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
How Should Transformers Encode Numeric Values in Electronic Health Records?
Maria Elkjær Montgomery, Christian Igel, Mikkel Odgaard, Martin Sillesen, Mads Nielsen
NLP Optimization Time Series
  • Introduces a unified evaluation framework for numeric reasoning in EHR transformers.
  • Systematic comparison of discrete, continuous, and hybrid numeric value encodings reveals trade-offs in performance.
  • Hybrid token-based approaches with binning provide a robust alternative for numeric encoding.
  • All evaluated methods can perform approximate numeric computations reliably.
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Graph Classification via Network Usable Information: From Representation Evaluation to Structure Selection
Abdullah Shaik, Anwar Said
Graph Learning
  • NETINFOGC extends the NUI framework to graph classification, addressing representation-space mismatches.
  • The framework combines propagation-based descriptors with classical centrality measures to capture complementary structural information.
  • A training-free, clustering-based NUI estimation procedure provides a model-free proxy for representation quality.
  • Empirical findings indicate that degree centrality is a strong representation, often correlating closely with classification accuracy.
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SABER: A Semantic-Aligned Brain Network Analysis Framework via Multi-scale Hypergraphs
Yidan Xu, Xiangmin Han, Rundong Xue, Huihui Ye
Graph Learning NLP Large Language Models
  • SABER integrates LLM-derived semantics directly into brain network classification, enhancing decision-making.
  • The framework employs multi-scale hypergraphs to capture complex interactions among brain regions.
  • A decision-level semantic alignment mechanism allows for patient-specific semantic information to guide predictions.
  • SABER outperforms existing methods on brain network datasets, particularly in small-sample settings.
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A Physics-Regulated Neural Framework for Learning 3D Grain Growth Dynamics
Zhihui Tian, Kang Yang, Michael Tonks, Amanda R. Krause, Joel B. Harley
Efficient ML Theory
  • 3D-PRIMME effectively models 3D grain growth dynamics using a local evolution rule.
  • The model is trained on only two time steps but can predict grain growth over large spatial domains.
  • It maintains consistent kinetics and grain topology across significant increases in system size.
  • The framework operates with minimal supervision, making it data-efficient.
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TREK: Distill to Explore, Reinforce to Refine
Yuanda Xu, Zhengze Zhou, Kayhan Behdin, Jelena Markovic-Voronov, Hejian Sang, Xiaomin Li, Wenhui Zhu, Xinchen Du, Aida Rahmattalabi, Ran He, Sen Na, Zhipeng Wang, Alborz Geramifard
Reinforcement Learning Large Language Models NLP
  • TREK improves exploration support in GRPO by using distillation for exploration rather than imitation.
  • The method can utilize both external and internal proposal sources, making it broadly applicable.
  • TREK effectively identifies hard prompts and integrates verified solutions to enhance the student's sampling capabilities.
  • Significant performance improvements were observed in mathematical reasoning and agentic tasks.
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Integrating Physics-Informed Neural Networks for Safe Reinforcement Learning in a 1-DoF Helicopter System
Georg Schäfer, Jakob Rehrl, Stefan Huber
Reinforcement Learning Robotics Optimization
  • Integration of a differentiable physics model into the PPO algorithm for safe reinforcement learning.
  • Simulated future trajectories are used to penalize anticipated safety violations during training.
  • Demonstrated significant reduction in constraint violations while maintaining reliable target tracking.
  • Evaluation conducted on a simulated 1-DoF helicopter system with strict pitch constraints.
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HiFA4: Training-Free 4-bit FlashAttention on Ascend HIF4 NPUs for LLM Inference
Hui Dong, Yanzhao Li, Jie Gao, Chunlu Li, Zhiyuan Zhang, Yupeng Sun, Zhenyuan Chen, Zhiqiang Zou
NLP Large Language Models Efficient ML
  • HiFA4 is the first design for 4-bit FlashAttention evaluated on standard NLP benchmarks.
