AI-generated summaries

Today's ML research,
without the noise.

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

66 Papers today
8h Update frequency
7 Days of history
Similarity search generalisation in contrastive learning with InfoNCE loss
Nick Whiteley
Theory
  • Introduces a new continuity bound for InfoNCE loss using Gˆateaux differentiation.
  • Shows that the population risk with k negative samples is O(1/k) close to expected cross-entropy.
  • Demonstrates that the averaging effect of negative samples stabilizes generalization error as k increases.
  • Offers a new perspective on similarity search generalization in contrastive learning.
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Pitfalls and Remedies for Multi-Task Bayesian Optimization
Carl Hvarfner, Sam Daulton, Max Balandat, Eytan Bakshy
Optimization Theory
  • Identified two structural pitfalls in the standard MTGP model that lead to misestimation of task correlations.
  • Proposed three remedies to improve correlation estimation in multi-task Bayesian optimization.
  • Demonstrated the effectiveness of the remedies through empirical evaluations on synthetic and real-world tasks.
  • Highlighted the limitations of existing multi-task optimization models, particularly in cases of negative transfer.
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Fully Trainable Deep Differentiable Logic Gate Networks and Lookup Table Networks
Wout Mommen, Lars Keuninckx, Matthias Hartmann, Werner Van Leekwijck, Piet Wambacq
Efficient ML Theory
  • Introduces a novel method for learning connections in LGNs and LUTNs.
  • Demonstrates significant performance improvements over fixed-connection networks.
  • Achieves high accuracy with drastically fewer gates, enhancing energy efficiency.
  • Ensures training stability for deep networks through innovative techniques.
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Pattern-Aware Graph Neural Networks for Handling Missing Data
Minett Tran, Taehee Jeong
Graph Learning
  • Introduces pattern-aware GNNs that incorporate missingness patterns, achieving significant improvements in predictive performance.
  • Demonstrates that simple random embeddings can perform comparably to learned embeddings, emphasizing the importance of pattern distinction.
  • Shows that attention mechanisms are less critical when pattern information is utilized, with mean aggregation achieving competitive results.
  • Finds heterogeneous improvements across datasets, with some showing dramatic gains while others exhibit minimal benefits.
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AutoMatBench: An Automatic Optimization Toolkit for the Acceleration of Material Properties Prediction Benchmarking
Hongxiao Li, Wanling Gao
Optimization
  • AutoMatBench combines MatBench with OOD performance evaluation to improve benchmarking of MPP models.
  • The study reveals significant performance discrepancies across different configurations, necessitating careful evaluation.
  • Bayesian optimization in AutoMatBench allows for efficient exploration of configurations, saving computational resources.
  • The toolkit provides insights that enhance the understanding of MPP benchmarking beyond existing studies.
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COAST: Context-Aware Differential Learning for Gene Expression Prediction in Spatial Transcriptomics
Keunho Byeon, Sunhong Park, Jeewoo Lim, Jin Tae Kwak
Computer Vision
  • COAST addresses the limitations of existing methods by focusing on relative expression relationships rather than just absolute values.
  • The framework utilizes a Transformer encoder to effectively integrate local and global context features.
  • Training involves a joint objective that combines absolute and signed differential regression, enhancing the model's ability to capture spatial relationships.
  • Experimental results show significant improvements in prediction accuracy and clinically relevant outcomes across multiple datasets.
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Reinforcement Learning with Verifiable Physics: Post-training LLMs with Continuous Rewards
Pengfei Cai, Utkarsh Utkarsh, Alan Edelman, Christopher Vincent Rackauckas, Rafael Gomez-Bombarelli
Reinforcement Learning Large Language Models Theory
  • Introduction of RLVP, a framework combining reinforcement learning with verifiable physics for PDE solver generation.
  • Development of a hybrid verifier that integrates binary and continuous rewards to enhance model training.
  • Demonstration of effective multi-PDE training, allowing a single model to handle diverse PDE families.
  • Smaller models trained with RLVP outperform larger models using traditional prompting techniques.
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CatRetriever: Contrastive Representation Learning for Slab-to-Bulk Retrieval in Generative Catalyst Discovery
Jungho Oh, Woosung Kim, Dong Hyeon Mok, Jonggeol Na, Seoin Back
Generative Models
  • CatRetriever effectively addresses the slab-to-bulk retrieval problem in catalyst discovery.
