AI-generated summaries

Today's ML research,
without the noise.

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

64 Papers today
8h Update frequency
7 Days of history
Adversarial Attacks on Online Handwriting using Salience-based Temporal Editing
Yataro Tamura, Brian Kenji Iwana, Jiseok Lee
Time Series
  • Introduces a new adversarial attack framework for online handwriting recognition based on temporal editing.
  • Demonstrates the inadequacy of spatial perturbations for time series data in maintaining handwriting quality.
  • Achieves stronger one-shot black-box transferability compared to conventional image-based attacks.
  • Preserves the visual structure of handwriting while effectively targeting model vulnerabilities.
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From Novice to Expert: Cost-Aware Bandits for Evolving Worker Performance in Crowdsensing
Yin Huang, Qingsong Liu, Jie Xu
Optimization Theory
  • Introduces a structured bandit model for evolving worker performance in crowdsensing.
  • Develops the CATI-UCB algorithm to optimize worker selection under budget constraints.
  • Demonstrates the importance of accounting for learning dynamics in worker performance.
  • Provides theoretical guarantees for the proposed method's performance.
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Data-Efficient Adaptation of LLMs via Attention Head Reweighting
Tuomas Oikarinen, Zixiao Chen, Charlotte Siska, Tsui-Wei Weng, Chandan Singh, Jianfeng Gao
NLP Large Language Models Efficient ML
  • Introduces Attention Head Reweighting (AHR) for data-efficient adaptation of LLMs.
  • AHR learns only one scalar per attention head, drastically reducing trainable parameters.
  • Outperforms standard baselines like LoRA with 200-1000 times fewer parameters.
  • Demonstrates significant accuracy improvements in security-related text classification tasks.
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Algebraic Representability as the Limiting Regime of Grokking: An Exactly Solvable Model with Holomorphic Activations
Chon-Fai Kam, Xavier Cadet, Miloud Bessafi, Frederic Cadet
Theory
  • Introduces an algebraic characterization of representability in neural networks.
  • Demonstrates that representability constraints affect both memorization and generalization.
  • Finds that non-representable tasks cannot be fitted even on training data.
  • Establishes a binary outcome in performance: instant success or failure, with no grokking.
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TSSM: Triaxial State Space Model for Global Station Weather Forecasting with Temporal-Variable-Historical Modeling
Songru Yang, Zili Liu, Tao Han, Ben Fei, Fenghua Ling, Lei Bai, Chang Liu, Xiangyang Ji, Zhenwei Shi, Zhengxia Zou
Time Series
  • Introduction of the Triaxial State Space Model (TSSM) for improved weather forecasting.
  • Utilizes a history-enhanced Temporal-Variable-Historical paradigm to capture long-term weather patterns.
  • Achieves state-of-the-art performance on the Weather-5K dataset with significant accuracy gains.
  • Demonstrates robustness in forecasting under missing observations.
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An Agentic AI Scientific Community for Automated Neural Operator Discovery
Luis Loo, Ulisses Braga-Neto
Theory Large Language Models Optimization
  • Introduces an agentic AI framework for neural operator discovery using a community of virtual labs.
  • Demonstrates the effectiveness of LLM agents in proposing diverse neural architectures.
  • Finds that LLM agency is crucial for maintaining architectural diversity in the discovery process.
  • Establishes a no-free-lunch theorem for neural operators, indicating no universal winner across problems.
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Scalable Optimal Transport Algorithm for Network Alignment
Elaheh Hassani, Durga Mandarapu, Qi Yu, Hanghang Tong, Ariful Azad
Graph Learning Optimization Efficient ML
  • Introduction of FastAlign, a scalable framework for OT-based network alignment.
  • Preservation of the original OT formulation while optimizing for sparsity.
  • Development of a custom SpMM algorithm tailored for network alignment tasks.
  • Significant runtime improvements over existing methods, achieving up to 32.54× speedup on GPU.
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Mechanical Analysis of Parachute Suspension Line Deployment with Binding Tapes Using PINN
Xiang Zhao, Ronghui Quan, Yaqi Xiao, Junlin Chen
Theory Optimization
  • Development of a PINN algorithm for predicting tension in parachute suspension lines.
  • Investigation of the impact of binding tape parameters on line dynamic tension.
  • Validation of the PINN framework against flight test data and conventional numerical methods.
  • Improved computational efficiency and accuracy in tension prediction compared to traditional methods.
