$ point sample into a small but provably high-fidelity coreset. For standard kernels and subexponential distributions, CTT inherits the statistical behavior of a quadratic-time test -- recovering the same optimal detection boundary -- while running in near-linear time. We couple these advances with cheaper permutation testing, justified by new power analyses; improved time-vs.-quality guarantees for low-rank approximation; and a fast aggregation procedure for identifying especially discriminating kernels. In our experiments with real and simulated data, CTT and its extensions provide 20--200x speed-ups over state-of-the-art approximate MMD tests with no loss of power., Accepted as a paper at AISTATS 2023

Published

2023

3. On counterfactual inference with unobserved confounding

Author

Shah, Abhin, Dwivedi, Raaz, Shah, Devavrat, and Wornell, Gregory W.

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Methodology, Machine Learning (cs.LG)

Abstract

Given an observational study with $n$ independent but heterogeneous units, our goal is to learn the counterfactual distribution for each unit using only one $p$-dimensional sample per unit containing covariates, interventions, and outcomes. Specifically, we allow for unobserved confounding that introduces statistical biases between interventions and outcomes as well as exacerbates the heterogeneity across units. Modeling the underlying joint distribution as an exponential family, we reduce learning the unit-level counterfactual distributions to learning $n$ exponential family distributions with heterogeneous parameters and only one sample per distribution. We introduce a convex objective that pools all $n$ samples to jointly learn all $n$ parameter vectors, and provide a unit-wise mean squared error bound that scales linearly with the metric entropy of the parameter space. For example, when the parameters are $s$-sparse linear combination of $k$ known vectors, the error is $O(s\log k/p)$. En route, we derive sufficient conditions for compactly supported distributions to satisfy the logarithmic Sobolev inequality. As an application of the framework, our results enable consistent imputation of sparsely missing covariates.

Published

2022

4. Counterfactual inference for sequential experiments

Author

Dwivedi, Raaz, Tian, Katherine, Tomkins, Sabina, Klasnja, Predrag, Murphy, Susan, and Shah, Devavrat

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Machine Learning (stat.ML), Machine Learning (cs.LG)

Abstract

We consider after-study statistical inference for sequentially designed experiments wherein multiple units are assigned treatments for multiple time points using treatment policies that adapt over time. Our goal is to provide inference guarantees for the counterfactual mean at the smallest possible scale -- mean outcome under different treatments for each unit and each time -- with minimal assumptions on the adaptive treatment policy. Without any structural assumptions on the counterfactual means, this challenging task is infeasible due to more unknowns than observed data points. To make progress, we introduce a latent factor model over the counterfactual means that serves as a non-parametric generalization of the non-linear mixed effects model and the bilinear latent factor model considered in prior works. For estimation, we use a non-parametric method, namely a variant of nearest neighbors, and establish a non-asymptotic high probability error bound for the counterfactual mean for each unit and each time. Under regularity conditions, this bound leads to asymptotically valid confidence intervals for the counterfactual mean as the number of units and time points grows to $\infty$ together at suitable rates. We illustrate our theory via several simulations and a case study involving data from a mobile health clinical trial HeartSteps.

Published

2022

5. Doubly robust nearest neighbors in factor models

Author

Dwivedi, Raaz, Tian, Katherine, Tomkins, Sabina, Klasnja, Predrag, Murphy, Susan, and Shah, Devavrat

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Machine Learning (stat.ML), Machine Learning (cs.LG)

Abstract

In this technical note, we introduce an improved variant of nearest neighbors for counterfactual inference in panel data settings where multiple units are assigned multiple treatments over multiple time points, each sampled with constant probabilities. We call this estimator a doubly robust nearest neighbor estimator and provide a high probability non-asymptotic error bound for the mean parameter corresponding to each unit at each time. Our guarantee shows that the doubly robust estimator provides a (near-)quadratic improvement in the error compared to nearest neighbor estimators analyzed in prior work for these settings.

