AI-generated summaries

Today's ML research,
without the noise.

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

45 Papers today
8h Update frequency
7 Days of history
Fast and Accurate Anomaly Detection in Time Series
Emanuele Mele, Massimo Cafaro, Angelo Coluccia, Italo Epicoco
Time Series
  • Introduces a novel unsupervised anomaly detection algorithm based on Haar Discrete Wavelet Transform.
  • Addresses the challenges of class imbalance and high false positive rates in anomaly detection.
  • Demonstrates superior performance over existing unsupervised and self-supervised methods across 343 datasets.
  • Utilizes a rigorously derived t-test for assigning anomaly scores to observations.
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An Optimisation Framework for the Well-Conditioned Training of Physics-Informed Neural Networks
Joseph Webb, Sadok Jerad, Coralia Cartis
Optimization
  • Introduction of DSGNAR, a scalable second-order optimization framework for PINNs.
  • Achieves unprecedented accuracy and speed in solving PDEs compared to state-of-the-art methods.
  • Demonstrates significant improvements in relative ℓ2 errors across various complex problems.
  • Robust performance regardless of architecture, arithmetic precision, and initial hyperparameters.
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Multilayer Q-Matrix-Embedded Neural Network for Cognitive Diagnosis (M-QCDNet): Structure-Aware Deep Learning Architecture for Psychometric Interpretability
Yiyao Yang
Interpretability
  • M-QCDNet integrates Q-matrix structures into neural networks to enhance both predictive accuracy and interpretability.
  • The model introduces new interpretability metrics to evaluate the alignment of latent skill representations with cognitive theory.
  • M-QCDNet offers practical applications in educational settings for early detection of learning difficulties.
  • The architecture maintains psychometric meaning while leveraging the representation-learning capabilities of deep neural networks.
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Revisiting Decentralized Online Convex Optimization with Compressed Communication
Hao Zhou, Xiaoyu Wang, Chang Yao, Mingli Song, Yuanyu Wan
Optimization Theory Efficient ML
  • Introduction of two FTRL-type algorithms for D-OCO with compressed communication.
  • First algorithm matches existing regret bounds in a full-information setting.
  • Second algorithm improves regret bounds and communication costs in a bandit setting.
  • Simplified theoretical analysis compared to existing methods.
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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, an attack method for inferring LLM architectural properties under restrictive API access.
  • Demonstrates that hidden dimensions, depth, and parameter counts can still be recovered despite limited API information.
  • Achieves an average relative error of 23% for hidden dimensions and 53% for depth and parameter counts on large models.
  • Highlights the inadequacy of current API restrictions in safeguarding LLM architectural details.
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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, which generalizes from scalar functions to Spin-Weighted Spherical Harmonics.
  • SpinGTP overcomes the expressivity limitations of the Gaunt Tensor Product by recovering antisymmetric interactions.
  • The method maintains the computational efficiency of GTP while providing a more expressive equivariant basis.
  • Evaluation shows SpinGTP achieves comparable accuracy to full CGTP and excels in chiral and non-centrosymmetric tasks.
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Predicting Closed-Loop Performance of Latent World Models: Offline Checkpoint Selection for MPC and Model-Based RL Under Non-Markovian Rewards in LunarLander
Nikolai Smolyanskiy
Reinforcement Learning Robotics Optimization
  • Introduces a suite of 40 structural validation-time metrics for evaluating world models.
  • Proposes the Composite Reward Observability Fraction (CROF) for offline checkpoint selection.
  • Demonstrates that CROF effectively predicts closed-loop performance in non-Markovian reward settings.
  • Shows significant improvements in data efficiency and performance over traditional model-free approaches.
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Privacy-Preserving and Verifiable Approximate Distributed Coded Computing
Xavier Martínez-Luaña, Alba Gude-Santos, Manuel Fernández-Veiga, Rebeca P. Díaz-Redondo
Federated Learning Theory Efficient ML
  • Introduction of a unified framework for adversary-resilient distributed learning that addresses privacy and malicious behavior in both federated and decentralized settings.
  • Integration of GPBACC with robust aggregation strategies for federated learning to enhance privacy and security.
  • Application of approximate decode-and-compare and group testing techniques for decentralized learning to enable verification without a trusted aggregator.
  • Empirical evaluation of the framework through practical attack scenarios, demonstrating significant improvements in privacy preservation and adversary resilience.
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From Approximation to Emergence: A Theory of Deep Learning
Zhilin Zhao
Theory Optimization Generative Models
  • Synthesizes existing theoretical frameworks in deep learning into a coherent narrative.