  • The model achieves high retrieval accuracy, significantly improving the efficiency of identifying bulk structures from slab representations.
  • An end-to-end pipeline is developed that combines slab-to-bulk retrieval with generative models and adsorption energy evaluations.
  • The approach allows for exploration beyond fixed databases, enhancing the scope of potential catalyst candidates.
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Weight-Adjusted Gradients Reveal Parameter Importance and Failure Modes in LLMs
Shrestha Datta, Hongfu Liu, Anshuman Chhabra
Large Language Models Interpretability Efficient ML
  • WAG combines zeroth-order and first-order information to estimate parameter importance effectively.
  • It identifies a critical subset of parameters that cause significant performance degradation when perturbed.
  • WAG reveals the previously unexplored relationship between weights and gradients in LLMs.
  • The method is computationally efficient and applicable across various practical scenarios.
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TSAI-MetaFraud: A Benchmark Dataset for Financial Fraud Transaction and Behavioral Risk Detection in Metaverse Ecosystems
Refat Ishrak Hemel, Ehsan Hallaji, Roozbeh Razavi-Far
Graph Learning Multimodal
  • Introduction of TSAI-MetaFraud, a comprehensive dataset for fraud detection in metaverse environments.
  • Integration of behavioral, transactional, and graph-structured data to reflect real-world complexities.
  • Establishment of benchmark tasks for systematic evaluation of fraud detection methods.
  • Baseline evaluations provided using machine learning and graph neural network approaches.
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Understanding Schedule-Free Methods in Nonconvex Optimization: Rate Guarantees and Escaping Saddles
Jiseok Chae, Donghwan Kim
Optimization Theory
  • Schedule-Free methods eliminate the need for handcrafted learning rate schedules, simplifying optimization in machine learning.
  • The paper establishes optimal worst-case convergence rates for SF-GD and SF-SGD in nonconvex optimization.
  • A Lyapunov function is constructed to analyze the continuous-time limiting ODE of SF-GD, demonstrating an O(1/T) decay rate for the squared gradient norm.
  • SF-GD is shown to avoid strict saddle points with a small one-time perturbation, ensuring convergence to local minimizers.
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SciML in the Wild: A Diagnostic Study of When Structural Priors Help and When They Hurt
Vrishank Sai Anand, Prathamesh Dinesh Joshi, Raj Abhijit Dandekar, Rajat Dandekar, Sreedath Panat
Time Series
  • Heuristic structural priors in PINN and UDE models often degrade predictive performance compared to less-constrained models like ARIMA and NODE.
  • The study identifies four failure modes of physics-informed learning under non-stationarity.
  • Empirical testing of structural priors is crucial in domains with uncertain or evolving governing equations.
  • The effectiveness of SciML methods is highly dependent on the alignment of structural priors with the data-generating process.
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Manifold Constrained Tabular Deep Neural Networks
Tian Li, Lucy Robinson, Varun Ojha, Huizhi Liang
Theory Efficient ML Graph Learning
  • Introduction of Latent Decision Nodes (LDNs) for unified feature representation.
  • Utilization of hyperbolic geometry to model hierarchical decision structures.
  • Soft Decision Routing mechanism for differentiable range discretization of numerical features.
  • Entropy-aware Capacity Allocation algorithm to balance model complexity and expressiveness.
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Neural Collapse Is Forbidden: Information Floors in Language Models
Bruno Abrahao
NLP Large Language Models Theory
  • Within-class variance in language models is an allocation of information storage, not an indication of incomplete neural collapse.
  • 79-91% of representational variance is attributed to within-token context variability, while macro-category structure accounts for only 4-12%.
  • Token-level weight decay penalizes categories based on type count, affecting next-token prediction as an imbalanced K-class problem.
  • A converse floor for binary categories establishes a minimum dispersion proportional to conditional mutual information.
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All you need is SAMPAT
Jayadeva, Madhur Aswani
Theory Interpretability Efficient ML
  • SAMPAT provides a fully interpretable neural architecture using algebraic expressions.
  • It can approximate any smooth function with a three-layer structure.
  • The architecture allows for optimization of both model parameters and structure.
  • SAMPAT demonstrates competitive performance on various datasets.
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Statistically Undetectable Backdoors in Deep Neural Networks
Andrej Bogdanov, Alon Rosen, Neekon Vafa
Theory
  • Backdoors can be implanted in DNNs that are statistically undetectable in white-box settings.