  • Introduces Smooth-QK and P-Reordering to improve quantization accuracy and efficiency.
  • Achieves a 37.5% recovery of accuracy gap on Qwen3-8B compared to direct HIF4 quantization.
  • Reduces the fraction of inconsistent predictions and accuracy regressions significantly.
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Conditional Inference Trees and Forests for Feature Selection
Robert Milletich, Justin Downes, Steve Goley, Newel Hirst
Theory Efficient ML Interpretability
  • CIT and CIF effectively reduce split-selection bias in feature selection.
  • CIF ranks 4th among 17 classification methods and 3rd among 18 regression methods in benchmark tests.
  • Adaptive stopping and threshold search significantly affect CIF runtime, with potential increases in fitting time by up to 10.8x.
  • The study identifies scenarios where forest feature sampling may exclude informative features.
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FedACT: Federated Adaptive Coordinate Trust Modulation for Robust Transformer Training under Data Heterogeneity
Shuai Li, Qinglin Wang, Ping Luo, Jiahuan Wang, Hongyang Hu, Haotian Mo, Yigui Feng, Ziang Liu, Qisong Xiao, Jie Liu, Tao Sun
Federated Learning Optimization Large Language Models
  • Identification of coordinate trust mismatch as a critical issue in federated AdamW training.
  • Introduction of FedACT, which reallocates update magnitudes based on coordinate-wise trust scores.
  • Demonstrated improvements in communication-round efficiency and training stability.
  • Extensive empirical validation across multiple model types, showing significant performance gains.
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What Does a Discrete Diffusion Model Learn?
Rodrigo Casado Noguerales, Bernhard Schölkopf, Thomas Hofmann, Aran Raoufi
Generative Models Theory Optimization
  • The negative ELBO is exactly equal to data entropy plus the path KL divergence, not just a bound.
  • The learned reverse process can be represented in three different ways: denoiser, cavity, and score.
  • Different noising processes share the same best achievable negative ELBO, which is the data entropy.
  • The paper resolves several puzzles in the literature regarding the optimization objectives of various diffusion models.
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A Near-Linear-Time Solver for Graph $p$-Laplacian Semi-Supervised Learning via Continuation in $p$
Oren E. Livne
Graph Learning Efficient ML Theory
  • Introduces a near-linear-time solver for graph p-Laplacian semi-supervised learning.
  • Addresses the degeneracy problem in traditional SSL methods when labeled data is limited.
  • Utilizes damped chord-Newton continuation in p for efficient solving of nonlinear systems.
  • Empirical results show significant speed and accuracy improvements over existing solvers.
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OmniFocus: Query-Guided Modality-Balanced Token Compression for Omni-Modal Large Language Models
Shijie Cao, Qingyu Zhang, Boxi Yu, Yuzhong Zhang, Boxi Cao, Yaojie Lu, Hongyu Lin, Xianpei Han, Le Sun
Multimodal Large Language Models Efficient ML
  • OmniFocus mitigates modality bias in token compression by using query-guided importance estimation for both audio and video.
  • The method preserves inter-modal association and intra-modal peak evidence, enhancing the quality of compressed outputs.
  • Experiments show that OmniFocus achieves high accuracy and efficiency, outperforming existing compression techniques.
  • The approach is training-free, making it accessible for practical applications in resource-constrained environments.
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Predicting Early Stages Of Alzheimer's Disease And Identifying Key Biomarkers Using Deep Artificial Neural Network And Ensemble Of Machine Learning Methodologies
Debopriya Ghosh
Theory
  • Developed an automated diagnostic system for early-stage Alzheimer's Disease.
  • Addressed data challenges such as missing values and class imbalance.
  • Utilized advanced feature selection techniques to improve model accuracy.
  • Implemented both ensemble and deep learning models for comparative analysis.