  • Explores the implications of overparameterization and emergent behaviors in modern neural networks.
  • Clarifies the assumptions and limitations of various theoretical explanations in deep learning.
  • Focuses on approximation, optimization, and generalization while addressing additional complexities.
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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 Large Language Models Interpretability
  • SABER integrates LLM-derived semantics directly into brain network classification, enhancing decision-making.
  • The framework employs multi-scale hypergraphs to capture high-order interactions among brain regions.
  • A decision-level semantic alignment mechanism allows for patient-specific semantic information to guide predictions.
  • SABER outperforms existing methods in terms of performance and interpretability on benchmark datasets.
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Bayesian Sparse Low-Rank Adaptation for Large Language Model Uncertainty Estimation
Jijie Zhang, Zhe Ren, Quan Zhang, Dandan Guo
NLP Large Language Models Efficient ML
  • DALorRA shifts uncertainty quantification from dense parameter spaces to low-rank adaptation levels, minimizing computational overhead.
  • The framework integrates variational Bayesian estimation with ensemble-like inference, enhancing uncertainty quantification.
  • Extensive empirical validation shows DALorRA achieves excellent calibration and reasoning accuracy across diverse benchmarks.
  • The method dynamically adjusts the LoRA rank, addressing the limitations of fixed rank adaptations in low-data scenarios.
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SA-HGNN: Sample-Adaptive Hyperbolic Graph Neural Network for EEG-Based Depression Recognition
Yang Li, Pan Hu, Yan Zhang, Wenfan Yang, Tao Wu, Lianbo Guo
Graph Learning
  • SA-HGNN introduces a dynamic graph construction method tailored to individual brain networks.
  • Utilizes hyperbolic geometry to better capture hierarchical relationships in brain connectivity.
  • Incorporates an attention mechanism to reduce noise in EEG signals.
  • Demonstrates superior performance compared to traditional GNNs in EEG-based depression recognition.
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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 covariance matrices and maps them to the SPD tangent space.
  • 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 in cross-subject EEG stress detection.
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Domain Knowledge Based Temporal-Spatial Graph Convolution Network for ECG Recognition
Wenting Ma, Zhipeng Zhang, Xiaohang Yuan, Ningwei Xie, Yuxin Xie, Xiaolin Wang, Meng Guo, Xingang Chai, Zhenjie Yao
Graph Learning Time Series
  • Introduces a domain knowledge-based graph structure for ECG recognition.
  • Utilizes a double-stream directed graph model to capture both spatial and temporal information.
  • Achieves an average F1 score of 88.1% on the ECG classification task.
  • Demonstrates improved performance in detecting rare ECG categories.
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Certified World Models as Sensing Clocks: Drift-Aware Deadlines for Active Perception
Hongbo Wang
Robotics Reinforcement Learning Theory
  • Introduction of a certified sensing clock that indicates when to re-sense based on prediction validity.
  • Drift-aware deployment method improves the accuracy of sensing deadlines compared to traditional Lyapunov rates.
  • Demonstrated effectiveness on a frozen 3D VN-JEPA model, controlling certificate violations across multiple trials.
  • Significant reduction in eventful-tail violations compared to existing reactive scheduling methods.
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One More Time: Revisiting Neural Quantum States from a Reinforcement Learning Perspective
Juan Agustín Duque, Sergio García Heredia, Vinicius Hernandes, Eliška Greplová, Thomas Spriggs, Aaron Courville, Anna Dawid
Reinforcement Learning Optimization Theory
  • Introduces Proximal Wavefunction Optimization (PWO) for training Neural Quantum States.
  • Establishes a formal connection between variational energy minimization and policy-gradient reinforcement learning.
  • Demonstrates improved stability and convergence speed of NQS training compared to existing methods.
  • Fine-tunes a large-scale RWKV-7 model, showcasing the scalability of the proposed method.
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Program-as-Weights: A Programming Paradigm for Fuzzy Functions
Wentao Zhang, Liliana Hotsko, Woojeong Kim, Pengyu Nie, Stuart Shieber, Yuntian Deng
NLP Large Language Models Efficient ML
  • PAW allows for the compilation of fuzzy functions from natural language specifications into efficient neural artifacts.
  • The framework significantly reduces memory usage and increases execution speed compared to direct prompting of larger models.
  • FuzzyBench, a dataset of 10 million examples, is released to support the training of the neural compiler.
  • PAW demonstrates versatility across multiple applications, showcasing its ability to handle various fuzzy tasks.
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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 quadrotors.
  • Achieves high accuracy in wind estimation with a GRU network trained on simulated turbulence.
