Yahya Sattar scite author profile

Yahya Sattar

5Publications

52Citation Statements Received

229Citation Statements Given

How they've been cited

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138

229

Affiliations

University of California, Riverside, Lahore University of Management Sciences

Publications

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Non-asymptotic and Accurate Learning of Nonlinear Dynamical Systems

Sattar¹,

Oymak²

2020

Preprint

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We consider the problem of learning stabilizable systems governed by nonlinear state equation ht+1 = φ(ht, ut; θ) + wt. Here θ is the unknown system dynamics, ht is the state, ut is the input and wt is the additive noise vector. We study gradient based algorithms to learn the system dynamics θ from samples obtained from a single finite trajectory. If the system is run by a stabilizing input policy, we show that temporally-dependent samples can be approximated by i.i.d. samples via a truncation argument by using mixing-time arguments. We then develop new guarantees for the uniform convergence of the gradients of empirical loss. Unlike existing works, our bounds are noise sensitive which allows for learning ground-truth dynamics with high accuracy and small sample complexity. Together, our results facilitate efficient learning of the general nonlinear system under stabilizing policy. We specialize our guarantees to entrywise nonlinear activations and verify our theory in various numerical experiments.

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Identification and Adaptive Control of Markov Jump Systems: Sample Complexity and Regret Bounds

Sattar¹,

Du²,

Tarzanagh³

et al. 2021

Preprint

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Learning how to effectively control unknown dynamical systems is crucial for intelligent autonomous systems. This task becomes a significant challenge when the underlying dynamics are changing with time. Motivated by this challenge, this paper considers the problem of controlling an unknown Markov jump linear system (MJS) to optimize a quadratic objective. By taking a model-based perspective, we consider identification-based adaptive control for MJSs. We first provide a system identification algorithm for MJS to learn the dynamics in each mode as well as the Markov transition matrix, underlying the evolution of the mode switches, from a single trajectory of the system states, inputs, and modes. Through mixing-time arguments, sample complexity of this algorithm is shown to be O(1 √ T ). We then propose an adaptive control scheme that performs system identification together with certainty equivalent control to adapt the controllers in an episodic fashion. Combining our sample complexity results with recent perturbation results for certainty equivalent control, we prove that when the episode lengths are appropriately chosen, the proposed adaptive control scheme achieves O( √ T ) regret, which can be improved to O(polylog(T )) with partial knowledge of the system. Our proof strategy introduces innovations to handle Markovian jumps and a weaker notion of stability common in MJSs. Our analysis provides insights into system theoretic quantities that affect learning accuracy and control performance. Numerical simulations are presented to further reinforce these insights.

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Quickly Finding the Best Linear Model in High Dimensions via Projected Gradient Descent

Sattar

Oymak

2020

IEEE Trans. Signal Process.

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We study the problem of finding the best linear model that can minimize least-squares loss given a dataset. While this problem is trivial in the low-dimensional regime, it becomes more interesting in high-dimensions where the population minimizer is assumed to lie on a manifold such as sparse vectors. We propose projected gradient descent (PGD) algorithm to estimate the population minimizer in the finite sample regime. We establish linear convergence rate and data-dependent estimation error bounds for PGD. Our contributions include: 1) The results are established for heavier tailed sub-exponential distributions besides sub-gaussian. 2) We directly analyze the empirical risk minimization and do not require a realizable model that connects input data and labels. 3) Our PGD algorithm is augmented to learn the bias terms which boosts the performance. The numerical experiments validate our theoretical results.

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Certainty Equivalent Quadratic Control for Markov Jump Systems

Du¹,

Sattar²,

Tarzanagh³

et al. 2021

Preprint

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Real-world control applications often involve complex dynamics subject to abrupt changes or variations. Markov jump linear systems (MJS) provide a rich framework for modeling such dynamics. Despite an extensive history, theoretical understanding of parameter sensitivities of MJS control is somewhat lacking. Motivated by this, we investigate robustness aspects of certainty equivalent model-based optimal control for MJS with quadratic cost function. Given the uncertainty in the system matrices and in the Markov transition matrix is bounded by and η respectively, robustness results are established for (i) the solution to coupled Riccati equations and (ii) the optimal cost, by providing explicit perturbation bounds which decay as O( + η) and O(( + η) 2 ) respectively.

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Exploring Weight Importance and Hessian Bias in Model Pruning

Li¹,

Sattar²,

Thrampoulidis³

et al. 2020

Preprint

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Model pruning is an essential procedure for building compact and computationally-efficient machine learning models. A key feature of a good pruning algorithm is that it accurately quantifies the relative importance of the model weights. While model pruning has a rich history, we still don't have a full grasp of the pruning mechanics even for relatively simple problems involving linear models or shallow neural nets. In this work, we provide a principled exploration of pruning by building on a natural notion of importance. For linear models, we show that this notion of importance is captured by covariance scaling which connects to the well-known Hessian-based pruning. We then derive asymptotic formulas that allow us to precisely compare the performance of different pruning methods. For neural networks, we demonstrate that the importance can be at odds with larger magnitudes and proper initialization is critical for magnitude-based pruning. Specifically, we identify settings in which weights become more important despite becoming smaller, which in turn leads to a catastrophic failure of magnitude-based pruning. Our results also elucidate that implicit regularization in the form of Hessian structure has a catalytic role in identifying the important weights, which dictate the pruning performance.

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Yahya Sattar

Non-asymptotic and Accurate Learning of Nonlinear Dynamical Systems

Identification and Adaptive Control of Markov Jump Systems: Sample Complexity and Regret Bounds

Quickly Finding the Best Linear Model in High Dimensions via Projected Gradient Descent

Certainty Equivalent Quadratic Control for Markov Jump Systems

Exploring Weight Importance and Hessian Bias in Model Pruning

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