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SHiPPO: Recurrent Memory with Transported Polynomial Projections
Tomoya Mizuguchi, Bum Jun Kim
Theory Time Series NLP
  • SHiPPO enhances memory semantics in recurrent models through transported polynomial projections.
  • The framework allows for dynamic channel interactions, moving beyond fixed coordinate systems.
  • Empirical results show that SHiPPO can recover order-sensitive changes in memory that traditional methods cannot.
  • The methodology includes a restricted realization that maintains efficient updates and decoding.
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Robustness Meets Uncertainty: Evidential Adversarial Training for Robust Selective Classification
Nicolas Sournac, Ahmed Baha Ben Jmaa, Bertrand Braeckeveldt
Computer Vision Theory
  • Introduces a standardized benchmark for evaluating robustness and uncertainty in selective classification.
  • Proposes Evidential Adversarial Training (EV-AT) to improve both robustness and uncertainty quality.
  • Demonstrates that existing adversarial training methods often degrade uncertainty ranking despite improving robustness.
  • Shows through experiments that EV-AT enhances adversarial robustness while maintaining reliable uncertainty estimates.
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Probabilistic Low-Voltage Peak Load Forecasting with Time Series Foundation Models Evaluated on Application-Oriented Metrics
Benedikt Kaas, Manuel Treutlein, Hannes Benedikt Gerber, Oliver Neumann, Cheewan Phatthanakhuha, Oliver Resch, Ralf Mikut, Veit Hagenmeyer
Time Series
  • Evaluation of TSFMs for low-voltage load forecasting shows superior performance, especially for Chronos-2.
  • Ablation study indicates TSFMs can handle increased uncertainty without weather covariates.
  • Introduction of a novel application-oriented metric for assessing forecasting capabilities in grid asset planning.
  • The study utilizes a real-world dataset, ensuring relevance and applicability of results.
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Wind-Aware Reinforcement Learning Control of a Small Quadrotor Using Learned Onboard Wind Estimation in Simulated Atmospheric Turbulence
Abdullah Al Tasim, Wei Sun
Reinforcement Learning Robotics
  • Introduces a two-stage learning pipeline for wind estimation and control in small quadrotors.
  • Achieves high accuracy in wind estimation with a GRU network, even in unseen conditions.
  • Demonstrates a significant reduction in tracking error using a PPO controller informed by wind estimates.
  • Highlights the importance of wind perception, particularly in varying wind speeds.
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Towards Learning Representations of Policies in Two-Player Zero-Sum Imperfect-Information Games
Kevin Wang, Kevin Yang, Arjun Prakash, Amy Greenwald
Reinforcement Learning Theory
  • Introduction of methods for generating datasets of policies in two-player zero-sum games.
  • Development of various techniques for learning compact policy representations.
  • Creation of downstream tasks for evaluating the effectiveness of learned policy embeddings.
  • Demonstration of the presence of useful behavioral representations in learned embeddings.
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How to Allocate Your Tokens? Scaling Laws with Training Steps and Batch Size
Fabian Schaipp
Large Language Models Optimization Theory
  • Introduction of a three-term scaling law that considers model size, training steps, and batch size.
  • The proposed law can be fitted using fewer training runs, reducing the required data to 28%.
  • It provides a framework for understanding both optimal and suboptimal batch sizes in training.
  • The law aligns with previous empirical findings on critical batch sizes and extends to practical constraints.
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Grokking Is Conditional and Fragile: A Fully-Tractable, Multi-Seed Study at 12K Parameters
Yoshiyuki Ootani
Theory
  • Grokking is conditional on training-set coverage and output cardinality.
  • Weight decay reproduces the inverted-U relationship in grok-rate.
  • Grokking is sensitive to floating-point environment perturbations.
  • Task decomposition improves data efficiency and generalization.
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X-LogSMask: Expand Transformer for Graph-Structured Data
Leyan Li, Rennong Yang, Zhenxing Zhang, Liping Hu
Graph Learning
  • X-LogSMask introduces a logarithmic structural mask for graph data, enhancing the interpretability of attention mechanisms.
