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1. Weak-to-strong generalization through the data-centric lens

   Shin, Changho; Cooper, John; Sala, Frederic (April 2025, ICLR)

   The weak-to-strong generalization phenomenon is the driver for important machine learning applications including highly data-efficient learning and, most recently, performing superalignment. While decades of research have resulted in numerous algorithms that produce strong empirical performance, understanding what aspects of data enable weak-to-strong generalization has been understudied. We propose a simple data-centric mechanism that characterizes weak-to-strong generalization: the overlap density. Intuitively, generalization tracks the number of points that contain overlaps, i.e., both easy patterns (learnable by a weak model) and challenging patterns (only learnable by a stronger model), as with such points, weak predictions can be used to learn challenging patterns by stronger models. We provide a practical overlap detection algorithm to find such points in datasets and leverage them to learn, among multiple sources of data, which to query when seeking to maximize overlap density and thereby enhance weak-to-strong generalization. We present a theoretical result showing that the generalization benefit is a function of the overlap density and a regret bound for our data selection algorithm. Empirically, we validate the mechanism and the overlap detection algorithm on a wide array of settings. 

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2. The Delta Learning Hypothesis: Preference Tuning on Weak Data can Yield Strong Gains

   Geng, S; Ivison, H; Li, C_L; Sap, M; Li, J; Krishna, R; Koh, P W (July 2025, https://doi.org/10.48550/arXiv.2507.06187)

   Improvements in language models are often driven by improving the quality of the data we train them on, which can be limiting when strong supervision is scarce. In this work, we show that paired preference data consisting of individually weak data points can enable gains beyond the strength of each individual data point. We formulate the delta learning hypothesis to explain this phenomenon, positing that the relative quality delta between points suffices to drive learning via preference tuning--even when supervised finetuning on the weak data hurts. We validate our hypothesis in controlled experiments and at scale, where we post-train 8B models on preference data generated by pairing a small 3B model's responses with outputs from an even smaller 1.5B model to create a meaningful delta. Strikingly, on a standard 11-benchmark evaluation suite (MATH, MMLU, etc.), our simple recipe matches the performance of Tulu 3, a state-of-the-art open model tuned from the same base model while relying on much stronger supervisors (e.g., GPT-4o). Thus, delta learning enables simpler and cheaper open recipes for state-of-the-art post-training. To better understand delta learning, we prove in logistic regression that the performance gap between two weak teacher models provides useful signal for improving a stronger student. Overall, our work shows that models can learn surprisingly well from paired data that might typically be considered weak. 

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3. Nonlinear Stein Variational Gradient Descent for Learning Diversified Mixture Models

   Wang, Dilin; Liu, Qiang (July 2019, International conference of machine learning)

   Diversification has been shown to be a powerful mechanism for learning robust models in non- convex settings. A notable example is learning mixture models, in which enforcing diversity between the different mixture components allows us to prevent the model collapsing phenomenon and capture more patterns from the observed data. In this work, we present a variational approach for diversity-promoting learning, which leverages the entropy functional as a natural mechanism for enforcing diversity. We develop a simple and efficient functional gradient-based algorithm for optimizing the variational objective function, which provides a significant generalization of Stein variational gradient descent (SVGD). We test our method on various challenging real world problems, including deep embedded clustering and deep anomaly detection. Empirical results show that our method provides an effective mechanism for diversity-promoting learning, achieving substantial improvement over existing methods. 

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4. Weak Target Detection in MIMO Radar via Beamspace Canonical Correlation

   https://doi.org/10.1109/SAM48682.2020.9104284  

   Ibrahim, Mohamed Salah; Sidiropoulos, Nicholas D. (June 2020, 2020 IEEE International Workshop on Sensor Array and Multichannel Signal Processing (SAM 2020))

   Reliable detection and accurate estimation of weak targets and their Doppler frequencies is a challenging problem in MIMO radar systems. Reflections from such targets are often overpowered by those from stronger nearby targets and clutter. Considering a 3-D data model where the coherent processing interval comprises multiple pulses, a novel weak target detection and estimation approach is proposed in this paper. The proposed method is based on creating partially overlapping spatial beams, and performing canonical correlation analysis (CCA) in the resulting beamspace. It is shown that if a target is present in the overlap sector, then its Doppler profile can be reliably estimated via beamspace CCA, even if hidden under much stronger interference from nearby targets and clutter. Numerical results are included to validate this theoretical claim, demonstrating that the proposed Beamspace Canonical Correlation (BCC) method yields considerable performance improvement over existing approaches. 

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5. Non-stationary Domain Generalization: Theory and Algorithm

   Pham, TH; Zhang, X; Zhang, P (July 2024, OpenReview.net)

   Although recent advances in machine learning have shown its success to learn from independent and identically distributed (IID) data, it is vulnerable to out-of-distribution (OOD) data in an open world. Domain generalization (DG) deals with such an issue and it aims to learn a model from multiple source domains that can be generalized to unseen target domains. Existing studies on DG have largely focused on stationary settings with homogeneous source domains. However, in many applications, domains may evolve along a specific direction (e.g., time, space). Without accounting for such non-stationary patterns, models trained with existing methods may fail to generalize on OOD data. In this paper, we study domain generalization in non-stationary environment. We first examine the impact of environmental non-stationarity on model performance and establish the theoretical upper bounds for the model error at target domains. Then, we propose a novel algorithm based on adaptive invariant representation learning, which leverages the non-stationary pattern to train a model that attains good performance on target domains. Experiments on both synthetic and real data validate the proposed algorithm. 

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