Published

2022

6. Distribution Compression in Near-linear Time

Author

Shetty, Abhishek, Dwivedi, Raaz, and Mackey, Lester

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Computer Science - Data Structures and Algorithms, FOS: Mathematics, Machine Learning (stat.ML), Data Structures and Algorithms (cs.DS), Mathematics - Statistics Theory, Statistics Theory (math.ST), Statistics - Methodology, Machine Learning (cs.LG)

Abstract

In distribution compression, one aims to accurately summarize a probability distribution $\mathbb{P}$ using a small number of representative points. Near-optimal thinning procedures achieve this goal by sampling $n$ points from a Markov chain and identifying $\sqrt{n}$ points with $\widetilde{\mathcal{O}}(1/\sqrt{n})$ discrepancy to $\mathbb{P}$. Unfortunately, these algorithms suffer from quadratic or super-quadratic runtime in the sample size $n$. To address this deficiency, we introduce Compress++, a simple meta-procedure for speeding up any thinning algorithm while suffering at most a factor of $4$ in error. When combined with the quadratic-time kernel halving and kernel thinning algorithms of Dwivedi and Mackey (2021), Compress++ delivers $\sqrt{n}$ points with $\mathcal{O}(\sqrt{\log n/n})$ integration error and better-than-Monte-Carlo maximum mean discrepancy in $\mathcal{O}(n \log^3 n)$ time and $\mathcal{O}( \sqrt{n} \log^2 n )$ space. Moreover, Compress++ enjoys the same near-linear runtime given any quadratic-time input and reduces the runtime of super-quadratic algorithms by a square-root factor. In our benchmarks with high-dimensional Monte Carlo samples and Markov chains targeting challenging differential equation posteriors, Compress++ matches or nearly matches the accuracy of its input algorithm in orders of magnitude less time., Accepted to ICLR 2022; An outdated proof of Theorem 2 was previously included in the appendix; this oversight is corrected in this version

Published

2021

7. Generalized Kernel Thinning

Author

Dwivedi, Raaz and Mackey, Lester

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, FOS: Mathematics, Machine Learning (stat.ML), Mathematics - Statistics Theory, Statistics Theory (math.ST), Statistics - Methodology, Machine Learning (cs.LG)

Abstract

The kernel thinning (KT) algorithm of Dwivedi and Mackey (2021) compresses a probability distribution more effectively than independent sampling by targeting a reproducing kernel Hilbert space (RKHS) and leveraging a less smooth square-root kernel. Here we provide four improvements. First, we show that KT applied directly to the target RKHS yields tighter, dimension-free guarantees for any kernel, any distribution, and any fixed function in the RKHS. Second, we show that, for analytic kernels like Gaussian, inverse multiquadric, and sinc, target KT admits maximum mean discrepancy (MMD) guarantees comparable to or better than those of square-root KT without making explicit use of a square-root kernel. Third, we prove that KT with a fractional power kernel yields better-than-Monte-Carlo MMD guarantees for non-smooth kernels, like Laplace and Mat\'ern, that do not have square-roots. Fourth, we establish that KT applied to a sum of the target and power kernels (a procedure we call KT+) simultaneously inherits the improved MMD guarantees of power KT and the tighter individual function guarantees of target KT. In our experiments with target KT and KT+, we witness significant improvements in integration error even in $100$ dimensions and when compressing challenging differential equation posteriors., Comment: Published in ICLR 2022

Published

2021

8. Kernel Thinning

Author

Dwivedi, Raaz and Mackey, Lester

Subjects

Methodology (stat.ME), FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, FOS: Mathematics, Machine Learning (stat.ML), Mathematics - Statistics Theory, Statistics Theory (math.ST), Statistics - Computation, Computation (stat.CO), Statistics - Methodology, Machine Learning (cs.LG)

Abstract

We introduce kernel thinning, a new procedure for compressing a distribution $\mathbb{P}$ more effectively than i.i.d. sampling or standard thinning. Given a suitable reproducing kernel $\mathbf{k}_{\star}$ and $\mathcal{O}(n^2)$ time, kernel thinning compresses an $n$-point approximation to $\mathbb{P}$ into a $\sqrt{n}$-point approximation with comparable worst-case integration error across the associated reproducing kernel Hilbert space. The maximum discrepancy in integration error is $\mathcal{O}_d(n^{-1/2}\sqrt{\log n})$ in probability for compactly supported $\mathbb{P}$ and $\mathcal{O}_d(n^{-\frac{1}{2}} (\log n)^{(d+1)/2}\sqrt{\log\log n})$ for sub-exponential $\mathbb{P}$ on $\mathbb{R}^d$. In contrast, an equal-sized i.i.d. sample from $\mathbb{P}$ suffers $\Omega(n^{-1/4})$ integration error. Our sub-exponential guarantees resemble the classical quasi-Monte Carlo error rates for uniform $\mathbb{P}$ on $[0,1]^d$ but apply to general distributions on $\mathbb{R}^d$ and a wide range of common kernels. Moreover, the same construction delivers near-optimal $L^\infty$ coresets in $\mathcal O(n^2)$ time. We use our results to derive explicit non-asymptotic maximum mean discrepancy bounds for Gaussian, Mat\'ern, and B-spline kernels and present two vignettes illustrating the practical benefits of kernel thinning over i.i.d. sampling and standard Markov chain Monte Carlo thinning, in dimensions $d=2$ through $100$., Comment: Accepted for presentation as an extended abstract at the Conference on Learning Theory (COLT) 2021