  • The method allows for multi-hop information propagation within a single Transformer layer, reducing the need for multiple message-passing layers.
  • Transformers with X-LogSMask achieve state-of-the-art performance on 13 datasets across various benchmarks.
  • The approach maintains the core Transformer architecture while effectively adapting it for graph-structured data.
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Geometry-Aware Bayesian Quantification via Compositional Data Analysis
Alejandro Moreo, Pablo González, Juan José del Coz
Theory
  • Introduces a geometry-aware KDE model for multiclass quantification that respects the simplex structure of compositional data.
  • Utilizes log-ratio transformations and Aitchison geometry to improve density estimation accuracy.
  • Implements shrinkage regularization to enhance robustness near simplex boundaries.
  • Demonstrates competitive performance against state-of-the-art quantifiers across various datasets.
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One Framework for All: Cross-Modal Membership Inference for Generative Models
Dayong Ye, Tainqing Zhu, Kun Gao, Junhao Liu, Yichuan Chen, Shuai Zhou, Hengzhu Liu, Bo Liu, Wanlei Zhou
Generative Models Multimodal
  • Introduces a unified framework for membership inference across multiple generative model modalities.
  • Utilizes the property of output distributions approximating training data distributions for effective inference.
  • Employs likelihood ratio testing without the need for training additional models.
  • Demonstrates superior performance compared to existing methods optimized for single model classes.
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Statistically Meaningful Geometry (SMG) Beyond the Euclidean Paradigm, with Application to Generative AI
Bing Cheng, Yi-Shuai Niu, Howell Tong, Shing-Tung Yau
Generative Models Theory Optimization
  • Introduction of the Statistically Meaningful Geometry (SMG) framework for over-parameterized models.
  • Development of a Two-Fold Inference Paradigm to enhance statistical inference in complex models.
  • Utilization of an Ehresmann connection as a dynamic geometric filter to isolate learning trajectories.
  • Addressing operational pathologies like generative hallucination and catastrophic forgetting in AI systems.
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BOUNDARY_SYNC: Measuring Communication-Induced Representational Coupling in Multi-Agent LLM Systems
Zewen Liu
Large Language Models NLP Multimodal
  • Boundary_Sync provides a standardized measurement for communication-induced representational coupling in LLMs.
  • Text communication leads to significant homogenization of outputs, while image communication shows comparable effects.
  • Group size influences the direction of coupling, with smaller groups potentially leading to diversification.
  • Coupling is stateless and dependent on immediate peer information, with no evidence of cumulative convergence.
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Multi-modal Rail Crossing Safety Analysis
Paimon Goulart, Chansong Lim, Nícolas Roque dos Santos, Yue Dong, Sheldon Peterson, Jia Chen, Evangelos E. Papalexakis
Multimodal
  • Integration of visual and structured data improves safety assessment of railway crossings.
  • Vision-Language Models (VLMs) are effective in analyzing multimodal data for risk scoring.
  • The proposed system identifies high-risk and low-risk crossings with significant accuracy.
  • The methodology addresses critical challenges in data preparation and model training.
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Single-Channel EEG-Based Cognitive Load Assessment in Online Learning: A Hybrid Deep Learning Approach
Rowan Hussein, Mohamed Ouf
Time Series
  • The hybrid CNN+LSTM+Attention model achieves up to 78.5% accuracy in cognitive load assessment.
  • Regularization techniques are crucial for reducing overfitting and improving model generalization.
  • The study advocates for subject-independent evaluation to better assess model performance across different learners.
  • An open-source evaluation pipeline and visualization tool are provided to enhance reproducibility and practical application.
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Quantize the Target, Quantize the Drafter: Efficient Inference with Qwen3.5-4B
Jaeyeon Kim, Jewon Lee, Bo-Kyeong Kim
Large Language Models Efficient ML Optimization
  • Achieved a 6.978× speedup in inference latency over the baseline model.
