AI-generated summaries

Today's ML research,
without the noise.

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

63 Papers today
8h Update frequency
7 Days of history
EXHOLD: Experience-Aware Real-Time Hold Control for Large-Scale Ride-Hailing Matching at DiDi
Xu Liu, Kai Wan, Zihao Lu
Optimization
  • EXHOLD improves hold control in ride-hailing systems by decoupling assessment and execution.
  • The framework uses experience tiers to optimize multiple satisfaction-related signals.
  • Constrained optimization ensures that hold times are managed within service guardrails.
  • Real-world deployment in Brazil showed significant improvements in trip success and driver welfare.
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Semantic Pareto-DQN: A Multi-Objective Reinforcement Learning Framework for Financial Anomaly Detection
Cláudio Lúcio do Val Lopes, Lucca Machado da Silva
Reinforcement Learning Optimization
  • Introduces a multi-objective reinforcement learning framework for financial anomaly detection.
  • Utilizes large language models to create cohesive state representations from transaction features.
  • Decouples multiple objectives into a vectorial reward system to navigate trade-offs effectively.
  • Demonstrates superior performance in minority-class recall compared to traditional methods.
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Variable-Length Generative Protein Design via Generalized Poisson Flow
Chaoran Cheng, Zhanghan Ni, Yanru Qu, Yuxin Chen, Ruihan Guo, Jiajun Fan, Ge Liu
Generative Models
  • Introduction of GPFlow, a variable-length generative model for protein design.
  • Theoretical guarantees for joint multimodal distribution recovery and KL divergence bounds.
  • Superior performance of GPFlow over fixed-length models in various protein design tasks.
  • Demonstrated flexibility in generating proteins of varying lengths without prior length specification.
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Autoregressive latent diffusion for 3D molecule generation
Federico Ottomano, Gaopeng Ren, Yingzhen Li, Kim E. Jelfs, Alex M. Ganose
Generative Models Graph Learning
  • Introduction of KRONOS, a latent autoregressive diffusion framework for 3D molecule generation.
  • Combines autoregressive sequence modeling with diffusion-based latent token prediction.
  • Enables both unconditional and fragment-conditioned molecular generation within a single model.
  • Achieves leading unconditional generation performance on benchmark datasets.
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Frequency-Domain Multi-Modality Transportation Modeling
Jiewen Deng, Hangchen Liu, Junchen Li, Boyuan Zhang, Renhe Jiang
Time Series Multimodal
  • Introduces a frequency-domain approach to multi-modality transportation modeling.
  • Employs a Modality-Wise Frequency Filter (MFF) for spectral refinement.
  • Incorporates a Frequency-Guided Synergy Integrator (FSI) for selective cross-modality information sharing.
  • Demonstrates superior performance compared to state-of-the-art methods on real-world datasets.
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Data-Efficient Deep Learning: Empirical Guidelines for Training Set Size Estimation in Inertial Sensor Classification
Ofir Kruzel, Itzik Klein
Efficient ML Time Series Theory
  • Learning curve convergence for inertial sensor classification is evaluated.
  • Classification accuracy consistently follows a logarithmic growth pattern.
  • A new stability point metric is introduced to optimize training data collection.
  • Models often reach stability with fewer samples than traditional heuristics suggest.
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A Unified Approach to Interpreting Knowledge Distillation for Large Language Models via Interactions
Qingzhuo Wang, Ruiyang Qin, Zhenxin Qin, Wen Shen, Zhihua Wei
NLP Large Language Models Interpretability
  • The paper provides a unified interpretation of knowledge distillation mechanisms in LLMs through interaction analysis.
  • Sparsification of interactions is identified as the common mechanism across different KD methods.
  • The performance of KD methods is linked to their ability to handle complex interactions effectively.
  • The proposed Complex Interaction Penalty (CIP) loss function improves the performance of KD methods.
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Application of machine learning to monster level prediction in tabletop RPG game design
Jolanta Åšliwa, Jakub Adamczyk
Theory Interpretability
  • Introduction of the first dataset for TTRPG monster-level prediction, fostering further research.
  • Formalization of monster level prediction as a tabular ordinal regression problem.
  • Comprehensive benchmarking of 16 models, demonstrating the superiority of tree-based ensembles.
  • Use of domain-specific evaluation schemes for realistic model generalization assessment.