  • The presence of a backdoor allows for the creation of adversarial examples that are not possible to generate without it.
  • The study highlights a significant power asymmetry between model trainers and users, complicating trust in machine learning services.
  • The authors provide a theoretical framework for understanding the construction and implications of these backdoors.
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Adaptive Bayes exactly tracks information over intrinsic time
Akshay Balsubramani
Theory Optimization Reinforcement Learning
  • Introduces an exact information-accounting identity for Bayesian updates.
  • Demonstrates two exact adaptive decompositions of cumulative regret.
  • Establishes that favorable learning conditions are intrinsic to the sequence rather than approximations.
  • Applies the framework to a wide range of learning scenarios, including bandits and online optimization.
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Beyond Euclidean Clipping: Overcoming Exploration Collapse in LLM RL via Riemannian Isometric Policy Optimization
Zhicheng Cai, Xinyuan Guo, Hanlin Wu, Mingxuan Wang, Wei-Ying Ma, Ya-Qin Zhang, Hao Zhou
Reinforcement Learning Large Language Models Optimization
  • Identifies the geometric mismatch in PPO-Clip as the root cause of exploration collapse in LLM RL.
  • Proposes Riemannian Isometric Policy Optimization (RIPO) to correct the geometric flaws of PPO-Clip.
  • Demonstrates that RIPO allows for balanced exploration and exploitation, enhancing model performance.
  • Achieves significant improvements in various benchmarks, showcasing the efficacy of the proposed method.
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Bandit PCA with Minimax Optimal Regret
Moïse Blanchard, Dmitrii Ostrovskii, Aadirupa Saha
Theory Optimization
  • Establishes a minimax optimal regret bound for Bandit PCA of order r√dT.
  • Introduces a novel algorithm combining online mirror descent and multiscale exploration.
  • Constructs an adaptive adversary to demonstrate the lower bound of regret.
  • Connects Bandit PCA to quantum tomography, highlighting its relevance in quantum state estimation.
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MawForge: Memory-Bounded Expert Materialization for Local Mixture-of-Experts Inference
Craig Opie
NLP Large Language Models Efficient ML
  • MawForge enables practical local inference for large MoE models on memory-constrained devices.
  • The split-pack architecture allows for on-demand materialization of expert tensors, reducing memory requirements.
  • Validation results show that MawForge can serve large models without exceeding memory limits, with a focus on cache behavior.
  • Larger expert caches improve hit rates but may negatively impact throughput due to increased memory pressure.
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A Novel Graph Fraud Detector via Grouped Attribute Completion and Confidence-Aware Contrastive Learning
Junpeng Wu, Ye Yuan
Graph Learning
  • Introduces GFD-GC framework to tackle incomplete node attributes and class imbalance in graph fraud detection.
  • Develops a grouped attribute completion module for effective feature recovery by capturing heterogeneous neighborhood semantics.
  • Implements a confidence-aware contrastive learning strategy to enhance fraud representation learning using pseudo-fraud nodes.
  • Demonstrates superior performance of GFD-GC over existing state-of-the-art methods in extensive experiments.
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Hierarchical Bayesian Quadrature
Tim Weiland, Toni Karvonen, Philipp Hennig
Theory Efficient ML Optimization
  • Hierarchical Bayesian Quadrature (HBQ) adapts to nonstationary integrands using a tree-based partitioning approach.
  • The method combines local integral estimates through a hierarchical Gaussian process conditioning, enhancing correlation across subdomains.
  • HBQ outperforms standard Bayesian Quadrature on nonstationary integrands while matching its performance on stationary ones.
  • The algorithm is computationally efficient, avoiding MCMC and reducing the size of local Gram matrices.
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PRISM Edit: One Vector for All Temporal Answers
Chen Huang, Qi Zheng, Ruiqin Zheng, Long Zeng, Yuantong Xu
NLP Large Language Models Optimization
  • PRISM Edit allows LLMs to maintain historical accuracy while updating temporal facts.
  • The method leverages the model's existing internal mechanisms for temporal modulation.
  • A new benchmark, TIMECONFLICT, is introduced to evaluate temporal editing performance.
  • PRISM Edit achieves state-of-the-art results with significant improvements over baseline methods.
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Optimal Top-k Identification from Pairwise Comparisons
Motti Goldberger, Nils Rudi
Theory Optimization Efficient ML
  • Introduces an asymptotically optimal algorithm for top-k identification from pairwise comparisons under latent utility models.