Published

2021

9. Revisiting minimum description length complexity in overparameterized models

Author

Dwivedi, Raaz, Singh, Chandan, Yu, Bin, and Wainwright, Martin J.

Subjects

FOS: Computer and information sciences, Computer Science::Machine Learning, Computer Science - Machine Learning, Statistics - Machine Learning, Information Theory (cs.IT), Computer Science - Information Theory, FOS: Mathematics, Machine Learning (stat.ML), Mathematics - Statistics Theory, Statistics Theory (math.ST), Machine Learning (cs.LG)

Abstract

Complexity is a fundamental concept underlying statistical learning theory that aims to inform generalization performance. Parameter count, while successful in low-dimensional settings, is not well-justified for overparameterized settings when the number of parameters is more than the number of training samples. We revisit complexity measures based on Rissanen's principle of minimum description length (MDL) and define a novel MDL-based complexity (MDL-COMP) that remains valid for overparameterized models. MDL-COMP is defined via an optimality criterion over the encodings induced by a good Ridge estimator class. We provide an extensive theoretical characterization of MDL-COMP for linear models and kernel methods and show that it is not just a function of parameter count, but rather a function of the singular values of the design or the kernel matrix and the signal-to-noise ratio. For a linear model with $n$ observations, $d$ parameters, and i.i.d. Gaussian predictors, MDL-COMP scales linearly with $d$ when $dn$. For kernel methods, we show that MDL-COMP informs minimax in-sample error, and can decrease as the dimensionality of the input increases. We also prove that MDL-COMP upper bounds the in-sample mean squared error (MSE). Via an array of simulations and real-data experiments, we show that a data-driven Prac-MDL-COMP informs hyper-parameter tuning for optimizing test MSE with ridge regression in limited data settings, sometimes improving upon cross-validation and (always) saving computational costs. Finally, our findings also suggest that the recently observed double decent phenomenons in overparameterized models might be a consequence of the choice of non-ideal estimators., Comment: First two authors contributed equally

Published

2020

10. Instability, Computational Efficiency and Statistical Accuracy

Author

Ho, Nhat, Khamaru, Koulik, Dwivedi, Raaz, Wainwright, Martin J., Jordan, Michael I., and Yu, Bin

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, FOS: Mathematics, Machine Learning (stat.ML), Mathematics - Statistics Theory, Statistics Theory (math.ST), Machine Learning (cs.LG)

Abstract

Many statistical estimators are defined as the fixed point of a data-dependent operator, with estimators based on minimizing a cost function being an important special case. The limiting performance of such estimators depends on the properties of the population-level operator in the idealized limit of infinitely many samples. We develop a general framework that yields bounds on statistical accuracy based on the interplay between the deterministic convergence rate of the algorithm at the population level, and its degree of (in)stability when applied to an empirical object based on $n$ samples. Using this framework, we analyze both stable forms of gradient descent and some higher-order and unstable algorithms, including Newton's method and its cubic-regularized variant, as well as the EM algorithm. We provide applications of our general results to several concrete classes of models, including Gaussian mixture estimation, non-linear regression models, and informative non-response models. We exhibit cases in which an unstable algorithm can achieve the same statistical accuracy as a stable algorithm in exponentially fewer steps -- namely, with the number of iterations being reduced from polynomial to logarithmic in sample size $n$., 68 pages, 6 Figures, 2 Tables. First three authors contributed equally

Published

2020

11. Fast mixing of Metropolized Hamiltonian Monte Carlo: Benefits of multi-step gradients

Author

Chen, Yuansi, Dwivedi, Raaz, Wainwright, Martin J., and Yu, Bin

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Machine Learning (stat.ML), Statistics - Computation, Computation (stat.CO), Machine Learning (cs.LG)