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Dimensionality Reduction Meets Network Science: Sensemaking on UMAP's kNN Graph
Duen Horng Chau, Donghao Ren, Fred Hohman, Dominik Moritz
Graph Learning
  • UMAP's kNN graph is a valuable resource for data analysis, often overlooked in favor of 2D projections.
  • Standard graph algorithms can be effectively applied to the kNN graph to enhance understanding of data structure.
  • PageRank, k-core decomposition, and clustering coefficient provide insights into data representativeness, density, and local cohesion.
  • Graph-based analyses on MNIST and Fashion MNIST datasets show competitive performance compared to traditional methods.
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Sticky Routing: Training MoE Models for Memory-Efficient Inference
Ali Kayyam
NLP Large Language Models Efficient ML
  • Introduction of StickyMoE, a routing consistency loss for MoE models.
  • Significant reduction in expert switch rates and cache misses during inference.
  • No architectural modifications required, only a single hyperparameter added.
  • Empirical results show improved perplexity and efficiency in MoE models.
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Unlocking Temporal Generalization in Hamiltonian Video Dynamics Models
Eli Laird, Corey Clark
Generative Models Robotics Time Series
  • World models typically lack the ability to generalize across different temporal resolutions due to fixed training step sizes.
  • Hamiltonian Generative Networks (HGN) can predict dynamics based on continuous-time energy functions but face challenges in non-conservative settings.
  • The authors identify specific failure modes in HGN rollouts and propose targeted solutions to enhance temporal generalization.
  • The extended HGN framework can predict stable dynamics at temporal resolutions outside the training regime.
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Certified Interventional Fidelity: Anytime-Valid, Adaptive Evaluation of Causal Claims in Mechanistic Interpretability
Amir Asiaee
Interpretability
  • CIF provides a statistical layer for interventional interpretability evaluations, ensuring claims are backed by uncertainty quantification.
  • The framework allows for adaptive evaluation while maintaining the original target estimand through bounded mixture importance weighting.
  • CIF introduces anytime-valid confidence sequences, which remain valid under repeated monitoring of results.
  • The methodology significantly reduces certification costs by 10-30 times using variance-adaptive betting sequences.
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A Practical Investigation of Training-free Relaxed Speculative Decoding
Guoxuan Xia, Luka Ribar, Paul Balanca
NLP Large Language Models Efficient ML
  • Relaxed speculative decoding can yield speed-ups but requires careful capability evaluation.
  • A unified framework for understanding various relaxed speculative decoding methods is presented.
  • Benchmarking of relaxed approaches reveals performance trade-offs compared to strict speculative decoding.
  • Many relaxed methods depend on the quality of the drafter model, limiting their applicability.
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Present but Rescaled: Chat-to-Agent Transfer of Additive Activation Steering
Lucas Pinto
NLP Large Language Models Generative Models
  • Additive activation steering shows real but rescaled transfer from chat to agent contexts.
  • The injected direction survives with near-full strength, but behavioral outcomes reset per model and context.
  • Amplification and attenuation of steering effects vary significantly across different models.
  • Directional ablation does not amplify, highlighting a specific mechanism for additive injection.
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Optimal Learning Rate Scaling Depends on Data in Deep Scalar Linear Networks
Yedi Zhang, Peter E. Latham, Leena Chennuru Vankadara, Andrew Saxe
Theory Optimization
  • Optimal learning rate scaling in deep scalar linear networks is data-dependent.
  • Data-agnostic scaling rules fail to transfer effectively across different depths.
  • The proposed data-dependent scaling leads to a constant linear convergence rate.
  • The findings extend to deep scalar linear networks with residual connections.
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Risk-Aware General-Utility Markov Decision Processes
Pedro P. Santos, Fábio Vital, Alberto Sardinha, Francisco S. Melo
Reinforcement Learning Robotics Optimization
  • Introduction of risk-aware GUMDPs that allow for a trade-off between expected performance and risk aversion.
  • Development of an MCTS-based approach for solving risk-aware GUMDPs with provable accuracy.
  • Experimental validation of the proposed method across diverse tasks, highlighting its versatility and effectiveness.
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A Survey on the Green Development of Large Models: From Resource-Efficient Architectures to Hardware-Software Co-Design
Linhui Xiao, Guiping Cao, Mingyue Guo, Xianchao Guan, Fan Yang, Ming Tao, Xin Li, Yuxin Peng, Yaowei Wang
Efficient ML
  • The survey emphasizes the need for resource-efficient architectures in large AI models to mitigate environmental impacts.