  • Characterizes the oracle allocation problem as a two-player game, leading to insights on optimal sampling strategies.
  • Develops a primal-dual algorithm for online learning of comparison allocations, proving its asymptotic optimality.
  • Addresses the importance of adaptivity in selecting pairs for comparison to minimize costs associated with comparisons.
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LionVote: Per-Layer Learning Rate Adaptation for Lion
Kris Atallah
Optimization
  • LionVote provides a per-layer adaptive learning rate mechanism for the Lion optimizer.
  • The effective learning rate varies significantly across different layer types, necessitating tailored adaptations.
  • LionVote outperforms standard Lion and AdamW optimizers in terms of accuracy on ViT-Tiny/CIFAR-100.
  • The adaptation mechanism is based on diagnostics of gradient stability and momentum health.
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LLM-PDESR: Robust PDE Discovery via Subdomain Weighted Residuals and LLM-Guided Symbolic Hypothesis Generation
Jinyang Du, Hao Ma, Xiaohu Shi, Bo Yang, Yanchun Liang, Heow Pueh Lee, Chunguo Wu
Large Language Models Optimization Interpretability
  • Introduction of LLM-PDESR, an end-to-end framework for PDE discovery.
  • Utilization of C4 continuous quintic splines and SWR evaluations to address derivative noise.
  • Development of a rigorous benchmark to validate genuine symbolic discovery capabilities.
  • Successful extraction of a 1D dynamical surrogate from noisy climate data.
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CoCoT-EEG: Contrastive-Pretrained Multiscale Convolutional Transformer for EEG Decoding
Gabriel Mahuas, Victoria Shevchenko, Ugo Tanielian, Yassir Bendou, Richard Gao
Time Series
  • CoCoT-EEG introduces a convolution-first architecture for EEG decoding, enhancing feature extraction from noisy signals.
  • The model outperforms existing single-task EEG models and competes with large-scale pretrained models.
  • Contrastive pretraining significantly boosts performance on diverse downstream EEG tasks.
  • Extensive ablation studies reveal important design considerations for EEG foundation models.
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Diachronic Sample Integration: Robust Tail-Risk Estimation with Generative Models
Shuning Zhao, Patrick Wong, Leran Zhang, Xiaolin Hu
Generative Models Theory Time Series
  • Introduction of Diachronic Sample Integration (DSI) for robust tail-risk estimation.
  • DSI aggregates samples from multiple training checkpoints to mitigate tail estimation instability.
  • Formalization of a bias-variance decomposition for VaR and ES under non-i.i.d. samples.
  • Empirical results demonstrate substantial reduction in tail-estimation error compared to existing methods.
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Advancing Optimal Subset Oracle via Learning Relaxation of Neural Set Functions
Yongquan Shi, Zijing Ou, Shiping Wang, Yatao Bian
Optimization Theory Efficient ML
  • Introduction of a learned surrogate objective to replace Monte Carlo sampling in optimal subset oracles.
  • The proposed ReSet method provides stable and efficient gradients, reducing computational overhead.
  • Theoretical guarantees for convergence and approximation ratios are established.
  • Demonstrated improvements over existing methods in real-world applications.
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NeuroMem-FHP: A Likelihood-Free Deep Learning Framework for Parameter Estimation of Fractional Hawkes Process
Neha Gupta, Aditya Maheshwari
Time Series
  • Introduction of NeuroMem-FHP, a deep learning framework for parameter estimation of FHP.
  • Utilization of LSTM and Transformer architectures to bypass traditional likelihood-based estimation.
  • Significant performance improvement over classical MLE methods in synthetic and real-world datasets.
  • Validation of the framework through predictive validation on high-frequency datasets.
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Reinforcement Learning for Execution under Dynamic Fees in a Closed-Loop DEX Simulator
Wen-Ting Wang
Reinforcement Learning
  • Introduces a closed-loop simulator to study the impact of dynamic fees on trade execution in DEXs.
  • Demonstrates that a small DQN outperforms traditional execution heuristics in dynamic-fee environments.
  • Establishes a rigorous evaluation methodology for model-free control in trading environments.
  • Finds that the advantage of the DQN diminishes under constant fee conditions, indicating the significance of fee variability.