  • Utilized quantization-aware distillation to recover accuracy in the quantized target model.
  • Developed a block-diffusion drafter optimized for speculative decoding.
  • Implemented sliding-window attention to enhance long-context decoding efficiency.
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On the Design Space of Discrete Diffusion Online Adaptation for Molecular Optimization
Trevor Chen, Ariel Dai, Jason Yang, Riccardo De Santi, Daniel Khalil, Wenda Chu, Nate Gruver, Pranav Murugan, Alexander F. G. Goldberg, Maruan Al-Shedivat, Yisong Yue
Generative Models Optimization
  • The study explores the interactions among various design choices in online adaptation for molecular optimization.
  • Acquisition, reward shaping, and debiasing techniques provide complementary benefits, especially for small molecules.
  • The proposed online fine-tuning recipe outperforms offline methods and inference-time searches under fixed oracle budgets.
  • Replay mechanisms stabilize learning and maintain valid molecular exploration.
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Expander Sparse Autoencoders: Parameter-Efficient Dictionaries for Mechanistic Interpretability
Rodrigo Mendoza-Smith
Interpretability Efficient ML Large Language Models
  • Introduction of Expander SAEs, a parameter-efficient architecture for sparse coding.
  • Demonstrated a significant reduction in learned decoder values while maintaining high reconstruction fidelity.
  • Proposed a parallel implementation of OMP that improves decoding efficiency.
  • Theoretical proofs supporting the identifiability of k-sparse codes under specific conditions.
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FedAvg for HAR: Exploring the Tradeoff Between Personalized and Generalization Accuracy
Andrea De Luna, Susanna Peretti, Chiara Contoli, Alessandro Bogliolo
Federated Learning
  • FedAvg demonstrates improved personalization capabilities while maintaining generalization compared to centralized learning.
  • The performance tradeoff between personalization and generalization is influenced by factors like client data heterogeneity and class distribution.
  • New evaluation strategies, including activity class exclusion, provide deeper insights into federated learning dynamics.
  • Under stressful conditions, such as varying class distributions, the advantages of FedAvg may not be as pronounced.
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Self-explainable Operator Learning for Discovering Spatial Patterns in Functional Data
Mojgan Alishiri, Amirhossein Arzani
Interpretability
  • Introduces a self-explainable operator learning framework for improved interpretability.
  • Reformulates operator learning using integral equations to enhance transparency.
  • Enables direct interpretability by linking input regions to output predictions.
  • Demonstrates effectiveness in fluid flow problems, providing physically meaningful insights.
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Finite-Lag Operator Geometry of Recurrent Representations
Kanishka Reddy
Theory Time Series
  • Introduction of finite-lag operator geometry for recurrent representations.
  • Development of a conditional transport law and source-centered transport tensor.
  • Proof of structural results including affine covariance and estimator stability.
  • Demonstration of the framework's effectiveness in detecting deterministic recurrent motion.
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Signal or Noise? Understanding Generative Models for Real-World Sensor Time Series
Zitao Shuai, Zongzhe Xu, Yuntian Wu, Sirui Li, Tianhong Li, Yuzhe Yang
Generative Models Time Series
  • Introduction of SensorGen, a large-scale framework for evaluating generative models on sensor time series.
  • Flow-matching models demonstrate superior performance across diverse generation settings.
  • Signal properties, including demographic covariates and time-frequency modeling, enhance generation quality.
  • Generated signals provide practical benefits beyond visual realism, improving performance in downstream tasks.
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The Rollout Infrastructure Tax in Coding-Agent Reinforcement Learning
Daniel Thi Graviet, Lovre Pesut, Ivan Dagelic, Vedran Jukic, Ivan Burazin
Reinforcement Learning Efficient ML
  • Introduction of the 'rollout infrastructure tax' concept, highlighting the impact of execution substrate on RL performance.