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How the Hessian-Spectrum of Neural Networks Depends on Data
Jasraj Singh, Enea Monzio Compagnoni, Antonio Orvieto
Theory Optimization
  • The Hessian matrix is crucial for understanding optimization dynamics and generalization in neural networks.
  • The sharpness of neural network solutions is related to the class distribution in the training data.
  • The authors derive eigenvalues of the Hessian for linear networks, extending previous theoretical frameworks.
  • Empirical validation shows that predictions remain robust even when relaxing common assumptions.
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Gauge-Invariant, Parameter-Insensitive Regularization for Potential Recovery from Flow on Directed Graphs
Mohammad Forouhesh
Graph Learning Theory Optimization
  • Introduces gauge-invariant regularization that prevents inversion of potential ordering.
  • Demonstrates parameter-insensitivity across four orders of magnitude in regularization strength.
  • Proves that the new method preserves dynamic range and maintains high rank correlation.
  • Applies the gauge invariance concept to improve performance in graph neural networks.
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From Geometric Recovery to Causal Validation: A Reproducible Audit of Sparse Autoencoder Features, from Superposition Geometry to Causal Inertness
Mohamed Abdessalem Bal
Interpretability
  • Demonstrates the inadequacy of current evaluation metrics for Sparse Autoencoders, highlighting the need for causal validation.
  • Introduces the sae-causal-audit tool for rigorous auditing of feature relevance in machine learning models.
  • Finds that a significant percentage of features with high cosine similarity are causally inert, questioning their interpretability.
  • Proposes a new framework for reproducibility in machine learning, emphasizing the importance of semantic equality over byte-exactness.
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CARE-LoRA: Compressed Activation REconstruction for Memory-Efficient LoRA
Gengyu Zhang, Haiyin Ran, Zhengbao He, Yuhang Liu, Hanling Tian, Zhehao Huang, Xiaolin Huang
NLP Large Language Models Efficient ML
  • CARE-LoRA effectively reduces memory usage during LoRA fine-tuning by compressing activations.
  • The framework maintains the trainability of LoRA matrices while keeping memory overhead low.
  • Empirical results show that CARE-LoRA outperforms LoRA-FA and achieves better performance than standard LoRA when memory is reinvested into higher ranks.
  • The method is applicable across diverse tasks, demonstrating its versatility and efficiency.
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LIDAR-AD: A Decoder-Free Latent-Interaction Dreamer with Action-Residual Chains for Autonomous Driving
Yongzhi Liu, Yang Xiao, Zhong Cao, Zeng Kang, Sunan Zhang, Zhaozhi Dong, Guojun Yu, Weichao Zhuang
Reinforcement Learning Robotics Optimization
  • Introduces a decoder-free latent interaction model for autonomous driving.
  • Focuses on risk-relevant relationships and reduces redundancy in observations.
  • Implements residual action updates for improved continuous control.
  • Demonstrates superior performance in simulated and real-world driving scenarios.
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OrDA: Orthogonal Disentanglement of Access Habits Framework for Homepage Marketing Block Recommendations
Lingxiao Zhang, Xiaobo Li, Tao Xu
Theory
  • Introduces a novel framework (OrDA) to disentangle user interests from habitual access patterns in recommendation systems.
  • Identifies and formalizes the concept of 'Pseudo-Positives' caused by habitual clicks, providing a new perspective on bias in recommendations.
  • Utilizes a dual-tower architecture with orthogonal regularization to ensure rigorous separation of interest and habit signals.
  • Demonstrates superior performance over state-of-the-art methods in large-scale empirical evaluations.
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Local Redundancy: An Information-Theoretic Measure of Plasticity from Synthetic Memorization
Jiaxuan Cheng
Theory Optimization Time Series
  • Local redundancy is a principled measure of plasticity based on information theory.
  • It provides a lower bound on plasticity that can be computed efficiently using gradient norms.
  • Local redundancy correlates better with future task performance than traditional plasticity metrics.
  • The measure aids in selecting optimal pretraining checkpoints for improved adaptation.
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STKAN: Kolmogorov-Arnold Networks for Spatio-Temporal Forecasting
Sicong Lai, Yuehong Hu, Siru Zhong, Si Qiao, Yuxuan Liang, Guangyin Jin
Time Series Graph Learning
  • Introduction of STKAN, a KAN-based architecture for spatio-temporal forecasting.