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Exploratory Analysis of Deep Learning Models for Forecasting Meteorological Parameters in the Agricultural Sector
Piotr Sikora, Sotirios Kontogiannis
Time Series
  • The study evaluates recurrent and hybrid deep learning models for meteorological forecasting in agriculture.
  • Hybrid CNN-GRU models outperformed purely recurrent models in short-term forecasting tasks.
  • The analysis utilized a substantial dataset of 134,376 hourly observations from Ioannina, Greece.
  • Performance metrics included normalized RMSE, R2, and a composite Weighted Quotient Score (WQS).
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EvoClawBench: Can Agents Learn Reusable Skills from Their Own Runs?
Zhiyuan Peng, Xin Yin, Chenhao Ying, Zhe Cui, Zixiang Ding, Zhenhua Liu, Jiang Wu, Yuan Luo
Large Language Models Reinforcement Learning Robotics
  • EvoClawBench is a novel benchmark for evaluating agents' ability to learn reusable skills from their own runs.
  • The benchmark includes 100 tasks and supports multiple agent runtimes, allowing for comprehensive evaluation.
  • Three evaluation modes (BASELINE, PRESKILL, POSTSKILL) are established to isolate the effects of skill authoring.
  • Experimental results indicate that the effectiveness of self-authored skills varies significantly across different models.
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modelDNA: Calibrated Lineage Verification and Merge Decomposition from Sampled Weight Fingerprints
Muhammad Awais Bin Adil, Saad Aamir
Large Language Models Theory Efficient ML
  • Introduction of modelDNA, a tool for lineage verification of language models.
  • Fingerprinting method that captures lineage signals from minimal data.
  • Calibrated verdict engine that prioritizes abstention to avoid false accusations.
  • Merge decomposition capability that recovers mixture weights from fingerprints.
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Energy-guided Recursive Model
Yifei Zhao, Ying Tang
Theory Optimization Efficient ML
  • ERM introduces an intrinsic selection principle using Hopfield energies for candidate trajectory evaluation.
  • The model outperforms previous recursive reasoning models in structured problem-solving tasks.
  • Explicit energy functions improve the efficiency of inference in recursive reasoning frameworks.
  • ERM effectively integrates with energy-based techniques like parallel tempering for enhanced sampling.
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Agentic Skill Optimization over Lie Algebroids
Sridhar Mahadevan
Optimization Large Language Models Theory
  • LASKO framework models skill edits as interdependent operations within a structured artifact context.
  • Utilizes controlled Lie algebroids to capture the relationships and order sensitivity of skill edits.
  • Achieves significant speedups in skill optimization through efficient screening tests.
  • Highlights the geometric nature of skill optimization, focusing on the interactions between edits.
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Two Confounds in Cross-Model Value Comparison: Response Determinism and the Access Harness
Hong-In Won, Jinseok Jang, Hyoseop Kim
NLP Large Language Models Theory
  • Introduces a separation protocol to distinguish between genuine value differences and response determinism in language models.
  • Demonstrates that response determinism varies significantly across models and should be measured for accurate comparisons.
  • Identifies the access harness as a confounding factor that alters model value profiles based on deployment context.
  • Findings suggest that apparent individuation of models is often inflated by response determinism and deployment conditions.
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RDQ: Residual Distribution Quantization for Large Language Models
Prateek Singh
NLP Large Language Models Efficient ML
  • Identifies residual stream drift as the main cause of performance degradation in sub-4-bit quantization of LLMs.
  • Discovers that a significant majority of layers in LLaMA-3-8B have non-Gaussian distributions and that variance increases substantially with depth.
  • Introduces Cascaded Error Compensation (CEC) for effective calibration of quantized layers, correcting for cross-layer drift.
  • Achieves state-of-the-art perplexity results on LLaMA-3-8B, Qwen-2.5-7B, and Mistral-7B across all tested bit-widths.
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DiffEEG: A Self-Supervised Denoising Diffusion Model for Learning EEG Generic Representations
Abdulkader Helwan, Lina Abou-Abbas, Hussein El Amouri, Belkacem Chikhaoui, Khadidja Henni
Time Series Reinforcement Learning Generative Models
  • DiffEEG addresses severe annotation scarcity and class imbalance in EEG data for seizure detection.
  • The model employs a denoising diffusion pre-training strategy to learn robust EEG representations.
  • A reinforcement learning-based fine-tuning mechanism enhances sensitivity to rare seizure events.
  • DiffEEG achieves clinically relevant performance metrics, including high accuracy and F1-scores.