  • It highlights the importance of hardware-software co-design for optimizing energy consumption and computational efficiency.
  • The paper reviews various strategies for efficient model construction and deployment, including sparsification and data-efficient learning.
  • Applications of large models in sustainability-critical areas are explored, showcasing their potential for real-world impact.
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NFTR: From Provable Mode-Averaging to Geodesic Subgoal Selection in Offline Goal-Conditioned RL
Erdemt Bao, Xing Lei, Jun Chen
Reinforcement Learning Robotics Theory
  • NFTR addresses optimistic bias and mode collapse in HIQL by using Normalizing Flows for subgoal selection.
  • The triangle-slack score provides a mechanism to downweight unreliable subgoals based on geometric consistency.
  • NFTR preserves population-level monotonic improvement and allows for a detailed suboptimality decomposition.
  • Empirical evaluations indicate substantial performance improvements over HIQL in various offline GCRL tasks.
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Action-Factored Multi-Agent Reinforcement Learning for Scalable Quantum Device Tuning
Edwin De Nicolo, Rahul Marchand, Cornelius Carlsson, Pranav Vaidhyanathan, Natalia Ares
Reinforcement Learning Optimization Robotics
  • Introduction of QADAPT, a multi-agent reinforcement learning framework for quantum device tuning.
  • Adaptive action-space factorization reduces cross-agent interference and improves sample efficiency.
  • Zero-shot generalization allows the framework to adapt to unseen quantum device configurations.
  • Empirical results demonstrate superior performance compared to existing tuning methods.
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SafeExplorer: An Unbiased Policy Gradient for Reinforcement Learning with Recovery Interventions
Elham Daneshmand, Majid Khadiv, Glen Berseth, Hsiu-Chin Lin
Reinforcement Learning Robotics Theory
  • Introduces SafeExplorer, an unbiased policy gradient method for safe reinforcement learning.
  • Addresses the bias introduced by mixed-policy rollouts when using a recovery policy.
  • Empirically reduces training-time falls by factors of 233×, 48×, and 26× in different environments compared to standard PPO.
  • Includes a closed-form value for recovery-triggering states and an imitation loss for successful recovery actions.
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Prompt-Driven Exploration
Sunshine Jiang, John Marangola, David Zhang, Raghuram Kowdeed, Ruiyang Luo, Nitish Dashora, Richard Li, Pulkit Agrawal, Zhang-Wei Hong
Reinforcement Learning Large Language Models Robotics
  • PDE enables global exploration in RL by modifying natural language prompts.
  • The method allows RL to escape weak initial policies by refining prompts based on rollout performance.
  • PDE improves sample efficiency and success rates in tasks with sparse rewards.
  • The approach is validated on manipulation and reasoning tasks, as well as coding tasks.
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LieBN: Batch Normalization over Lie Groups
Ziheng Chen, Yue Song, Rui Wang, Xiao-Jun Wu, Nicu Sebe
Theory Optimization
  • Introduction of LieBN, a general framework for Riemannian Batch Normalization over Lie groups.
  • Development of a novel right-invariant metric on the SPD manifold, enhancing normalization capabilities.
  • Demonstration of LieBN's effectiveness across multiple geometries and tasks.
  • Theoretical guarantees for controlling both Riemannian mean and variance.
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Accelerating GPU Inference of Large Language Models with Moderately Unstructured Sparse Weight Matrices
Tao Lu, Haoyu Wang, Zonghui Wang, Keshen Xiang, Jiaheng Zhang, Wenzhi Chen
NLP Large Language Models Efficient ML
  • Introduces a three-layer matrix storage format for efficient SpMM under moderate sparsity.
  • Develops a co-optimized SpMM kernel that utilizes both sparse tensor cores and CUDA cores.
  • Achieves up to 1.64× kernel-level speedup over existing methods and outperforms dense matrix multiplication.
  • Addresses key challenges in sparse LLM inference, including tensor core compatibility and metadata overhead.
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COBS: Cumulant Order Block Sparse Attention
Alexander Tian, Aditya Ghai, Sanjit Neelam, Zaal Vasania, Akshay Mishra
Large Language Models NLP Efficient ML
  • COBS formalizes block selection as ranking blocks by attention mass, improving selection accuracy.
