AI-generated summaries

Today's ML research,
without the noise.

Daily summaries of the latest machine learning papers from arXiv, processed every 8 hours.

48 Papers today
8h Update frequency
7 Days of history
LongStraw: Long-Context RL Beyond 2M Tokens under a Fixed GPU Budget
Changhai Zhou, Kieran Liu, Yuhua Zhou, Qian Qiao, Jun Gao, Harry Zhang, Irvine Lu, Nolan Ho, Lucian Li, Andrew Lei, Cleon Cheng, Steven Chiang, Yihang Zeng, Di Zhang, Rio Yang, Kaijie Chen, Andrew Chen, Pony Ma, Weizhong Zhang, Cheng Jin
Reinforcement Learning Large Language Models Efficient ML
  • Introduces LongStraw, an architecture-aware execution stack for long-context RL post-training.
  • Demonstrates the ability to handle context lengths exceeding 2 million tokens under fixed GPU budgets.
  • Utilizes Group Relative Policy Optimization (GRPO) to optimize memory usage during training.
  • Validates the approach on two model families, achieving significant context length extensions.
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Certified Domain Consistency for Multi-Domain Retrieval: Label-Free Per-Domain Contamination Control with Conformal Risk Guarantees
Jayakumar Manoharan
Theory
  • C3R provides a label-free per-domain contamination certificate, addressing the limitations of existing methods.
  • The method integrates seamlessly into existing retrieval architectures without requiring retraining.
  • C3R demonstrates superior performance in maintaining recall while controlling contamination compared to traditional methods.
  • The study introduces BEIR-MIX, a public benchmark for evaluating multi-domain contamination in retrieval systems.
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xHC: Expanded Hyper-Connections
Xiangdong Zhang, Xiaohan Qin, Sunan Zou, Tuo Dai, Xiaoming Shi, Huaijin Wu, Yebin Yang, Zhuo Xia, Shaofeng Zhang, Lin Yao, Yuliang Liu, Yu Cheng, Junchi Yan
Large Language Models Efficient ML
  • xHC enables meaningful expansion of Hyper-Connections beyond N=4, addressing previous limitations.
  • The method combines temporal feature augmentation and sparse residual-stream architecture to enhance efficiency.
  • Empirical results show significant improvements in downstream performance with modest increases in training costs.
  • xHC changes the benefit-cost tradeoff of scaling, making larger N more cost-effective.
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HyperShadow: A Benchmark for Detecting 3D Projections of Higher-Dimensional Spatial Objects
Akshay Sasi
Computer Vision Theory
  • HyperShadow is the first benchmark for detecting 3D projections of higher-dimensional spatial objects.
  • Traditional intrinsic-dimension estimation methods are inadequate for this task, achieving only 71-73% accuracy.
  • A compact learned point network achieves 96.2% accuracy in detecting projections.
  • The introduced rigidity witness is a zero-parameter statistic that effectively separates classes with high accuracy.
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Probabilistic Physics-Informed Neural Networks for Estimating Heterogeneous Elastic Properties from Low-Resolution and Noisy Displacement Data
Tatthapong Srikitrungruang, Jaesung Lee
Theory
  • PIE-PINN framework enhances robustness in estimating elastic properties from low-resolution and noisy data.
  • Utilizes a combination of B-spline-guided networks and hierarchical models to improve accuracy.
  • Demonstrates effectiveness through systematic case studies with varying noise levels.
  • Addresses limitations of existing methods that require high-fidelity observations.
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Multi-Axis Max@K Reinforcement Learning for Representative Diversity in Text-to-Image Generation
Ku Onoda, Paavo Parmas, Hiroki Furuta, Soichiro Nishimori, Yuta Oshima, Shohei Taniguchi, Yutaka Matsuo
Generative Models Reinforcement Learning Computer Vision
  • Introduces multi-axis max@K, a reinforcement learning objective for enhancing diversity in T2I models.
  • Formulates the problem of image diversity as target-mode coverage, focusing on visually distinct modes.
  • Validates the method through controlled experiments and real-world applications, showing significant improvements in fairness metrics.