  • Demonstrates significant improvement in trajectory tracking using a PPO controller informed by wind estimates.
  • Highlights the regime-dependent value of wind perception in control performance.
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Beyond the Performance Illusion: Structure-Aware Stratified Partitioning and Curriculum Distributionally Robust Optimization for Spatially Correlated Domains
Prathamesh Patil, Arpit Jain, Aswanth Krishnan
Computer Vision Optimization
  • Identification of spatiotemporal leakage and hidden stratification as critical issues in performance evaluation.
  • Introduction of Structure-Aware Stratified Partitioning (SASP) to create better dataset splits.
  • Development of Curriculum Distributionally Robust Optimization (CDRO) to stabilize training under rigorous evaluation conditions.
  • Demonstration of improved generalization and confidence calibration across multiple domains.
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Role-Aware Neural Convex Divergence Heads for Asymmetric Representation Learning
He Huang, Lu Shen, Yunfeng Huang, Li Qi
NLP Theory Interpretability
  • Introduction of a role-aware neural convex divergence head for asymmetric representation learning.
  • The method retains classical Bregman properties while allowing for role-specific projections.
  • Empirical results show improved directional accuracy over traditional symmetric and unstructured methods.
  • The approach is versatile, functioning as a plug-in distance module for various encoders.
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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
  • Extensive evaluation of time series foundation models for low-voltage load forecasting.
  • Introduction of a novel application-oriented metric for assessing forecasting performance.
  • Demonstration of superior performance of Chronos-2 in peak load prediction.
  • Investigation of the impact of weather covariates on forecasting accuracy.
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SINA: A Fully Automated Circuit Schematic Image to Netlist Generator Using Artificial Intelligence
Saoud Aldowaish, Yashwanth Karumanchi, Kai-Chen Chiang, Mohammed Ayman Habib, Finn Murphy, Rishen Cao, Morteza Fayazi
Computer Vision NLP Multimodal
  • SINA automates the conversion of circuit schematic images to netlists, enhancing EDA workflows.
  • The system achieves high accuracy (96.67%) in netlist generation, surpassing state-of-the-art methods.
  • SINA effectively handles both IC and PCB schematics, including complex layouts and hand-drawn designs.
  • The integration of deep learning, OCR, and VLMs allows for robust component detection and reference designator assignment.
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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 protocol effectively measures representational coupling in multi-agent LLMs.
  • Text communication leads to significant homogenization of outputs (CAF=0.803).
  • Image communication also causes homogenization, comparable to text (CAF=0.834).
  • Group size influences the direction of coupling, with smaller groups potentially leading to diversification.
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QFedAgent: Quantum-Enhanced Personalized Federated Learning for Multi-Agent Activity Recognition
Quoc Bao Phan, Tuy Tan Nguyen
Federated Learning Multimodal Robotics
  • Introduction of QFedAgent, a quantum-enhanced personalized federated learning framework.
  • Utilization of variational quantum circuits for efficient multimodal data fusion.
  • Achieved approximately 10× reduction in parameters compared to classical methods.
  • Demonstrated high accuracy (97.7%) on the OPPORTUNITY dataset under non-IID conditions.
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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
  • The rollout infrastructure tax significantly affects the efficiency of coding-agent RL systems.
  • Cold-start latency can vary by up to 110× across different execution substrates.
  • The choice of substrate can lead to a 1.8× spread in projected worker-hours for large-scale rollouts.
  • Optimizing execution substrates should be a core concern in the design of coding-agent RL systems.
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Set Diffusion: Interpolating Token Orderings Between Autoregression and Diffusion for Fast and Flexible Decoding
Marianne Arriola, Volodymyr Kuleshov
NLP Large Language Models Generative Models
  • Set diffusion allows for flexible-length and flexible-position token generation, enhancing decoding flexibility.
  • The set-causal diffusion architecture supports KV cache updates after each inference step, improving efficiency.
  • Set diffusion outperforms previous diffusion models in speed-quality tradeoffs across various tasks.
  • The model demonstrates superior infilling performance compared to block diffusion.
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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
  • The system combines visual data from railway crossing images with structured accident history data.
  • It utilizes Vision-Language Models to analyze and assess crossing safety from a highway user's perspective.
  • The proposed pipeline achieves a macro F1 score of 0.757 for risk classification.
  • The model estimates FRA safety scores with an RMSE of 0.078, indicating strong predictive capability.
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Do LLMs Truly Generalize in the Molecular Domain? A Perturbation-Based Analysis
Jiatong Li, Weida Wang, Changmeng Zheng, Shufei Zhang, Yatao Bian, Xiao-yong Wei, Qing Li
Large Language Models Graph Learning
  • LLMs show limited generalization in the molecular domain, with performance sensitive to small structural changes.