  • The method incorporates a second-order statistic to capture within-block covariance, enhancing performance.
  • COBS achieves a mean score of 0.8195 on the 32k RULER benchmark, significantly outperforming the NSA baseline.
  • The method uses only 1.21× the KV cache read traffic of the NSA baseline and 15.15× less than dense attention.
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FairSelect: A Systematic Evaluation of Multi-Level and Intersectional Algorithmic Fairness
Nick Souligne, Isabella Mixton-Garcia, Vignesh Subbian
Theory
  • FairSelect provides a systematic framework for evaluating fairness strategies across multiple modeling stages.
  • The toolkit supports intersectional subgroup analysis, addressing disparities that arise from multiple demographic characteristics.
  • Combining fairness interventions can lead to improved fairness outcomes, though results can vary significantly in practical applications.
  • The study emphasizes the importance of context in assessing the effectiveness of fairness strategies.
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Secure Decentralized Federated Learning via Gossip and Virtual Voting
Amirhossein Taherpour, Xiaodong Wang
Federated Learning
  • gspDAG-FL provides a secure framework for decentralized federated learning that enhances resilience against adversarial participants.
  • The framework utilizes gossip history for consensus, allowing for efficient model dissemination without central coordination.
  • Finality is achieved through unique model-origin tuples, improving provenance tracking and filtering invalid updates.
  • Experimental results indicate that gspDAG-FL maintains high learning quality while reducing coordination bottlenecks.
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TSRouter: Dynamic Modality-Model Selection for Time Series Reasoning
Fangxu Yu, Tao Feng, Dehai Min, Lu Cheng, Ge Liu, Tianyi Zhou
Time Series Graph Learning Multimodal
  • TSROUTER leverages a graph-based approach to model complex interactions among tasks, queries, modalities, and models.
  • The framework allows for dynamic selection of the most suitable modality and model, enhancing performance in time series reasoning.
  • TSROUTER achieves significant improvements over baseline methods, with relative performance gains of 16% to 46%.
  • It demonstrates strong zero-shot generalization capabilities, effectively handling new tasks and models without retraining.
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Scalable and Trustworthy Earth Observation Foundation Models
Syed Usama Imtiaz, Mitra Nasr Azadani, Nasrin Alamdari
Computer Vision Multimodal
  • Foundation models (FMs) can be adapted for multiple downstream tasks in Earth Observation.
  • Remote Sensing Foundation Models (RSFMs) require domain-specific adaptations due to unique EO data characteristics.
  • Evaluation of RSFMs should consider modality-aware transfer and physical plausibility, not just benchmark accuracy.
  • Two case studies demonstrate practical applications of RSFMs in environmental monitoring.
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LLT: Local Linear Transformer for PDE Operator Learning
Oded Ovadia, Eli Turkel
Efficient ML Theory Optimization
  • LLT combines linear global attention with local spatial mixing to improve efficiency in PDE operator learning.
  • The architecture incorporates coordinate and geometry information to enhance performance on PDE problems.
  • LLT demonstrates competitive accuracy with lower relative L2 error compared to existing models.
  • Significant reductions in training time per iteration make LLT a more efficient alternative for PDE simulations.
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SLORR: Simple and Efficient In-Training Low-Rank Regularization
David González-Martínez, Shiwei Liu
Efficient ML Computer Vision Large Language Models
  • SLORR is SVD-free and does not require architectural changes, making it practical for modern neural networks.
  • The framework provides GPU-efficient approximations for low-rank regularization, ensuring scalability.
  • Empirical results show that SLORR improves post-training compressibility with minimal training overhead.
  • SLORR maintains model performance better than traditional methods during compression.
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COAST: Context-Aware Differential Learning for Gene Expression Prediction in Spatial Transcriptomics
Keunho Byeon, Sunhong Park, Jeewoo Lim, Jin Tae Kwak
Computer Vision
  • COAST integrates local and global context features for improved gene expression prediction.
  • The framework employs a joint training objective combining absolute and differential regression.
  • Experiments show consistent performance improvements over existing methods.
  • COAST retains clinically meaningful prognostic information in gene expression representations.