  • Maintains image quality and text alignment while increasing diversity in generated outputs.
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Causal Inference for Sequential Settings under Interference and Latent Confounding
Phevos Paschalidis, Constantinos Daskalakis, Devavrat Shah
Theory
  • Introduces a model for causal inference in sequential settings with interference and latent confounding.
  • Utilizes an Ising model to capture dependencies among binary outcomes across time and units.
  • Proposes a computationally efficient Maximum Pseudo-Likelihood Estimation (MPLE) method for parameter estimation.
  • Establishes non-asymptotic consistency for parameter estimation and causal quantity estimation.
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Learning in Infinitesimal Non-Compositional Sketches
Sridhar Mahadevan
Theory
  • Introduces LINCS, a framework that addresses non-compositionality in ML through categorical sketches.
  • Defines Infinitesimal Non-Compositionality (INC) as an obstruction to factorization under perturbations.
  • Presents Tangent Learning Sketches, ensuring properties of models are preserved under tangent lifts.
  • Establishes the existence of a final INC coalgebra and discusses conditions for convergence.
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Kernel weighted importance sampling for off-policy evaluation in contextual bandits
Joshua Spear, Matthieu Komorowski, Rebecca Pope, Neil J Sebire, Erica E.M. Moodie
Reinforcement Learning Theory
  • Introduction of Kernel-WIS, a new estimator for off-policy evaluation in contextual bandits.
  • Kernel-WIS demonstrates asymptotic consistency and outperforms traditional methods under complex conditions.
  • The method effectively combines properties of existing importance sampling techniques to reduce variance.
  • Empirical results show significant performance improvements over baseline estimators.
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Depth-Dependent Hidden-State Collapse in Dynamical System Autoencoders for LiDAR Point-Cloud Classification
Patricia Medina, Hy P. G. Lam
Computer Vision Theory
  • Identification of hidden-state collapse in DSAE at encoder depth K = 5.
  • Demonstration that total hidden scatter limits class separation capabilities.
  • Evaluation of DSAE performance across different LiDAR feature settings.
  • Mathematical proof linking hidden variance to class-separating scatter.
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CASP: Learning-Augmented Offline Approximation with Verifiable Certificates and Bounded-Loss PAC Guarantees
Haifeng Li, Mo Hai
Optimization Theory Efficient ML
  • CASP uses verifiable certificates to determine which parts of the search space can be ignored, enhancing the reliability of predictions in NP-hard optimization.
  • The framework ensures correctness is independent of prediction quality, addressing the limitations of traditional learning-augmented algorithms.
  • A quantitative theory of confidence filtering is developed, showing significant improvements over standard methods in handling noisy predictions.
  • The paper demonstrates that CASP can achieve optimal solutions even in the presence of distribution shifts, unlike unverified pruning methods.
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QFireNet: A Quantum-Enhanced U-Net for Wildfire Segmentation from Sentinel-2 Imagery
Jaiman Munshi, Tanvi Tewary, Sawyer Bloom, Aidan Chu, Chetan Maviti, Kyon Winston-Bey, Harshit Badjatia, Farhan Kittur, Vardhan Madhavarapu, Varun Kota, Joshua Kwon, Nazia Rangwala-Vohra, Franz Klein
Computer Vision
  • QFireNet integrates quantum-enhanced techniques into the U-Net architecture for improved wildfire segmentation.
  • Both QB-Net and QuFeX models outperform classical U-Net baselines in F1 score metrics.
  • Data mixing strategies significantly mitigate domain shifts, enhancing model performance.
  • The study highlights the potential of quantum machine learning in addressing complex image segmentation challenges.
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ChronoQG: Towards a Temporally Expressive and Hop-Bounded Benchmark for Temporal Knowledge Graph Question Generation
Xuemeng Liu, Zhengpin Li, Wanpeng Tang, Haotong Xie, Wentao Zhang
NLP Graph Learning Large Language Models
  • ChronoQG is the first benchmark framework specifically designed for Temporal Knowledge Graph Question Generation (TKGQG).
  • The framework integrates a comprehensive taxonomy of temporal constraints and topology-temporal subgraph sampling.