Abstract

Hamiltonian Monte Carlo (HMC) is a state-of-the-art Markov chain Monte Carlo sampling algorithm for drawing samples from smooth probability densities over continuous spaces. We study the variant most widely used in practice, Metropolized HMC with the St\"{o}rmer-Verlet or leapfrog integrator, and make two primary contributions. First, we provide a non-asymptotic upper bound on the mixing time of the Metropolized HMC with explicit choices of step-size and number of leapfrog steps. This bound gives a precise quantification of the faster convergence of Metropolized HMC relative to simpler MCMC algorithms such as the Metropolized random walk, or Metropolized Langevin algorithm. Second, we provide a general framework for sharpening mixing time bounds of Markov chains initialized at a substantial distance from the target distribution over continuous spaces. We apply this sharpening device to the Metropolized random walk and Langevin algorithms, thereby obtaining improved mixing time bounds from a non-warm initial distribution., Comment: 73 pages, 2 figures, fixed a mistake in the proof of Lemma 11, accepted in JMLR

Published

2019

12. Sharp Analysis of Expectation-Maximization for Weakly Identifiable Models

Author

Dwivedi, Raaz, Ho, Nhat, Khamaru, Koulik, Wainwright, Martin J., Jordan, Michael I., and Yu, Bin

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, FOS: Mathematics, Mathematics - Statistics Theory, Machine Learning (stat.ML), Statistics Theory (math.ST), Machine Learning (cs.LG)

Abstract

We study a class of weakly identifiable location-scale mixture models for which the maximum likelihood estimates based on $n$ i.i.d. samples are known to have lower accuracy than the classical $n^{- \frac{1}{2}}$ error. We investigate whether the Expectation-Maximization (EM) algorithm also converges slowly for these models. We provide a rigorous characterization of EM for fitting a weakly identifiable Gaussian mixture in a univariate setting where we prove that the EM algorithm converges in order $n^{\frac{3}{4}}$ steps and returns estimates that are at a Euclidean distance of order ${ n^{- \frac{1}{8}}}$ and ${ n^{-\frac{1} {4}}}$ from the true location and scale parameter respectively. Establishing the slow rates in the univariate setting requires a novel localization argument with two stages, with each stage involving an epoch-based argument applied to a different surrogate EM operator at the population level. We demonstrate several multivariate ($d \geq 2$) examples that exhibit the same slow rates as the univariate case. We also prove slow statistical rates in higher dimensions in a special case, when the fitted covariance is constrained to be a multiple of the identity., Comment: 30 pages, 4 figures. The first three authors contributed equally to this work. To appear in AISTATS 2020

Published

2019

13. Log-concave sampling: Metropolis-Hastings algorithms are fast

Author

Dwivedi, Raaz, Chen, Yuansi, Wainwright, Martin J., and Yu, Bin

Subjects

FOS: Computer and information sciences, Statistics - Machine Learning, Machine Learning (stat.ML), Statistics - Computation, Computation (stat.CO), Statistics::Computation

Abstract

We consider the problem of sampling from a strongly log-concave density in $\mathbb{R}^d$, and prove a non-asymptotic upper bound on the mixing time of the Metropolis-adjusted Langevin algorithm (MALA). The method draws samples by simulating a Markov chain obtained from the discretization of an appropriate Langevin diffusion, combined with an accept-reject step. Relative to known guarantees for the unadjusted Langevin algorithm (ULA), our bounds show that the use of an accept-reject step in MALA leads to an exponentially improved dependence on the error-tolerance. Concretely, in order to obtain samples with TV error at most $\delta$ for a density with condition number $\kappa$, we show that MALA requires $\mathcal{O} \big(\kappa d \log(1/\delta) \big)$ steps, as compared to the $\mathcal{O} \big(\kappa^2 d/\delta^2 \big)$ steps established in past work on ULA. We also demonstrate the gains of MALA over ULA for weakly log-concave densities. Furthermore, we derive mixing time bounds for the Metropolized random walk (MRW) and obtain $\mathcal{O}(\kappa)$ mixing time slower than MALA. We provide numerical examples that support our theoretical findings, and demonstrate the benefits of Metropolis-Hastings adjustment for Langevin-type sampling algorithms., Comment: 42 pages, 11 Figures; The first two authors contributed equally; A subset of results were presented in an extended abstract at COLT 2018

Published

2018