  • The Molecular Perturbation framework reveals that even single edits can significantly degrade model performance.
  • In-Context Tuning (ICT) can improve robustness by anchoring predictions to structurally similar molecules.
  • Current LLMs prioritize textual coherence over topological consistency, leading to fragility in predictions.
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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-structured data, enhancing interpretability and efficiency.
  • The method allows multi-hop information propagation within a single Transformer layer by assigning different powers of the adjacency matrix to attention heads.
  • Transformers with X-LogSMask achieve state-of-the-art performance on 13 datasets across various benchmarks.
  • The approach maintains the original Transformer architecture while improving its applicability to graph data.
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Finite-Lag Operator Geometry of Recurrent Representations
Kanishka Reddy
Theory Time Series Optimization
  • Introduces finite-lag operator geometry for analyzing recurrent representations.
  • Develops a conditional transport law and source-centered transport tensor to capture dynamics.
  • Proves structural results including affine covariance and estimator stability.
  • Demonstrates the ability to detect deterministic recurrent motion not visible to traditional methods.
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Model Merging as Probabilistic Inference in Fine-Tuning Parameter Space
Long Minh Bui, Tuan Anh Le Van, Tung Phi Duc, Phi Le Nguyen, Jana Doppa, Trong Nghia Hoang
Theory Optimization Efficient ML
  • Introduces a probabilistic framework for model merging that improves upon traditional geometric approaches.
  • Demonstrates that existing methods can be viewed as special cases of the proposed product-of-experts formulation.
  • Addresses the mismatch between Gaussian assumptions and heavy-tailed distributions of directional residuals.
  • Implements a heavy-tailed PoE design using Cauchy experts for better model merging outcomes.
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Extreme Adaptive Transformer for Time Series Forecasting
Sanjeev Shrestha, Hui Liu, Yifan Zhang
Time Series
  • Introduction of the Extreme-Adaptive Attention mechanism that dynamically adjusts query-key interactions based on event severity.
  • Exformer is an encoder-only Transformer framework designed specifically for long-term time series forecasting.
  • Demonstrated superior performance in forecasting accuracy on hydrologic datasets compared to existing state-of-the-art models.
  • Reduction in computational costs while maintaining effective modeling of imbalanced time series data.
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A Mathematical Introduction to Diffusion Models
Jianfeng Lu
Generative Models Theory Optimization
  • Introduces diffusion models from a mathematical perspective, emphasizing sampling dynamics.
  • Establishes convergence guarantees for Langevin diffusion and its variants.
  • Analyzes discretization of continuous diffusion models into practical samplers.
  • Explores inference-time control techniques for trained models.
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Do Newer Lightweight CNNs Perform Better Under Resource Constraints? A Controlled Multigenerational Study of Architecture, Initialization, Training Budget, and Efficiency
Tasnim Shahriar
Computer Vision Efficient ML
  • EfficientNetV2-S and RepViT-M1.0 lead in accuracy for CIFAR-10/CIFAR-100 and Tiny ImageNet, respectively.
  • EfficientNet-B0 offers a strong balance of accuracy and resource efficiency across all datasets.
  • MobileNetV3-Small is the fastest model with the lowest GMAC count, performing well under severe resource constraints.
  • The study highlights the importance of controlled benchmarking in evaluating model performance.
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kNNGuard: Turning LLM Hidden Activations into a Training-Free Configurable Guardrail
Mahmoud Abdelfattah, Hamid Nasiri, Peter Garraghan
NLP Large Language Models Efficient ML
  • kNNGuard operates in the activation space of a frozen LLM, eliminating the need for fine-tuning.
  • The framework achieves competitive or superior F1 scores compared to state-of-the-art fine-tuned guardrails while running significantly faster.
  • Domain adaptation is simplified to updating a small reference bank, allowing for rapid deployment.
  • The methodology includes a layer-ensemble and a fused-ensemble approach to enhance classification accuracy.
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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 improved PPI prediction.
  • The introduction of a bridge reconstruction objective enhances the robustness of graph learning in sparse data scenarios.
  • A pair-level gated fusion mechanism allows for adaptive integration of sequence and graph representations tailored to specific protein pairs.
  • Experimental results indicate significant performance improvements over traditional PPI prediction methods in cold-start settings.