  • Evaluation of existing LLM-based KGQG methods shows significant challenges in preserving temporal constraints.
  • ChronoQG produces four benchmark datasets with a total of 16,011 verified questions, facilitating future research.
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Analytical study of the optimal combination of binary classifiers based on classifiers-induced partitioning of the training set
Jean-Marc Brossier, Olivier Lafitte
Optimization Theory
  • Establishes conditions for the existence and uniqueness of the minimum of convexified empirical risk.
  • Derives analytical formulas for optimal weights for binary classifiers using specific loss functions.
  • Introduces the concept of Ο•-frontiers for assessing classifier stability and data quality.
  • Identifies configurations leading to unique or non-unique solutions in classifier combinations.
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GAttNHP: Group Attention Neural Hawkes Process for Extrapolation Reasoning in Temporal Knowledge Graphs
Xiangni Tian, Kaixian Yu, Runpeng Dai, Niansheng Tang, Hongtu Zhu
Graph Learning Time Series
  • GAttNHP effectively captures long-range temporal dependencies in TKGs.
  • The framework incorporates mutual excitation among event chains through a semantic soft-grouping mechanism.
  • NCQ regression provides robust time predictions that are stable under heavy-tailed distributions.
  • GAttNHP outperforms state-of-the-art models on multiple TKG benchmarks.
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Long-term User Engagement Optimization through Model-agnostic Downstream Rewards Learning
Dingsu Wang, Filip Ryzner, Kelly He, Armando Ordorica, David Woo, Aditya Mantha, Liyao Lu, Usha Amrutha Nookala, Haoran Guo, Jiacong He, Olafur Gudmundsson, Matt Chun, Krystal Benitez, Dhruvil Deven Badani, Yijie Dylan Wang
Optimization Reinforcement Learning
  • Introduces a unified, model-agnostic framework for optimizing long-term user engagement in recommendation systems.
  • Develops an offline screening framework to identify session-level behaviors predictive of future retention.
  • Proposes several model-agnostic downstream reward signals derived from user action patterns.
  • Demonstrates significant improvements in engagement and retention through online A/B testing.
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Towards a Unified Multidimensional Explainability Metric: Evaluating Trustworthiness in AI Models
Georgios Makridis, Georgios Fatouros, Athanasios Kiourtis, Dimitrios Kotios, Vasileios Koukos, Dimosthenis Kyriazis, Jonh Soldatos
Interpretability
  • Introduction of a unified multidimensional explainability metric for XAI methods.
  • Focus on three key aspects: fidelity, simplicity, and stability.
  • Development of an offline knowledge base for context-dependent evaluation of explainability.
  • Demonstration of the framework on three open-source datasets.
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Active Real-World Factor-Based Evaluation for Generalist Robot Policies
Andrew Liao, Hanchen Cui, Karthik Desingh, Aryan Deshwal
Robotics Efficient ML
  • Proposes an active evaluation framework for generalist robot policies to improve evaluation efficiency.
  • Uses a probabilistic surrogate model to adaptively select task factor configurations.
  • Demonstrates significant savings in evaluation trials (20-40%) compared to traditional random testing.
  • Addresses the challenge of generalization in real-world environments for robot policies.
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Lyapunov Guidance: A Unified Framework for Stabilizing Generative Flows
Jingdong Zhang, Xinze Li, Yize Jiang, Luan Yang, Minkai Xu, Junhong Liu
Generative Models Theory Reinforcement Learning
  • LyaGuide provides a unified framework for stabilizing generative flows using Lyapunov control theory.
  • The framework establishes a theoretical equivalence between guided flow matching and Lyapunov control.
  • A pseudo-projection operator is introduced to enforce stability guarantees for guidance terms.
  • LyaGuide supports both model-driven and data-driven guidance settings.
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Accelerating A/B-Tests with Counterfactual Estimation: Reducing Variance through Policy Overlap
Olivier Jeunen
Theory Efficient ML
  • Introduces a novel experimental protocol leveraging policy overlap to reduce variance in A/B testing.
  • Demonstrates that the proposed Ξ”-OPE framework can provide unbiased ATE estimates and dominate traditional Difference-in-Means estimators.