  • Incorporation of Taylor-polynomial KAN mappings into spatial and temporal token-mixing modules.
  • Development of a learnable soft node-group assignment mechanism for compact spatial representations.
  • Demonstration of competitive performance on five traffic forecasting benchmarks.
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Disentangling Knowledge States with Ability and Proficiency Modeling for Knowledge Tracing
Duantengchuan Li, Yingqian Bi, Jinsong Chen, Rui Zhang, Mingwen Tong
Theory Time Series Interpretability
  • Introduction of Phase-Aware Knowledge Tracing (PAKT) framework for modeling knowledge states.
  • Decomposition of student interaction sequences into ability and proficiency phases.
  • Utilization of a multi-branch Transformer architecture for phase-specific modeling.
  • Causal analysis revealing biases in traditional phase-agnostic KT models.
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Cluster-Weighted EDMD
Lorenzo Tomaz, Judd Rosenblatt, Flavio Kicis, Thomas B. Jones, Diogo Schwerz de Lucena
Theory Time Series
  • CW-EDMD learns state space partitions and corresponding Koopman operators simultaneously.
  • The method utilizes an Expectation-Maximization algorithm to assign responsibilities based on proximity and prediction accuracy.
  • CW-EDMD significantly outperforms standard EDMD in multiple dynamical systems, particularly in challenging configurations.
  • The approach demonstrates residual-awareness, allowing for better prediction in regions where the model is more accurate.
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Maximally Robust Satisficing Bayesian Optimization
Samuli Kinnunen, Petrus Mikkola, Antti Niskanen, Arto Klami
Optimization
  • Introduces the concept of satisficing solutions in Bayesian optimization.
  • Focuses on robustness to input perturbations as a selection criterion.
  • Presents a new optimization method (MRSBO) that efficiently finds robust satisficing solutions.
  • Demonstrates superior performance of MRSBO compared to existing methods.
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What Makes a Representational Prior Work? Feature Families, Label-Free Invariances, and Critical Windows in Grokking
Gunner Levi Howe
Theory
  • Feature-family alignment is critical for enabling generalization in machine learning models.
  • Label-free invariance priors can outperform label-supervised methods in terms of generalization speed.
  • The timing of prior application is essential, with early exposure providing the most significant benefits.
  • Coherent but incorrect feature families can block generalization, behaving similarly to random noise.
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RF Spectrogram Anomaly Detection with Quantum Kitchen Sinks: Architecture, Representation, and Hardware Validation
Abdallah Aaraba, Alexis Vieloszynski, Remon Polus, Ola Ahmad, Soumaya Cherkaoui
Theory Efficient ML Time Series
  • Introduction of a novel QKS architecture for RF spectrogram anomaly detection.
  • Validation of the QKS approach on real quantum hardware, bridging theory and practical application.
  • Demonstration of superior performance of QKS over classical methods in detecting anomalies.
  • Development of a comprehensive dataset combining real and synthetic RF signals for robust testing.
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Is the Statistical Advantage Worth the Cost? An Empirical Comparison of KANs and MLPs for Structured Data Classification
Matthew Steven P. Toledo, Justine Raphael H. Jacinto, Vivekjeet Singh Chambal, Rodolfo C. Camaclang III, Jamlech Iram N. Gojo Cruz, Reginald Neil C. Recario
Theory Efficient ML Interpretability
  • KANs statistically outperform MLPs in binary and multiclass classification tasks.
  • KANs achieve a significant aggregate performance advantage across diverse datasets.
  • The medium effect size indicates a trade-off between performance and computational complexity.
  • KANs are recommended for high-precision applications, while MLPs are suitable for resource-limited scenarios.
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Saturation Makes Quantization Error Additive: A Coverage Model with a Certificate
Joshua Hill
Theory Efficient ML Optimization
  • 85-93% of quantization loss variance can be explained by per-layer effects.
  • A coverage model accurately predicts configuration loss based on saturation effects.
  • Traditional sensitivity measures can significantly misestimate quantization loss.
  • The proposed models achieve lower KL divergence in layer allocation compared to existing methods.
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Beyond Backbone Backpropagation: A Decoupled Strategy for Efficient Transfer Learning
Daniel Vila-Cruz, Laura Morán-Fernández, Verónica Bolón-Canedo
Efficient ML Computer Vision
  • Introduction of a decoupled framework that eliminates backbone backpropagation.
  • Normalization tuning is proposed for efficient domain adaptation.