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MLPs are Hebbians: Constructing Efficient Fact-Storing MLPs for Transformers
Roberto Garcia, Jerry Liu, Ronny Junkins, Sabri Eyuboglu, Atri Rudra, Christopher Ré
NLP Large Language Models Theory Efficient ML
  • Introduces a closed-form construction of MLPs that achieves optimal fact storage scaling.
  • Demonstrates the ability to handle arbitrary input/output geometries.
  • Shows that the proposed MLPs can be integrated into Transformer architectures for factual recall.
  • Achieves significant parameter efficiency compared to prior constructions.
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Nonlinear Axiomatic Attribution for Cooperative Games
Weida Li, Zhuanghua Liu, Yaoliang Yu, Bryan Kian Hsiang Low
Theory Optimization
  • The Shapley value's linearity can lead to unreliable player rankings in cooperative games.
  • Nonlinear axiomatic attribution methods are proposed to address the limitations of the Shapley value.
  • The new methods retain necessary axioms while relaxing linearity and efficiency.
  • Experimental results show improved performance in player ranking quality using the inclusion AUC metric.
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Time-Lag-Aware Deep Reinforcement Learning for Flexible Job-Shop Scheduling in PPVC Module Factories
Ziheng Zhang, Wei Zhang
Reinforcement Learning Optimization
  • Long post-operation time-lags in PPVC factories significantly inflate makespan and complicate scheduling.
  • The proposed DRL solver incorporates lag-aware dynamics and anticipatory features to improve scheduling decisions.
  • The learned policy outperforms traditional scheduling methods and is capable of rapid re-planning in response to disruptions.
  • A public benchmark generator is released to facilitate further research in this area.
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Super-Tuning: From Activation-Aware Pruning to Sparse Fine-Tuning
Ivan Ilin, Philip Zmushko, Peter Richtárik
NLP Large Language Models Efficient ML
  • Introduction of Super, a sparse PEFT method that selects weights using a training-free saliency score.
  • Development of Supra, a hybrid approach combining Super's sparse updates with LoRA.
  • Demonstration of the effectiveness of pruning-inspired strategies for selecting sparse supports.
  • Evaluation of multiple PEFT methods on arithmetic reasoning tasks, showing superior performance of Super and Supra.
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ERP Data Provisioning Financial Control Testing
Anitha Samudrala
Optimization
  • SEQ-FCT framework combines multiple data provisioning techniques to ensure secure and effective financial control testing.
  • The framework preserves financial control behavior while minimizing the risk of sensitive data exposure.
  • Evaluation using a synthetic dataset shows high performance in reconciliation and fraud detection metrics.
  • The approach emphasizes the importance of governance and validation in data provisioning processes.
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Domain-Aware Scaling Laws Uncover Data Synergy
Kimia Hamidieh, Lester Mackey, David Alvarez-Melis
NLP Large Language Models Theory
  • Introduces a formal definition of data synergy in the context of LLM pretraining.
  • Develops domain-aware scaling laws that account for first-order and second-order synergies.
  • Demonstrates improved predictive accuracy over traditional domain-agnostic scaling laws.
  • Provides actionable insights for data curation and acquisition based on synergy estimates.
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SPARC-Net: A Spectral, Causality-Aware, and Hard-Constrained Physics-Informed Architecture for Stiff and Shock-Dominated Partial Differential Equations
Divyavardhan Singh, Dimple Sonone, Hammad Mohammad, Kishor Upla
Theory Optimization
  • SPARC-Net addresses multiple concurrent issues in PINNs for stiff PDEs.
  • The architecture includes a hard-constraint output ansatz to enforce boundary conditions.
  • Significant improvements in accuracy were observed across various benchmark problems.
  • The framework is open-source and replicable, promoting further research and application.
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LeRoPE: Learnable RoPE Frequencies Improve Language Modeling
Petros Karypis, Sean O'Brien, Shreyas Kadekodi, Rui Zhu, Julian McAuley
NLP Large Language Models
  • LeRoPE introduces learnable frequencies for Rotary Positional Encodings, enhancing model adaptability.
  • The method consistently outperforms traditional RoPE and partial RoPE across various model sizes.
  • At the largest model scale, RoPE requires more compute to match LeRoPE's performance.
  • A dominant positional band was identified, highlighting its importance in attention mechanisms.