  • Identifies optimal traffic allocation strategies based on policy divergence to minimize variance.
  • Proposes Ξ”-MRDR and Ξ”-DCG estimators for direct variance minimization and ranking applications, respectively.
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Innocuous-Seeming Data, Latent Ideology: Ideological Generalisation in Finetuned LLMs
Robert Graham, Edward Stevinson, Yariv Barsheshat
NLP Large Language Models
  • Fine-tuning on narrow, innocuous datasets can lead to broad ideological shifts in language models.
  • The phenomenon of ideological generalisation can produce extreme outputs on unrelated topics.
  • A methodology is proposed to quantify the breadth and amplification of ideological shifts.
  • Results are consistent across different model families and evaluation methods.
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Explainable Geospatial AI for Satellite Ground Station Siting Using LiDAR-Derived Terrain Intelligence
Shohini Sarkar, Smithi Mahendran, Rishi Chudasama, Varun Mannam, Arav Luthra, Yuvraj Rekhi, Vivek Nadig, Arsh Goenka
Interpretability
  • Introduction of a machine learning framework for predicting Representative Clutter Height (RCH) using LiDAR and open geospatial data.
  • LightGBM model outperforms traditional fixed ITU-R clutter height defaults, achieving significant accuracy improvements.
  • SHAP analysis provides insights into the most influential predictors for RCH, enhancing model interpretability.
  • The framework is globally deployable and can improve site selection for satellite ground stations, reducing uncertainty in planning.
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BadWAM: When World-Action Models Dream Right but Act Wrong
Qi Li, Xingyi Yang, Xinchao Wang
Robotics
  • Introduction of World-Action Drift Attacks (WADAs) as a new class of adversarial attacks specific to WAMs.
  • Development of BadWAM, a unified framework for modeling and evaluating these attacks.
  • Demonstration of significant task performance degradation in WAMs under adversarial conditions.
  • Identification of a critical vulnerability where action outputs can be hijacked while maintaining plausible future predictions.
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Integration Matters: Rollout-Based Training for Constrained Diffusion Models
Xiaoxuan Liang, Saeid Naderiparizi, Berend Zwartsenberg, Frank Wood
Generative Models Robotics Optimization
  • Introduction of a fine-tuning framework that optimizes constraint satisfaction during the denoising trajectory.
  • Formal analysis shows that the training objective leads to convergence towards feasible regions.
  • Demonstrated effectiveness on constrained generation tasks, improving constraint satisfaction while maintaining sampling quality.
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CARPRT: Class-Aware Zero-Shot Prompt Reweighting for Black-Box Vision-Language Models
Ruijiang Dong, Zesheng Ye, Jianzhong Qi, Lei Feng, Feng Liu, Gang Niu, Masashi Sugiyama
Computer Vision Multimodal
  • Introduces CARPRT, a class-aware prompt reweighting method for zero-shot image classification.
  • Addresses limitations of existing methods that use uniform prompt weights across classes.
  • Utilizes a training-free approach to derive class-specific prompt weights from unlabeled images.
  • Demonstrates improved performance on image classification benchmarks compared to class-agnostic methods.
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Beyond Entropy: Correctness-Aware Advantage Shaping via Contrastive Policy Optimization
Weiwen Xu, Jia Liu, Hou Pong Chan, Long Li, Deng Cai, Min Chen, Hao Zhang
Reinforcement Learning Large Language Models Optimization
  • CPO introduces contrastive disagreement as a more reliable token-level correctness signal compared to entropy.
  • The framework effectively addresses the zero-advantage problem in RLVR, enabling more informative gradients.
  • CPO unifies various On-policy Distillation variants under a single correctness-driven objective.
  • Empirical results show substantial performance improvements over existing entropy-based RLVR methods.
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Adaptive Runge-Kutta Step Control Buys Training Loss, Not Generalization: An Honest Compute-Matched Study of RK-Adam Optimizers
Akhilesh Gogikar
Optimization Theory
  • RK3(2)-Adam fails to outperform standard Adam in training loss under a compute-matched protocol.
  • The adaptivity of the RK method is ineffective, leading to fixed-step behavior.