  • Margin-based weighted training enhances the classifier's performance.
  • Achieves competitive accuracy on medical benchmarks with reduced training time.
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Fisher Rank Inflation: A Spectral Signature of Memorization under Label Noise
Satwik Bathula, Anand A. Joshi
Theory
  • Fisher Rank Inflation is identified as a spectral phenomenon linked to memorization under label noise.
  • Corrupted labels inflate effective rank by spreading spectral mass into low-energy eigendirections.
  • The study provides a first-order attribution formula that highlights the contribution of corrupted examples to rank inflation.
  • Empirical validation shows consistent inflation-collapse dynamics across multiple datasets and architectures.
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Repairing Shape-Prior Shortcuts in Long-Range Single-Shot Fringe Projection Profilometry
Adam Haroon, Cody Fleming, Beiwen Li
Computer Vision Robotics Interpretability
  • Introduction of PhiCalNet architecture that outputs wrapped-phase representation instead of direct depth.
  • Significant reduction in mean absolute error (MAE) from 14.54 mm to 4.46 mm in depth recovery.
  • Demonstration of the ineffectiveness of traditional methods to eliminate shape-prior shortcuts through data or model capacity.
  • First application of pixel-wise conformal uncertainty quantification in fringe projection profilometry.
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Tabular Foundation Models for Discrete Choice Estimation
Liu Liu, Dan Zhang
Theory Efficient ML Optimization
  • TFMs can be adapted for discrete choice estimation by addressing structural mismatches.
  • The proposed reformulation captures choice-set dependence and individual heterogeneity.
  • The new approach outperforms traditional hierarchical Bayesian methods in predictive accuracy and speed.
  • Fine-tuning on population data enhances performance for consumers with shallow purchase histories.
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MetaPerch: Learning from metadata for bioacoustics foundation models
Mustafa Chasmai, Vincent Dumoulin, Jenny Hamer
Audio & Speech Multimodal
  • MetaPerch utilizes metadata as auxiliary supervision to improve species identification in bioacoustics.
  • The model is trained using a multi-task learning approach, addressing challenges related to metadata availability and spurious correlations.
  • Extensive experiments show that metadata significantly enhances model performance across diverse datasets.
  • The study provides insights into the importance of different metadata modalities and training design choices.
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The Spectrum Is Not Enough: When Context Helps Time-Series Forecasting
Mert Onur Cakiroglu, Mehmet Dalkilic, Hasan Kurban
Time Series
  • Distinction between series-level predictability and configuration-level context value.
  • Introduction of the 'coverage deficit' as a diagnostic tool for forecasting.
  • Demonstration that spectral indices do not capture the benefits of context due to phase randomization.
  • Validation of findings across multiple benchmarks, showing varying context value.
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Mono-Z Dark Matter Search with Neural Spline Flows Using CMS Run 2015D Open Data
Hitesh Rasineni, Bhavishya Chebrolu
Generative Models Theory
  • First application of Neural Spline Flows in a mono-Z dark matter search.
  • Utilizes CMS Run 2015D open data with a focus on leptonically decaying Z bosons.
  • Defines a signal region based on kinematic observables and employs a control region for background modeling.
  • Sets upper limits on signal strength parameters for scalar, vector, and axial-vector mediators.
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MxGPS: Multiplex Graph Transformers for a Power Grid Foundation Model
Charilaos Papaioannou, Ioannis Tsantilas, Dimitris Giannakakos, Vasilis Michalakopoulos, Sotiris Pelekis, Vangelis Marinakis, Arsam Aryandoust, Antonello Monti, Ricardo J. Bessa, Perdo P. Vergara, Jochen Cremer, Elissaios Sarmas
Graph Learning
  • Introduces MxGPS to combat topology overfitting in GNNs for power grids.
  • Utilizes a multiplex architecture with shared node encoding and task-specific branches.
  • Achieves 0% boundary violation rate on unseen topologies.
  • Demonstrates significantly reduced degradation under topology shifts compared to traditional models.
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A VAE-Driven Multi-Task Satellite-Aided Semantic Communication Framework for 6G-Enabled Connected Autonomous Vehicles
S. M. Abtahiul Alam, Niloy Das, Apurba Adhikary, Yu Qiao, Zhu Han, Choong Seon Hong
Computer Vision Generative Models Robotics
  • Introduction of a VAE-based framework for semantic communication in CAVs.