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The Spectral Structure of Latent Treatment Effects
Hamza Virk, Bijan Mazaheri, Yihren Wu
Theory
  • Introduces a spectral identification theorem for latent treatment effects using a compressed observable operator.
  • Demonstrates that latent treatment effects correspond to the eigenvalues of a difference operator derived from treatment and control moment factorizations.
  • Extends the Synthetic Potential Outcomes framework to handle overcomplete proxy systems.
  • Establishes high-probability bounds for treatment effects and mixture proportions, improving causal inference reliability.
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EvoLP: Self-Evolving Latency Predictor for Model Compression in Real-Time Edge Systems
Shuo Huai, Hao Kong, Shiqing Li, Xiangzhong Luo, Ravi Subramaniam, Christian Makaya, Qian Lin, Weichen Liu
Efficient ML
  • EvoLP provides an efficient and accurate latency prediction for DNNs on edge devices.
  • The framework reduces the search space for latency measurement, improving efficiency.
  • EvoLP incorporates a self-evolution mechanism to enhance prediction precision during model compression.
  • Experimental results show superior performance compared to state-of-the-art latency predictors.
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Invariant Learning Dynamics of Transformers in Inductive Reasoning Tasks
Tiberiu Musat, Tiago Pimentel, Nicholas Zucchet, Thomas Hofmann
NLP Large Language Models Theory
  • Introduction of the Invariant Manifold of Inductive Reasoning (IMIR) as a theoretical framework for understanding Transformer learning dynamics.
  • Establishment of a generalized class of inductive tasks that unifies various existing tasks in the literature.
  • Theoretical proof of the existence of the IMIR, enabling a more interpretable analysis of learning dynamics.
  • Investigation of the impact of data statistics and random initializations on circuit competition in Transformers.
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GatedLinear: Adaptive Routing of Complementary Linear Bases for Time Series Forecasting
Qitai Tan, Ruiwen Gu, Yilin Su, Mo Li, Xu Lin, Xiao-Ping Zhang
Time Series
  • GatedLinear offers a lightweight framework for time series forecasting by utilizing adaptive routing of complementary linear bases.
  • The Tri-Factorized Fusion Gate enables dynamic and interpretable routing decisions tailored to specific temporal dynamics.
  • GatedLinear achieves state-of-the-art accuracy on benchmark datasets while maintaining a smaller parameter footprint compared to traditional deep learning models.
  • The framework effectively captures diverse temporal patterns, addressing the heterogeneity of real-world time series data.
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Data-Efficient Deep Learning: Empirical Guidelines for Training Set Size Estimation in Inertial Sensor Classification
Ofir Kruzel, Itzik Klein
Efficient ML Time Series
  • Classification accuracy in inertial sensor tasks follows a logarithmic growth pattern.
  • Introduces a stability point metric for optimizing training data collection.
  • Models often reach stability with fewer samples than traditional heuristics suggest.
  • Provides a unified framework for analyzing performance in binary and multi-class scenarios.
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JEPA for AI-Native 6G: Predictive Representations and Open Challenges
Sheikh Salman Hassan, Irshad A. Meer, Almoatssimbillah Saifaldawla, Yan Kyaw Tun, Mustafa Ozger, Madyan Alsenwi, Nguyen Van Huynh, Woong-Hee Lee, Cedomir Stefanovic, Mathini Sellathurai, Henk Wymeersch, Tharmalingam Ratnarajah
Multimodal
  • JEPA offers a novel self-supervised learning approach for AI-native 6G networks.
  • The architecture predicts future representations, improving label efficiency and robustness.
  • The paper highlights the importance of wireless-aware design choices in JEPA.
  • An illustrative case study shows practical applications of JEPA in beam management.
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Learning Subgroup Relations Using Siamese Graph Neural Networks
Tal Weissblat
Graph Learning
  • Introduction of a Siamese GNN for subgroup prediction in finite groups.
  • Integration of graph embeddings from Cayley graphs with algebraic features.
  • Achieved a high test accuracy of 95.9% on subgroup relation prediction.
  • Demonstrated the effectiveness of combining graph-based and algebraic information.
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Distance-Preserving Embeddings in Inhomogeneous Random Graphs
My Le, Luana Ruiz, Souvik Dhara
Graph Learning Theory Efficient ML
  • Introduces landmark-based embeddings for inhomogeneous random graphs, improving upon worst-case distortion guarantees.