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Beyond Backpropagation: Monte Carlo Method Can Train Deep Neural Networks
Hong Zhao
Optimization Theory Efficient ML
  • Introduces a gradient-free Monte Carlo method for training deep neural networks.
  • Demonstrates effectiveness without traditional techniques like batch normalization.
  • Validates the method on various architectures and tasks, including deep networks and Transformers.
  • Reveals substantial redundancy in deep networks and supports unconventional transfer functions.
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Shortcut Trajectory Planning for Efficient Offline Reinforcement Learning
Guanquan Wang, Yoshimasa Tsuruoka
Reinforcement Learning Generative Models Robotics
  • Introduction of Shortcut Trajectory Planning (STP) for offline reinforcement learning.
  • STP simplifies the training process by using a single-stage training of shortcut models.
  • The framework allows for adjustable inference steps, enhancing planning efficiency.
  • STP demonstrates competitive performance across various D4RL benchmarks.
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Write-Protected Discrete Bottlenecks for Language-Grounded World Models: A Structural Limitation and Sufficient Fix
Jiayi Fang
Robotics NLP Multimodal
  • Language gradients entering discrete bottlenecks create a structural trade-off that limits learning and diversity.
  • A three-layer architectural fix is proposed to address the limitations of existing end-to-end approaches.
  • The proposed architecture achieves high grounding accuracy while maintaining low computational requirements.
  • The findings challenge the assumption that larger LLMs inherently improve physical grounding in robotic systems.
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Forget Narrowly, Retain Broadly: Unlearning as an Asymmetric Generalization Problem
Amit Peleg, Naman Deep Singh, Naama Pearl, Bibhabasu Mohapatra, Matthias Hein
NLP Large Language Models Optimization
  • Introduces SUITE, a fine-grained evaluation protocol for unlearning in LLMs that captures the asymmetric generalization problem.
  • Identifies and addresses the failures of existing benchmarks in measuring unlearning effectiveness.
  • Presents JensUn++, an advanced unlearning algorithm that optimizes the trade-off between forgetting and retaining knowledge.
  • Demonstrates the importance of training data quality in achieving effective unlearning outcomes.
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Architecture Generalization with MetaNCA
Meet Barot, Daniel Berenberg, Sina Khajehabdollahi
Graph Learning Efficient ML Theory
  • MetaNCA enables the generation of diverse neural network architectures through local self-organization.
  • The Weight Transformer architecture uses linear attention to facilitate local weight updates.
  • MetaNCA demonstrates generalization to unseen architectures, enhancing adaptability.
  • The framework scales to large networks with millions of parameters without backpropagation.
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Federated Deep Learning for Privacy-Preserving Cardiovascular Disease Risk Prediction
Hyunho Mo, Djura Smits, Mahlet A. Birhanu, Maarten J.G. Leening, Daniel Bos, Pim van der Harst, Esther E. Bron
Federated Learning
  • Federated learning allows for collaborative model development without sharing sensitive patient data.
  • The study integrates two heterogeneous cohorts to improve cardiovascular disease risk prediction.
  • Federated deep learning models achieved higher predictive performance compared to local models.
  • The approach preserves patient privacy while enhancing model generalizability.
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Distributed Sketching on Data Partitions for OLS Regression
Luyuan Yang, Brayden Garner, Shayan Shafaei, Chao Lan
Theory Optimization Efficient ML
  • Introduces a distributed sketching method for OLS regression using partitioned data subsets.
  • Characterizes the exact excess loss of the averaged OLS estimator in this context.
  • Shows that the performance of the new method is comparable to traditional sketching when subset covariances are similar.
  • Highlights the importance of covariance divergence in determining the effectiveness of the sketching approach.
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AlphaZero in Sparsely Rewarded Games: Limits and Auxiliary Supervision
Brent Kong, Tejas Ram, Tony Yue Yu
Reinforcement Learning Theory
  • Vanilla AlphaZero achieves strong self-play policies but does not consistently recover oracle-consistent play in Connect Four and Chomp.
  • The introduction of AZAL significantly improves oracle consistency, particularly in Chomp, suggesting that standard AlphaZero may struggle with exact optimality.
  • Multi-frame inputs alone do not resolve the performance gap in Chomp, indicating that more sophisticated learning signals are necessary.
  • The study provides empirical evidence that highlights the distinction between superhuman and perfect play in AlphaZero-style agents.