  • Utilization of probabilistic latent representations to enhance robustness in noisy satellite channels.
  • Joint optimization of traffic sign reconstruction and classification tasks.
  • Significant bandwidth reduction achieved while maintaining performance.
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AI-Augmented Adaptive Digital Twin Modeling for Brain Tumor Evolution Prediction and Treatment Scheduling
Wenxi Liu, Michael Trimboli, Xianqi Li
Optimization Theory Interpretability
  • Introduces an AI-augmented digital twin framework for brain tumor modeling.
  • Combines reaction-diffusion modeling with residual learning for improved accuracy.
  • Demonstrates significant reductions in prediction errors and improvements in tumor burden estimates.
  • Shows effectiveness of model predictive control in optimizing treatment scheduling.
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From Preimage Search To Source-Grounded Feature Inversion
Kaixiang Shu
Interpretability
  • Introduces source-grounded feature inversion for improved neural network interpretability.
  • Conditions feature inversion on local network geometry, ensuring sample-specific results.
  • Utilizes closed-form matrix Wiener maps for correcting backpropagation signals.
  • Demonstrates effectiveness across diverse neural network architectures.
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Institutional Equity Holdings Prediction Using Node Affinities of Dynamic Graphs
Emad Izadifar, Zahed Rahmati
Graph Learning Time Series
  • Introduces the first benchmark for institutional equity holdings prediction using temporal graph machine learning.
  • Frames holdings prediction as a node affinity prediction task on a bipartite graph of managers and securities.
  • Achieves state-of-the-art performance with the NAVIS model, significantly outperforming competitors.
  • Demonstrates that temporal and structural signals in the ownership graph capture most predictive information.
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Sparse Autoencoders for Interpretable Out-of-Distribution Detection
Ayush Karmacharya, Luke Luschwitz, Lucia Romero, Yanan Niu, Joseph Campbell
Computer Vision Interpretability
  • SAID improves OOD detection performance by utilizing sparse autoencoders on intermediate layer activations.
  • Intermediate layers contain valuable discriminative information often lost in final-layer representations.
  • The method provides interpretable insights into the activation of learned concepts, aiding in understanding distribution shifts.
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Reassessing Muon for Matrix Factorization
Ali Parviz, Gal Mishne, Alex Cloninger
Optimization Theory
  • Muon optimizer's advantages are context-dependent and sensitive to hyperparameter tuning.
  • In low-rank matrix factorization, Muon does not consistently outperform AdamW.
  • Muon retains an advantage in nonnegative matrix factorization due to its orthogonalized updates.
  • The study highlights the importance of controlled benchmarks for evaluating optimizer performance.
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VAIOM: Continuous-Input, Discrete-Output Decoder-Only Financial Sequence Modeling
Yiming Ma, Xinyu Chen
Time Series
  • VAIOM separates input representation from output likelihood, allowing for continuous financial data processing.
  • The model outperforms traditional statistical and tree-based baselines in predicting financial returns.
  • Full-sequence autoregressive supervision enhances model performance compared to last-position training.
  • The integration of auxiliary objectives and a mixture-structured return head improves return likelihood.
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NodeImport: Imbalanced Node Classification with Node Importance Assessment
Nan Chen, Zemin Liu, Bryan Hooi, Bingsheng He, Jun Hu, Jia Chen
Graph Learning
  • Introduces NodeImport, a framework for class-imbalanced node classification.
  • Utilizes a balanced meta-set for dynamic assessment of node importance.
  • Separates synthetic node generation from filtering, enhancing flexibility.
  • Demonstrates superior performance over state-of-the-art baselines on benchmark datasets.
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ReDiTT: Retrieval Augmented Conditional Diffusion Transformers for Asynchronous Time Series
Saiyue Lyu, Zhitian Zhang, Ruizhi Deng, Thibaut Durand
Time Series Generative Models
  • Introduction of ReDiTT, the first retrieval-based diffusion framework for asynchronous time series prediction.
  • Utilization of a token memory bank to retrieve top-k similar latent sequences for conditioning.
  • Significant improvements in next-event and long-horizon prediction performance on real-world datasets.
  • Demonstration of enhanced sample diversity and stability in long-horizon forecasting.
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Transforming Rank: How Architecture Navigates the Spectral Pathologies of Depth
Katie Everett
Theory
  • Skip connections preserve rank by routing gradients around rank-reducing branches, creating a tradeoff between rank collapse and ensemble-like behavior.