  • Repairing the controller significantly reduces training loss but does not improve test accuracy.
  • Gradient averaging acts as an implicit regularizer, outperforming other optimizers in certain scenarios.
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Trajectory-Aware Flow Matching for Topology Optimisation
Shusheng Xiao, Jinshuai Bai, Hyogu Jeong, Yunfei Xi, Yilin Gui, YuanTong Gu
Generative Models Optimization
  • Introduces a trajectory-aware formulation for topology optimisation that enhances design exploration.
  • Demonstrates improved performance in generating diverse topology candidates with better compliance and fidelity.
  • Achieves significant reductions in sampling steps compared to traditional diffusion-based methods.
  • Highlights the importance of trajectory weighting in stabilizing generative processes.
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Decoding Market Emotion from Blockchain Activity: A Data-Driven Sentiment Classifier
Arthur G. Bubolz, Abreu Quevedo, Giancarlo Lucca, Rafael A. Berri, Eduardo Borges, Bruno L. Dalmazo
NLP Time Series Interpretability
  • Integration of blockchain data with social media sentiment to explain market behavior.
  • Focus on understanding market sentiment rather than predicting prices.
  • Gradient Boosting (XGBoost) achieved an average F1-score of 0.84 for sentiment classification.
  • SHAP values were used to enhance model interpretability and transparency.
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RTS Smoother-Guided Learning of Physics-Based Neural Differential Models
Ahmet Demirkaya, Georgios Stratis, Tales Imbiriba, Zachary D. Danziger, Deniz Erdogmus
Time Series Theory Interpretability
  • Introduces a hybrid neural-physics framework for modeling dynamical systems with incomplete dynamics.
  • Utilizes an iterative two-stage algorithm combining RTS smoothing and neural network parameter estimation.
  • Demonstrates improved latent-state reconstruction and long-horizon prediction capabilities.
  • Retains interpretability by preserving known mechanistic structures in the model.
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PAC Learning in Turn-Based Stochastic Games with Reachability Objectives: A Decentralized Private Approach via Expected Conditional Distance
Ali Asadi, Krishnendu Chatterjee, Pavol Kebis
Reinforcement Learning Theory
  • Introduces decentralized and private learning in TBSGs with reachability objectives.
  • Generalizes the Expected Conditional Distance (ECD) parameter for TBSGs.
  • Establishes polynomial sample complexity bounds for learning algorithms.
  • Demonstrates that adversarial learning is infeasible in TBSGs with reachability objectives.
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Multimodal Semantic-Aware Contrastive Learning For False Negative Mitigation in 3D Medical Imaging
Sara Ketabi, Matthias W. Wagner, Cynthia Hawkins, Uri Tabori, Birgit Betina Ertl-Wagner, Farzad Khalvati
Multimodal
  • Introduces MseaCL to mitigate false negatives in multimodal contrastive learning for 3D medical imaging.
  • Incorporates semantic similarity from radiology reports to improve representation learning.
  • Demonstrates significant performance improvements in downstream tasks, particularly in pediatric brain tumor classification.
  • Enhances model explainability by aligning learned representations with clinically relevant features.
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RENEW: Towards Learning World Models and Repairing Model Exploitation from Preferences
Logan Mondal Bhamidipaty, Mykel Kochenderfer, Subramanian Ramamoorthy
Reinforcement Learning Robotics Efficient ML
  • RENEW addresses model exploitation in offline RL by using human preferences to repair learned dynamics.
  • The proposed DLHF framework allows for direct supervision of model dynamics without requiring expert demonstrations.
  • Active preference querying based on epistemic uncertainty enhances sample efficiency and reduces prediction errors.
  • RENEW outperforms naive DLHF in terms of sample efficiency and robustness against catastrophic forgetting.
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LIGO-PINN: Learned Initialization via Gated Optimization to Alleviate Convergence Failures in Physics Informed Neural Networks
Nilay Anurag, Shital Adhikari, Taniya Kapoor, Nikhil Muralidhar
Optimization Theory
  • Introduces LIGO-PINN, a novel method for learned initialization of PINN weights.