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Deep Learning Method for Stationary Distribution of Reflected Brownian Motion
Jim Dai, Zhanhao Zhang
Theory Efficient ML Optimization
  • Develops a deep learning method for estimating the Laplace transform of high-dimensional reflected Brownian motion.
  • Combines a tailored loss function, sampling scheme, and neural network architecture to enhance performance.
  • Achieves near-perfect prediction of tail probabilities in high-dimensional settings.
  • Provides a scalable computational tool for analyzing stochastic systems.
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Jet-Long: Efficient Long-Context Extension with Dynamic Bifocal RoPE
Haozhan Tang, Zerui Wang, Yuxian Gu, Song Han, Han Cai
Large Language Models Efficient ML NLP
  • Jet-Long is a tuning-free method for zero-shot context extension in LLMs.
  • It dynamically adjusts the rescaling factor for long-range windows based on sequence length.
  • The method achieves superior performance on benchmarks compared to existing zero-shot methods.
  • Jet-Long incurs minimal latency overhead and is compatible with hybrid attention architectures.
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How are linear representations learned? Exact solutions to the dynamics of abstraction
William W. Yang, Andrew M. Saxe, Peter E. Latham
Theory Interpretability
  • Introduces a framework for studying the dynamics of abstraction in neural networks during training.
  • Establishes that data and target geometry jointly determine the final abstraction achieved.
  • Demonstrates that deeper networks improve abstraction and that initialization scale affects maximum abstraction.
  • Analyzes the impact of nonlinearity on abstraction dynamics, with ReLU networks showing different behaviors compared to erf networks.
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Adaptive Bayes exactly tracks information over intrinsic time
Akshay Balsubramani
Theory Optimization
  • Introduces an exact information-accounting identity for Bayesian updates.
  • Establishes two exact adaptive decompositions of cumulative regret.
  • Demonstrates the applicability of the framework across various learning paradigms.
  • Highlights the role of intrinsic time in understanding learning dynamics.
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Learning Physics-Informed Surrogate Model of Linear Elastic Displacement Fields from Geometry
Rodolphe Barlogis, Ferhat Tamssaouet, Quentin Falcoz, Stéphane Grieu
Theory Efficient ML
  • Development of a physics-informed DeepONet framework for predicting displacement fields.
  • Introduction of a dedicated geometry-encoding strategy that allows direct input of fracture geometry.
  • Weak enforcement of traction-free conditions on fracture boundaries through a localized penalty term.
  • Demonstration of the model's feasibility using a specific fracture geometry as a proof of concept.
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Group Invariant Spectral Embedding
Yeari Vigder, Paulina Hoyos, David Thong, Joakim Andén, Joe Kileel, Amit Moscovich
Graph Learning Theory Efficient ML
  • Introduces group-invariant spectral embedding to account for symmetries in data.
  • Proves that graph Laplacians from invariant kernels converge to differential operators on quotient spaces.
  • Demonstrates improved convergence rates and effective dimension reduction.
  • Validates the approach on datasets with SO(2) and SO(3) symmetry.
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GatedLinear: Adaptive Routing of Complementary Linear Bases for Time Series Forecasting
Qitai Tan, Ruiwen Gu, Yilin Su, Mo Li, Xu Lin, Xiao-Ping Zhang
Time Series
  • GatedLinear utilizes three complementary linear bases to address diverse temporal dynamics in time series forecasting.
  • The Tri-Factorized Fusion Gate enables adaptive routing of predictions based on variable characteristics and forecast horizons.
  • The framework achieves competitive accuracy against state-of-the-art models while being more parameter-efficient.
  • GatedLinear provides interpretable routing patterns, enhancing the understanding of the forecasting process.
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Active rejection enables reliable generalization of universal machine-learning interatomic potentials
Mingxiang Luo, Xinnan Mao, Lu Wang, Lei Bai, Feng Ding, Yuqiang Li
Theory Optimization Efficient ML
  • Introduction of the Adaptive Multi-Teacher Routing (ATR) framework for reliable data construction.
  • ATR utilizes multiple pretrained uMLIPs to filter and generate high-confidence pseudo-labels.
  • The framework successfully distills a large dataset from a minimal amount of high-fidelity labels.
  • Models trained on ATR-generated data show improved performance and stability in simulations.