  • Normalization placement influences the branch-to-skip ratio, affecting rank preservation across depth.
  • The two-matrix structure in feedforward blocks helps maintain the rank of the residual branch Jacobian.
  • The effective rank at initialization can predict the training success of networks on tasks like CIFAR-10.
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Deconstructing Actor-Critic: A Large-scale Empirical Study of Design Components for Practitioners
Haseeb Shah, Lingwei Zhu, Adam White, Martha White
Reinforcement Learning
  • Actor-critic algorithms are widely used but often lack generality across different problems.
  • Common defaults in actor-critic configurations can lead to unreliable performance.
  • Bounded distributions with adaptive update schedules are more robust than traditional Gaussian distributions.
  • The study provides empirical insights that can guide practitioners in making component-level decisions.
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HEDGEHOG: Hierarchical Evaluation of Drug Generators Through Rigorous Filtration
Daria A. Ryabchenko, Pavel Gurevich, Shamil Kadyrov, Daria Frolova, Kseniia Fedisheva, Sergei A. Nikolenko, Alexander Shapeev, Marina A. Pak
Generative Models
  • HEDGEHOG is a six-stage benchmark for evaluating molecular generators in drug discovery.
  • Only 0.65% of 230,000 generated molecules passed all evaluation stages, indicating significant limitations in current models.
  • The benchmark emphasizes the importance of multi-parameter design constraints in assessing drug candidates.
  • HEDGEHOG provides insights into where generative models fail, enabling targeted improvements.
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CDS: Counterfactual Directionality Score for Structured Interventions in Spatial Graphs
Humaira Anzum, Md Ishtyaq Mahmud, Jagan Mohan Reddy Dwarampudi, Tania Banerjee
Graph Learning
  • Introduction of a framework for structured counterfactual interventions in spatial graphs.
  • Development of the Counterfactual Directionality Score (CDS) to measure directional influence.
  • Theoretical interpretation of CDS as a finite-difference measure of local intervention sensitivity.
  • Implementation of a core-level bootstrap procedure for valid uncertainty estimation.
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Relevance-Aware Rule: Structural Deletion of Irrelevant Conditions in Decision Trees
Jung-Sik Hong, Jeongeon Lee, Min Kyu Sim, Sangheum Hwang
Interpretability Theory Efficient ML
  • Establishes the structural mechanics of IRCs in decision trees.
  • Introduces a relevance-aware rule framework for diagnosing and deleting IRCs.
  • Utilizes a three-layer analytical approach to assess the relevance of conditions.
  • Achieves substantial simplification of decision tree rules while maintaining reliability.
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Mitigating The Effect of Class Imbalance in Data with Hierarchical and Dependable Structure
Bipin Chhetri, Deepika Giri, Avishek Kadel, Rabin Kumar Karki, Akbar Siami Namin
NLP
  • Introduces a Hierarchy-Aware RoBERTa framework for CWE classification.
  • Critiques the effectiveness of traditional oversampling techniques in hierarchical contexts.
  • Achieves a weighted F1-score of 0.76 without data augmentation.
  • Demonstrates significant improvements in minority class performance.
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Conditional Invertible Neural Networks for Data-Driven UAV Control: A 2-D Proof of Concept
Christian Wittke, Stephan Myschik, Oliver Niggemann
Robotics
  • Introduction of a probabilistic inverse-dynamics model for UAV control using cINNs.
  • Demonstration of effective uncertainty estimation in motor commands.
  • High performance in open-loop and closed-loop evaluations compared to INDI.
  • Identification of command bandwidth and data coverage as critical factors for control failures.
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Leveraging unlabelled data for generalizable neural population decoding
Ximeng Mao, Nanda H. Krishna, Avery Hee-Woon Ryoo, Matthew G. Perich, Guillaume Lajoie
Multimodal Interpretability Time Series
  • Introduction of MOJO, a joint SSL-SL framework for neural decoding.
  • Demonstrated superior performance over traditional SL models, especially with limited labeled data.
  • Improved interpretability of neuronal representations.
  • Generalization of MOJO to human ECoG data, achieving competitive results.
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Energy-Based Physics-Informed Form Finding for Clustered Tensegrity Structures
Jing Qin, Muhao Chen
Optimization Robotics Theory
  • Introduces an energy-based learning framework for tensegrity structures.
  • Incorporates clustering to reduce the complexity of member forces.