  • Demonstrates significant performance improvements over existing PINN methodologies.
  • Addresses the critical role of weight initialization in mitigating convergence failures.
  • Validates the approach across multiple challenging PDE domains, including fluid dynamics.
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Interleaved Noise Injection Improves Clean, Corrupted, and OOD Performance
Matt L. Wiemann, Peter Melchior, Andrew K. Saydjari
Optimization Theory Computer Vision
  • Interleaved noise injection outperforms traditional noise schedules in improving model robustness.
  • Theoretical insights reveal that impulse noise approximates Jacobian regularization, enhancing optimization.
  • Gradient-norm stabilization effectively mitigates issues related to gradient volatility during training.
  • Architecture-specific noise preferences indicate that convolutional networks benefit more from impulse noise, while attention-based models perform better with Gaussian noise.
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Adaptive Ad Load Design for Sponsored Search Markets: Evidence, Theory, and Deployment
Mohammad Rashid, Hema Yoganarasimhan
Optimization Theory
  • Increasing ad load can significantly raise revenue but may negatively impact user engagement and conversions.
  • The effects of ad load vary greatly across different queries and market conditions.
  • The proposed e-LAAL algorithm adapts ad load dynamically based on recent outcomes and maintains support for multiple ad-load levels.
  • The deployment of e-LAAL in a real-world setting resulted in improved performance over static benchmarks.
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Evaluating Epistemic Uncertainty: Beyond OOD Detection and Active Learning
Jakub PaplhΓ‘m, Willem Waegeman, Eyke HΓΌllermeier, VojtΔ›ch Franc
Theory Optimization
  • Unification of selective classification and epistemic reject-option into a constrained optimization framework.
  • Demonstration of distinct rejection regions for OOD detection, active learning, and regret-minimization.
  • Critique of standard correlation metrics for uncertainty disentanglement, proposing a new diagnostic approach.
  • Empirical evidence showing disagreement between decision-theoretic rankings and proxy-task rankings.
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Data Driven Block Replacement Scheduling
Aniruddhan Ganesaraman, Vidyadhar Kulkarni
Optimization Theory
  • Development of data-driven algorithms for block replacement scheduling.
  • Formulation of the problem as a stochastic multi-armed bandit.
  • Introduction of a Kaplan-Meier renewal algorithm for lifetime distribution estimation.
  • Analysis of average-cost MDPs demonstrating the optimality of block replacement policies.
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Learning Who to Treat When Treatment is Missing
Johnna Sundberg, Rayid Ghani, Eli Ben-Michael, Edward Kennedy
Theory Efficient ML Optimization
  • Introduces a framework for policy learning under missing treatment data.
  • Proves that MAR estimators are more efficient than MCCAR estimators.
  • Demonstrates the critical importance of correctly specifying the missingness mechanism.
  • Empirical validation shows near-oracle performance of proposed methods.
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Muse: Representation Geometry of Muon Beyond Normalized Momentum
Da Chang, Qiankun Shi, Lvgang Zhang, Di He, Yaoshuai Ma, Ganzhao Yuan, Yongxiang Liu
Optimization Large Language Models Theory
  • Muse optimizers reveal the significance of matrix representation in Muon-style optimization.
  • Different Frobenius-isometric representations induce distinct polar geometries affecting optimization performance.
  • Balanced non-native representations can match the performance of native representations in large language models.
  • Reducing the shorter dimension in matrix representations weakens optimization capabilities.
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MIDiff: Tackling Sparsity and Imbalance in Mobile Usage Generation via Multivariate-Imaging Diffusion
Yilai Liu, Shiyuan Zhang, Hongyang Du
Generative Models Time Series Multimodal
  • Introduces MIDiff, a diffusion-based framework for mobile usage data generation.
  • Addresses challenges of sparsity, heterogeneity, and long-tail imbalance in mobile usage traces.
  • Utilizes C-GASF to convert sparse sequences into correlation images for better modeling.
  • Employs Triple Attention in a U-Net to preserve temporal and variable dependencies.