  • Significant variations in cold-start latency and worker-hour requirements based on substrate choice.
  • Development of a controlled evaluation methodology for comparing execution substrates.
  • Identification of critical components contributing to the rollout infrastructure tax.
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A Mathematical Introduction to Diffusion Models
Jianfeng Lu
Generative Models Theory Optimization
  • Introduces a comprehensive mathematical framework for understanding diffusion models.
  • Establishes convergence guarantees for Langevin diffusion and its applications.
  • Analyzes sampling errors in discretized diffusion models and their implications.
  • Explores inference-time control techniques for trained diffusion models.
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DeadPool: Resilient LLM Training with Hot-Swapping via Zero-Overhead Checkpoint
Haotian Xie, Junlin Chen, Mingkai Zheng, Lishan Yang, Zhao Zhang
Large Language Models Efficient ML Optimization
  • DEADPOOL enables hot-swapping of failed nodes without job termination.
  • Introduces an asynchronous in-memory checkpointing strategy for optimizer states.
  • Achieves zero overhead during normal execution and rapid recovery from failures.
  • Evaluated on large-scale systems with significant model sizes and GPU counts.
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Spin-Weighted Spherical Harmonics Enable Complete and Scalable E(3)-Equivariant Networks
Chenxing Liang, Yuchao Lin, Andrii Kryvenko, Wendi Yu, Chuan Li, Jianwen Xie, Xiaofeng Qian, Shuiwang Ji
Theory Efficient ML Graph Learning
  • Introduction of SpinGTP to enhance the expressivity of E(3)-equivariant networks.
  • SpinGTP recovers antisymmetric interactions lost in previous tensor product formulations.
  • Demonstrated superior performance in tasks involving chiral materials and non-centrosymmetric geometries.
  • Achieves comparable accuracy to full CGTP while maintaining scalability.
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Environmental Drivers of Respiratory Disease: A District Level Analysis
Rahim Iqbal, Asfi Ahamed, Izzath Nisfer, Shazan Shaheed, Muhammadu Ilham, Nathali Athukorala, Madara Mendis, Nisansa de Silva, Sandareka Wickramanayake
Interpretability
  • Developed an 11-year panel dataset integrating environmental and health data across 25 districts in Sri Lanka.
  • Achieved high predictive accuracy for respiratory disease rates and PM2.5 concentrations using XGBoost models.
  • Identified air quality as the primary driver of respiratory health variance, significantly ahead of forest degradation.
  • Introduced the Forest-Air-Health (FAH) Risk Index to rank districts by environmental health risk.
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I2RiMA: Spectral Riemannian Representation with Temporal Attention for Mental Stress Detection based on EEG Signals
Cheng He, Kunyu Peng, Shangen Han, Jinming Ma, Jinhong Ding, Likun Xia
Time Series
  • I2RiMA constructs frequency-specific spatial covariance matrices to preserve discriminative patterns.
  • The model employs frequency cluster aggregation for effective feature selection and redundancy reduction.
  • An intra-inter slice attention module captures both local and global temporal dependencies in EEG data.
  • I2RiMA achieves state-of-the-art performance on multiple datasets with a compact model architecture.
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Physiological Noise Augmentation Improves Non-Invasive Brain-to-Speech
Benjamin Ballyk, Teyun Kwon, Miran Özdogan, Oiwi Parker Jones
Audio & Speech Time Series Multimodal
  • Introduction of Physiological Noise Augmentation (PNA) for non-invasive brain-to-speech decoding.
  • PNA improves decoder robustness by training on augmented data that includes physiological artifacts.
  • Achieved a 4.7% increase in decoding accuracy on the MegNIST dataset using EEGNet.
  • PNA complements traditional multi-trial averaging techniques to enhance performance.