  • Enhances physical consistency and robustness through energy-based loss functions.
  • Demonstrates scalability and accuracy in form finding via numerical experiments.
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ExTernD: Expanded-Rank Ternary Decomposition Ternary LLM PTQ with Accuracy Approaching Any Quantization Level
Chethan Reddy G.P
Large Language Models Efficient ML Optimization
  • ExTernD achieves accuracy close to bf16 precision through expanded-rank ternary decomposition.
  • The method allows for continuous scaling of accuracy and resource usage, unlike fixed-plane quantization methods.
  • A greedy ALS algorithm is proposed for efficient factorization, with a GPU-optimized batched implementation.
  • Empirical results show competitive performance on benchmark datasets, with accuracy surpassing traditional methods.
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ShortOPD: Recovering Pruned LLMs with Short-to-Long On-Policy Distillation
Qingyu Zhang, Qianhao Yuan, Hongyu Lin, Yaojie Lu, Xianpei Han, Le Sun, Xiang Li, Ming Xu, Jiarui Li, Xiuyin Zhao
Large Language Models NLP Efficient ML
  • Structured pruning can severely impact the performance of LLMs in generation tasks.
  • Useful generation outputs are often demoted rather than erased after pruning.
  • ShortOPD optimizes the recovery process by focusing on effective sequence lengths and reducing repetitive suffixes.
  • The proposed method achieves significant performance gains with reduced training time and token usage.
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Understanding Structured Health Data through Interaction-Aware Mixture-of-Experts
Ji Hwan Park, Ying Ding, Tianjin Guo
Interpretability
  • The study explores multi-view learning for structured health data to improve prediction and interpretability.
  • Minimal performance gains were observed, indicating that views may not be independent modalities.
  • Routing attribution showed systematic differences in importance across different views.
  • View construction is essential for interpretability in clinical predictions.
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EXPLORE: Exploration with Guided Search for Analog Topology Generation using Language Models
Guanglei Zhou, Chen-Chia Chang, Yikang Shen, Jonathan Ku, Isaac Jacobson, Jingyu Pan, Yiran Chen, Xin Zhang
Generative Models Optimization Large Language Models
  • EXPLORE is the first framework to integrate structured test-time search with language model decoding for analog topology generation.
  • The framework improves the success rate of topology generation from 12% (one-shot) and 33% (sampling-and-filter) to 65%.
  • By employing structured-token filtering, EXPLORE reduces simulation trials by 24-48%, making it feasible to scale to higher-complexity circuits.
  • The results show over 20× lower MSE compared to sampling-and-filter methods under the same search budget.
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PUe: Biased Positive-Unlabeled Learning Enhancement by Causal Inference
Xutao Wang, Hanting Chen, Tianyu Guo, Yunhe Wang
Theory
  • PUe addresses the limitations of existing PU learning methods by relaxing the assumption of uniform sampling of labeled examples.
  • The framework employs normalized inverse probability weighting to correct PU risk estimators under biased conditions.
  • Regularization techniques are introduced to improve propensity score estimation using deep learning models.
  • PUe integrates with modern cost-sensitive PU methods, enhancing their performance in biased scenarios.
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When Does Reward Teach State? A Hidden-Automaton Instrument and the Group-Language Boundary
Jim Allchin
Reinforcement Learning Theory Optimization
  • Introduces a white-box measurement methodology to assess whether an RL agent learns the task state or a reward shortcut.
  • Establishes three axes (optimizer strength, task structure, observation informativeness) that influence the coupling of reward success and latent-state learning.
  • Demonstrates that high rewards do not necessarily indicate task understanding, as agents may exploit shortcuts.
  • Identifies a pre-training structural warning signal for perception gaps linked to group-language structures.
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Lyapunov Exponent as Physics-Informed Dense Reward: RL Discovery of Stabilization Beyond the Kapitza Pendulum
Slava Andrejev
Reinforcement Learning Robotics Theory
  • The Lyapunov characteristic exponent (LCE) is proposed as a dense reward signal for RL in stabilizing inverted pendulums.
  • Previous methods using sparse rewards failed to stabilize the pendulum, highlighting the importance of reward design.
  • The RL agent successfully discovered stabilization strategies for the inverted pendulum with vertical motion using LCE.
  • The paper provides a theoretical framework for understanding LCE and its application in dynamic systems.