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HERMES: A Multi-Granularity Labeling Substrate for Pre-training Data Mixtures
Ziyun Qiao, Yue Min, Ruining Chen, Yujun Li
NLP Large Language Models Optimization
  • HERMES introduces a hierarchical labeling substrate that allows for multiple granularities from a single document annotation.
  • The method employs a Learned Semantic Transform and a three-stage RVQ for efficient document labeling.
  • HERMES achieves competitive clustering performance while enabling flexible exploration of data mixtures.
  • The study highlights the importance of sampling strategies in optimizing model performance across different granularities.
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Liquid Latent State Dynamics for Interpretable Turbofan Degradation Modeling
Weizhi Nie, Weijie Wang, Yuting Su
Time Series Interpretability
  • Introduces liquid neural networks for modeling turbofan degradation dynamics.
  • Factorizes latent state into degradation and condition components for better interpretability.
  • Achieves improved sensor forecasting accuracy on the C-MAPSS benchmark.
  • Demonstrates a clearer temporal degradation axis compared to traditional models.
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Multi-Head Recurrent Memory Agents
Jiatong Li, Samuel Yeh, Sharon Li
Large Language Models NLP Efficient ML
  • Identifies memory retention failure as the main issue in recurrent memory agents for long contexts.
  • Proposes a novel Multi-Head Recurrent Memory (MHM) framework to improve memory retention.
  • Introduces MHM-LRU, a lightweight implementation that guarantees uniform head utilization.
  • Demonstrates significant improvements in memory retention and end-to-end accuracy across various benchmarks.
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Beyond Adam: SOAP and Muon for Faster, Label-Efficient Training of Machine Learning Interatomic Potentials
Gil Harari, Yoel Zimmermann, Ola Tangen Kulseng, Laura Zichi, Chuin Wei Tan, Marc L. Descoteaux, Boris Kozinsky
Optimization Efficient ML
  • SOAP and SOAP-Muon optimizers significantly improve convergence speed and accuracy compared to AdamW.
  • The performance of optimizers is particularly enhanced under conditions of partial force supervision.
  • SOAP-Muon can match the performance of AdamW trained with full force labels while using only 50% of the labels.
  • The resulting MLIPs maintain physical fidelity, even with minimal force supervision.
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A More Accurate Algorithm Comparison through A/B Testing using Offline Evaluation Methods
Koki Konishi, Masataka Ushiku, Yuta Saito
Theory Optimization
  • A/B testing can have a higher algorithm selection error rate than offline evaluation methods.
  • The proposed estimator introduces a hypothetical middle algorithm to induce positive correlation.
  • The new method improves sample efficiency by achieving the same error rate with half the data.
  • Bias-variance analysis supports the advantages of the proposed estimator over traditional methods.
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Efficient Temporal Point Processes via Monotone Alternating Splines
Cheng Wan, Quyu Kong, Feng Zhou
Time Series Efficient ML Theory
  • Identifies fundamental limitations of Monotone Neural Networks in CCIF modeling.
  • Introduces Monotone Alternating Splines as a flexible and efficient alternative.
  • Establishes a theoretical foundation for MAS, including generalization error analysis.
  • Demonstrates superior performance of MAS on synthetic and real-world datasets.
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Self-Gating Attention for Efficient Time Series Forecasting
Dezheng Wang, Tong Chen, Wei Yuan, Congyan Chen, Shihua Li, Hongzhi Yin
Time Series Efficient ML
  • Introduction of Self-Gating Attention (SGA) to reduce computational complexity in time series forecasting.
  • SGA utilizes a shared learnable matrix for common attention patterns and a residual component for input-specific variations.
  • Achieves linear time and memory complexity, making it suitable for resource-constrained environments.
  • Demonstrates competitive performance on nine real-world datasets compared to traditional self-attention mechanisms.
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IonSense-QKG: A Quantum-Readiness Metadata Framework for Lithium-Ion Battery Dataset Discovery
Sakthi Prabhu Gunasekar, Prasanna Kumar Rangarajan
Theory Optimization Time Series
  • Introduction of IonSense-QKG, a metadata framework for lithium-ion battery datasets.
  • Enrichment of dataset metadata with quantum-relevant fields to aid in dataset discovery.
  • Development of a Quantum Readiness Score (QRS) for ranking datasets based on their suitability for hybrid quantum-classical machine learning.
  • Demonstration of SQL-style queries for efficient dataset discovery.
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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 in LLM training without job termination.
  • The system employs an asynchronous in-memory checkpointing strategy to achieve zero overhead during normal execution.
  • Recovery from node failures is completed in under 40 seconds, demonstrating high efficiency.
  • The approach is evaluated on up to 512 GPUs and 65 billion parameter models, showing scalability.
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