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MKGR: Multimodal Knowledge-Graph Representation Learning for Cold-Start Protein-Protein Interaction Prediction
Wenbo Zhang
Multimodal Graph Learning
  • MKGR effectively combines protein sequence data with multimodal biomedical knowledge graphs for PPI prediction.
  • The framework introduces a bridge reconstruction objective to enhance graph learning under sparse conditions.
  • A pair-level gated fusion mechanism allows for adaptive integration of sequence and graph representations.
  • Experiments show significant performance improvements over traditional PPI prediction methods.
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Rank-Then-Act: Reward-Free Control from Frame-Order Progress
Yuriy Maksyuta, George Bredis, Ruslan Rakhimov, Daniil Gavrilov
Reinforcement Learning Computer Vision Multimodal
  • RTA enables learning control policies from video without environment rewards.
  • The framework uses a VLM trained as a progress scorer on shuffled video clips.
  • A correlation-based reward signal is introduced, leveraging Spearman rank correlation.
  • RTA outperforms existing methods on various control benchmarks.
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Stable Global Weighting of Flow Mixtures using Simplex Exponential Moving Average
Benjamin Wiriyapong, Oktay Karakus, Can Eyupoglu, Kirill Sidorov
Generative Models Optimization Theory
  • Introduces a two-stage framework for variational inference using normalising flows.
  • Employs a Simplex Exponential Moving Average for stable global weighting of flow mixtures.
  • Demonstrates improved performance on various posterior benchmarks compared to existing methods.
  • Decouples expert training from mixture optimization, enhancing stability and efficiency.
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Black-Box Inference of LLM Architectural Properties with Restrictive API Access
Christopher Ellis, Shreyas Chaudhari, Mei-Yu Wang, Leighton Barnes, Giulia Fanti, José M. F. Moura
Large Language Models NLP Theory
  • Introduces NightVision, a method for inferring LLM architectural properties under restrictive API access.
  • Demonstrates that hidden dimensions can be estimated without access to logit biases or top-k logits.
  • Empirical evaluation shows NightVision can recover hidden dimensions with 23% average relative error.
  • Depth and parameter count can be estimated with 53% average relative error for models with over 3 billion parameters.
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Scaling Laws for Grid-Based Approximate Nearest Neighbor Search in High Dimensions
Matthew J Liu, Wei Hang Zheng, Vidhan Purohit, Siqi Xie, Chieh-En Li, Jerry Li, Noah Flynn
Theory Efficient ML
  • Multiprobe grid algorithm shows favorable scaling properties in high-dimensional spaces.
  • Identified a unique d-scaling crossover where grid-based methods outperform others in throughput.
  • Near-linear scaling with dataset size (N) and lower indexing costs compared to traditional ANN methods.
  • Theoretical models derived for query cost and recall provide insights into algorithm performance.
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FlatManifold: Robust Continual Learning under Severe Label Noise and Domain Shifts via Intrinsic Manifold Flattening
Rai Hisada, Kanji Tanaka
Robotics Optimization Theory
  • FlatManifold effectively mitigates the effects of severe label noise and domain shifts in continual learning.
  • The framework utilizes a Nyström manifold flattening map for robust feature distribution mapping.
  • It incorporates a continual topology brake term to prevent catastrophic forgetting.
  • Extensive evaluations show superior performance compared to traditional continual learning methods.
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MPSelectTune: Prompt-type Selection for Fine-tuning improves Concept Unlearning in LLMs
Shubhadip Nag, Srinjoy Das, Agniva Saha, Anushree Ghosh, Soumi Das, Tarun Kumar, Suparna Bhattacharya, Sourangshu Bhattacharya
NLP Large Language Models
  • Introduces MPSelectTune for effective concept unlearning in LLMs.
  • Utilizes a two-stage approach combining Multi-Prompt Tuning and Selection Tuning.
  • Demonstrates significant improvements in main task accuracy while reducing concept accuracy.
  • Addresses the impact of prompt variation on unlearning performance.
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