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TerraZero: Procedural Driving Simulation for Zero-Demonstration Self-Play at Scale
Zhouchonghao Wu, Akshay Rangesh, Weixin Li, Wei-Jer Chang, Zachary Lee, Tim Wang, Wei Zhan
Reinforcement Learning Robotics Efficient ML
  • TerraZero achieves high simulation throughput of 1.3M agent-steps per second, enabling large-scale RL training.
  • The simulator generates diverse driving scenarios through procedural methods, enhancing training coverage of safety-critical situations.
  • Policies are trained from scratch using self-play without human demonstrations, showcasing strong generalization across different environments.
  • TerraZero outperforms existing methods in benchmark evaluations for safety and collision metrics.
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TRACE: Turn-level Reward Assignment via Credit Estimation for Long-Horizon Agents
Leitian Tao, Baolin Peng, Wenlin Yao, Tao Ge, Hao Cheng, Mike Hang Wang, Jianfeng Gao, Sharon Li
Reinforcement Learning Large Language Models
  • TRACE provides a dense credit-assignment mechanism for long-horizon reinforcement learning agents.
  • The method uses a frozen reference model to evaluate the effectiveness of intermediate actions in a trajectory.
  • Significant performance improvements were observed on both closed-web and open-web benchmarks.
  • TRACE eliminates the need for cold-start supervised fine-tuning or additional critic models.
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DeepLoop: Depth Scaling for Looped Transformers
Shuzhen Li, Yifan Zhang, Jiacheng Guo, Quanquan Gu, Mengdi Wang
NLP Large Language Models Optimization
  • Introduces the concept of tied-depth aggregation in Looped Transformers.
  • Derives a loop-aware first-order perturbation bound with a visit-alignment coefficient.
  • Proposes a new scaling rule for residual connections in looped architectures.
  • Demonstrates improved performance in language modeling tasks with increased loop counts.
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What Does Goodness Measure? A Likelihood-Ratio Account of Forward-Forward Learning
Paolo Giannitrapani
Theory
  • The goodness measure is shown to be a sufficient statistic for a likelihood-ratio test, providing a theoretical basis for its use in FF learning.
  • Generalizations to anisotropic and heavy-tailed distributions yield new insights into the behavior of the goodness measure and its implications for network training.
  • Normalization between layers is critical for effective learning, and the paper identifies the correct form of normalization to prevent performance collapse.
  • Empirical results validate the theoretical predictions, demonstrating the practical relevance of the derived goodness measure.
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Temperature Scaling Is Not Enough: Calibration Gaps Under Human Label Distributions
Wisdom Dogah
Computer Vision NLP Theory
  • Temperature scaling is ineffective for models trained on soft label distributions.
  • A positive soft-label calibration gap exists, with larger models exhibiting greater discrepancies.
  • Calibration gaps are more pronounced in language tasks compared to vision tasks.
  • The study provides a formal definition of the soft-label calibration gap.
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Contrastive-Collapsed Loss for Flexible and Geometrically Optimal Embeddings and Faster Convergence
Blanca Cano-Camarero, Ángela Fernández-Pascual, José R. Dorronsoro
Theory Optimization Efficient ML
  • Introduction of CoCo loss function for improved representation learning.
  • Theoretical advantages over traditional loss functions like dot regression and cross-entropy.
  • Empirical results show competitive performance with state-of-the-art methods.
  • CoCo promotes faster convergence and tighter class clustering.
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Where Should RL Post-Training Compute Go? Model Size, Search, Learning, and Feedback
Patrick Wilhelm, Odej Kao
Reinforcement Learning Robotics Efficient ML
  • Introduces a FLOP-accounting framework for RL post-training that categorizes compute allocation.
  • Demonstrates that optimal compute allocation is contingent on model size, budget, reward systems, and evaluation targets.
  • Finds that larger models require more compute per token, affecting the number of rollouts and updates possible.
  • Presents RACE as a diagnostic tool for determining effective compute allocation strategies.
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A Hybrid Mamba for Audio-Visual Navigation
Yi Wang, Yinfeng Yu
Multimodal Robotics Audio & Speech
  • Introduction of Samba, a hybrid state-space architecture for audio-visual navigation.
  • Replacement of traditional GRUs with the Mamba State Encoder for better temporal aggregation.
  • Development of the Audio Mamba Encoder to capture global time-frequency dependencies in audio data.
  • Significant improvements in navigation success rates compared to existing state-of-the-art models.
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