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Non-vacuous Generalization Bounds for Reinforcement Learning with Verifiable Rewards
Yuxuan Zhu, Rohan Alur, Daniel Kang
Reinforcement Learning Large Language Models Theory
  • First non-vacuous generalization bounds for RLVR fine-tuning at scale.
  • Introduction of the Progressive RLVR framework for efficient model compression.
  • Empirical validation across four domains showing significant accuracy improvements.
  • Use of Gumbel-max reparameterization to handle stochastic token generation.
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TEDDY: A Pediatric Foundation Model for Risk Forewarning from ICD-Coded Diagnostic Histories
Matthew Brady Neeley, Jorge Botas, Johnathan Jia, Lin Yao, Daniel Palacios, Benjamin Choi, Zhandong Liu, Hyun-Hwan Jeong
Generative Models Time Series
  • TEDDY is specifically designed for pediatric patients, addressing the limitations of adult-centric models.
  • The model achieved a median AUC of 72.0%, outperforming traditional machine learning baselines in disease onset prediction.
  • TEDDY demonstrated predictive capabilities over two years before the first diagnosis, highlighting its potential for early intervention.
  • The model is particularly effective in predicting rare diseases, with 90% of the rarest conditions showing significant predictive confidence.
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Counterfactual Optimal Action Trees (COAT): Interpretable Prescriptive Policies from Observational Data
Youssef Drissi, Markus Ettl, Shivaram Subramanian, Wei Sun, Zack Xue
Optimization Interpretability
  • COAT combines counterfactual estimation with mixed-integer optimization for interpretable decision-making.
  • The framework was successfully applied in a real-world airline pricing scenario, demonstrating significant revenue uplift.
  • COAT addresses the challenges of deploying AI in regulated environments by ensuring transparency and compliance.
  • The methodology emphasizes the integration of causal estimation and scalable optimization.
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LATTICE: Graph Self-Supervised Learning for Multimodal Spatial Omics Integration
Jagan Mohan Reddy Dwarampudi, Veena Kochat, Suresh Satpati, Kunal Rai, Tania Banerjee
Graph Learning Multimodal
  • LATTICE integrates multiple spatial omics modalities into a unified graph-based framework.
  • The framework employs self-supervised learning objectives to enhance multimodal representation.
  • Evaluation on a melanoma cohort shows improved concordance with established clustering methods.
  • Incorporating additional modalities can enhance spatial contiguity but may complicate transcriptomic alignment.
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A Continuous-Time Reinforcement Learning Framework for Fine-Tuning Discrete Diffusion Models
Zikun Zhang, Jiayuan Sheng, David D. Yao, Wenpin Tang
Reinforcement Learning Large Language Models Generative Models
  • Introduces a continuous-time RL framework for fine-tuning discrete diffusion models.
  • Allows incorporation of intermediate rewards, improving credit assignment during training.
  • Develops efficient trajectory subsampling techniques to reduce computational costs.
  • Demonstrates effectiveness on low-dimensional optimization and dLLM post-training tasks.
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Dysco: Dynamic Subspace Boosting to Mitigate LoRA Interference in Federated Learning
Haobo Zhang, Jiankun Wang, Suraj Rajendran, Weishen Pan, Lam Tsoi, Yong Chen, Fei Wang, Jiayu Zhou
Federated Learning Optimization Efficient ML
  • Dysco mitigates data-parameter interference in federated learning by dynamically allocating client-specific LoRA subspaces.
  • The method enhances stability and performance of federated LoRA aggregation through activation-insensitive subspace computation.
  • Dysco achieves substantial reductions in training loss and improves accuracy across multiple federated learning algorithms.
  • The approach adds minimal computational overhead, making it practical for real-world applications.
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Sharp Stability Threshold and Certification for Designing Stable Residual Architectures
Hyemin Gu, Michael Tyrrell, Tuhin Sahai, Markos A. Katsoulakis
Theory Optimization
  • Establishes a stability threshold (q ≀ 1) for deep residual architectures based on velocity field growth.
  • Introduces a method for certifying the stability of neural architectures through input-magnitude exponents.
  • Demonstrates that exceeding the stability threshold leads to training instability and divergent behavior.
  • Provides a parameter-free modification to stabilize supercritical blocks without normalization.
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