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Learning $ ext{AC}^0$ under Locally Sampleable Graphical Models
Weiming Feng, Xiongxin Yang, Yixiao Yu, Yiyao Zhang
Theory Graph Learning
  • Introduces a quasipolynomial-time learner for AC0 circuits under locally sampleable graphical models.
  • Circumvents the polynomial growth requirement of previous work by utilizing a new low-degree approximation method.
  • Establishes a connection between efficient local samplers and the approximation of AC0 functions.
  • Applies the framework to two-spin systems, including the hard-core and Ising models, on arbitrary bounded-degree graphs.
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On-Device Adaptive Battery Power Prediction for Electric Vehicles
Avik Bhatnagar, Anton Paule, Tobias Schuermann, Sebastian Reiter, Oliver Bringmann
Time Series
  • Introduces on-device learning for adaptive battery power prediction in EVs.
  • Demonstrates significant performance improvements through online and offline adaptation strategies.
  • Achieves mean absolute error reductions of up to 14.88% in battery power forecasting.
  • Highlights the importance of adapting to dynamic driving conditions and user behavior.
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Trustworthy Machine Learning through the Lens of Combinatorial Optimization: Survey and Research Perspectives
Thibaut Vidal, Julien Ferry
Optimization Theory Interpretability
  • Trustworthiness in ML requires more than just predictive accuracy; it encompasses transparency, interpretability, robustness, fairness, and privacy.
  • The Rashomon effect indicates that multiple models can achieve similar performance, allowing for the selection of models based on trustworthiness criteria.
  • Combinatorial optimization offers a robust framework for addressing various trustworthiness challenges in ML, including model training, auditing, and certification.
  • CO techniques can provide global optimality and formal certificates, which are essential for ensuring the reliability of ML systems.
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Model Agnostic Graph Prompt Learning for Crystal Property Prediction
Shrimon Mukherjee, Kishalay Das, Partha Basuchowdhuri, Pawan Goyal, Niloy Ganguly
Graph Learning
  • Introduction of a model agnostic soft prompt learning framework for crystal property prediction.
  • Combines node-level and graph-level prompts to capture both local and global features.
  • Achieves significant performance improvements (3% - 15%) over existing GNN models.
  • Lightweight addition of only 0.32% extra parameters to existing architectures.
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Training, Reading, and Editing Legible Transformers
Mark Oskin
Interpretability
  • Introduces legibility by construction in transformer models, enhancing interpretability.
  • Proposes a per-channel variance floor to maintain operator context during training.
  • Achieves significant legibility improvements, with a majority of operations being crisp detectors.
  • Enhances the model's editability and readability, allowing for more precise modifications.
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Multi-Modal, Multi-Environment Machine Teaching for Robust Reward Learning
Ali Larian, Qian Lin, Chang Zong Wu, Daniel S. Brown
Reinforcement Learning Robotics Multimodal
  • Analysis of feedback modalities reveals that comparisons impose stronger constraints than demonstrations for reward learning.
  • Formal characterization of environment-dependent reward identifiability shows residual ambiguity even with unlimited feedback in a single MDP.
  • Introduction of HSCOT, a hierarchical algorithm that selects informative environments and feedback queries for efficient reward learning.
  • Empirical validation indicates HSCOT achieves better performance than uniform teaching under identical feedback budgets.
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Stochastic Linear Bandits with Partially Observed Actions
Gautam Dasarathy, Vineet Gattani, Lalit Jain
Theory Optimization Reinforcement Learning
  • Introduces a novel algorithm, TOFU-POV, for stochastic linear bandits with partially observed actions.
  • Demonstrates that sublinear regret is achievable when action vectors lie in a low-dimensional subspace.
  • Provides a regret guarantee that scales with the intrinsic dimension rather than the ambient dimension.
  • Presents a rank-adaptive version of the algorithm that does not require knowledge of the intrinsic dimension.
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A law of robustness for two-layer neural networks with arbitrary weights
Yitzchak Shmalo
Theory
  • Proves the conjectured law of robustness for two-layer neural networks with arbitrary weights.
  • Establishes that Lipschitz constant must scale with √(n/m) for fitting noisy labels.
  • Introduces a function-space covering method to handle unbounded weights.
  • Demonstrates the applicability of results to continuous piecewise-linear activations, particularly ReLU.
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Multimodal Unlearning Across Vision, Language, Video, and Audio: Survey of Methods, Datasets, and Benchmarks
Nobin Sarwar, Shubhashis Roy Dipta, Zheyuan Liu, Vaidehi Patil
Multimodal
  • Introduces a unified taxonomy for multimodal unlearning across vision, language, video, and audio.
  • Addresses the challenges of targeted forgetting in multimodal foundation models.
  • Highlights the trade-offs among deletion strength, utility retention, efficiency, and reversibility.
  • Identifies open problems and practical considerations for future research in multimodal unlearning.
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Sensitivity-Aware Thresholding and Token Routing for Activation Sparsification in Large Language Models
Bishmoy Paul, Youngmin Yi, Hoeseok Yang
Large Language Models Efficient ML
  • Introduction of SATS, a sensitivity-aware method for threshold calibration in activation sparsification.
  • Demonstrated improvement over percentile-based thresholding methods in terms of model quality at matched sparsity.
  • Development of a token routing framework that allows dynamic selection of computation paths for each token.
  • Token routing enhances the quality-throughput trade-off compared to static execution methods.
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Mach-Mind-4-Flash Technical Report
Foundation Model Team (Li Auto Inc)
Large Language Models Reinforcement Learning Efficient ML
  • Mach-Mind-4-Flash achieves high performance with only 3B activated parameters.
  • The model utilizes a novel training infrastructure that accelerates the training process by 17%.
  • Domain-specific RL experts are trained in parallel and fused into a single generalist model.
  • The Hybrid Median-length Policy Optimization method significantly reduces token generation length with minimal accuracy loss.
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SYNRARE: Synthetic Rare Disease EHR Generation for ML Benchmarking
Nicolai Dinh Khang Truong, Richard Röttger
Generative Models
  • SYNRARE enables the generation of synthetic EHRs for rare disease patients, facilitating ML benchmarking.
  • The tool provides a no-code interface, making synthetic data generation accessible to a wider range of researchers.
  • SYNRARE allows for the modeling of comorbidities based on empirical evidence, enhancing the realism of generated data.
  • The framework supports the creation of patient cohorts with controlled dissimilarity from common diseases.
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TSAI-MetaFraud: A Benchmark Dataset for Financial Fraud Transaction and Behavioral Risk Detection in Metaverse Ecosystems
Refat Ishrak Hemel, Ehsan Hallaji, Roozbeh Razavi-Far
Multimodal Graph Learning
  • Introduction of TSAI-MetaFraud, a comprehensive dataset for fraud detection in metaverse environments.
  • Integration of behavioral, transactional, and graph-structured information to reflect the complexities of virtual economies.
  • Definition of benchmark tasks for systematic evaluation of fraud detection methods.
  • Provision of baseline results using machine learning and graph neural network approaches.
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Super-Tuning: From Activation-Aware Pruning to Sparse Fine-Tuning
Ivan Ilin, Philip Zmushko, Peter Richtárik
NLP Large Language Models Efficient ML
  • Introduction of Super, a sparse PEFT method based on activation-weighted magnitude scores.
  • Development of Supra, a hybrid method combining Super with LoRA under a fixed parameter budget.
  • Evaluation of various sparse and low-rank adaptation methods on arithmetic reasoning tasks.
  • Demonstration that simple pruning-inspired metrics can effectively guide parameter-efficient tuning.
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Towards the Explainability of Temporal Graph Networks via Memory Backtracking and Topological Attribution
Yazheng Liu, Xi Zhang, Sihong Xie, Hui Xiong
Graph Learning Interpretability Time Series
  • Introduces a framework for explaining predictions in Temporal Graph Networks by considering both spatial and temporal factors.
  • Utilizes topology attribution and memory backtracking trees to quantify contributions from neighboring and historical events.
  • Addresses limitations of existing explanation methods that ignore the memory module's role in TGNs.
  • Demonstrates improved performance in providing faithful explanations compared to state-of-the-art methods.
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Similarity search generalisation in contrastive learning with InfoNCE loss
Nick Whiteley
Theory
  • Establishes a new perspective on InfoNCE loss by analyzing similarity search generalisation.
  • Introduces a continuity bound for InfoNCE loss that incorporates an inverse temperature parameter.
  • Demonstrates that increasing the number of negative samples stabilizes generalisation error for Lipschitz functions.
  • Provides a theoretical framework that complements existing interpretations of InfoNCE in terms of mutual information.
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