  • Achieves tighter dimension-distortion trade-offs, demonstrating polynomial improvements in embedding dimensions.
  • Extends theoretical guarantees to global averages and introduces a GNN-augmented variant for efficient shortest-path approximations.
  • Establishes a novel metric sandwiching framework that unifies analysis across various latent spaces.
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Learning from Local Walks on Dynamic Graphs with Bandit Feedback
Sourav Chakraborty, Amit Kiran Rege, Claire Monteleoni, Lijun Chen
Graph Learning Theory Reinforcement Learning
  • Introduces a novel framework for stochastic multi-armed bandits on dynamic graphs with local movement constraints.
  • Establishes a structural condition (sliding-window mixing) that ensures stable exploration and navigation.
  • Analyzes local explore-then-commit algorithms achieving sublinear expected regret.
  • Proposes a reward-aware strategy with formal safety and performance guarantees.
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BlockServe: Block-Grained Continuous Batching for High-Throughput Diffusion LLM Serving
Yuanjie Zhu, Liangwei Yang, Ke Xu, Weizhi Zhang, Shanghao Li, Zihe Song, Philip S. Yu
Large Language Models Generative Models Efficient ML
  • Introduction of a block-grained scheduler to reduce straggler-induced compute bubbles in dLLM inference.
  • Development of a mixed-state memory manager that supports heterogeneous batch processing without custom kernels.
  • Implementation of a compute-aware admission controller that enhances effective batch capacity through token budgeting.
  • Achieved 1.9–10.6× throughput improvement over Fast-dLLM with similar generation quality.
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Learning More from Less: Reinforcement Learning from Hindsight
Iris Xu, Sunshine Jiang, John Marangola, Nitish Dashora, Richard Li, Thomas Liu, Zexue He, Yuheng Zhi, Alex Pentland, Pulkit Agrawal, Zhang-Wei Hong
Reinforcement Learning Robotics Multimodal
  • Introduces Learning from Hindsight (LfH) to improve sample efficiency in RL for VLA models.
  • Utilizes hindsight relabeling to convert failed rollouts into training signals.
  • Achieves a 5× improvement in sample efficiency on LIBERO-PRO tasks.
  • Demonstrates that relabeling can be more beneficial than dense feedback in sparse reward scenarios.
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On-Device Adaptive Battery Power Prediction for Electric Vehicles
Avik Bhatnagar, Anton Paule, Tobias Schuermann, Sebastian Reiter, Oliver Bringmann
Time Series
  • Introduces on-device adaptive learning for battery power prediction in EVs.
  • Demonstrates significant performance improvements through online and offline adaptation strategies.
  • Highlights the limitations of a 'one model fits all' approach in dynamic driving conditions.
  • Evaluates state-of-the-art models for very short-term forecasting (1-3 seconds).
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Group Invariant Spectral Embedding
Yeari Vigder, Paulina Hoyos, David Thong, Joakim Andén, Joe Kileel, Amit Moscovich
Graph Learning Theory Efficient ML
  • Introduces group-invariant affinity kernels for spectral embedding.
  • Proves convergence of graph Laplacians to differential operators on quotient spaces.
  • Demonstrates improved convergence rates and effective dimension reduction.
  • Validates the approach on datasets with SO(2) and SO(3) symmetries.
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Spectral Origins of the Self-Correction Blind Spot in Autoregressive Generation
Ingrid Petrova, Luan Vejsiu
NLP Large Language Models Reinforcement Learning
  • Introduces SPARC, a formal model explaining the self-correction blind spot in autoregressive generation.
  • Establishes that the blind spot arises when the spectral radius of the error-propagation operator is at least one.
  • Derives a precise activation threshold for correction markers, recovering a significant reduction in blind-spot rates.
  • Provides a convergence guarantee for RL-based self-correction training, highlighting the necessity of RL over supervised fine-tuning.
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Auditing Construct Overlap in Explainable Machine Learning: Evidence from Burnout-Depression Prediction Across Student Cohorts
Alireza Dehghan, Negin Ashrafi
Interpretability
  • The study reveals that apparent stability in risk hierarchies from XML models is often due to construct overlap rather than genuine predictive relationships.
  • A residualization protocol is introduced to quantify the impact of shared variance between correlated predictors and outcomes.
  • The predictive performance of the model significantly decreases when controlling for the correlation between trait anxiety and depression.
  • Individual-level clinical predictions are deemed non-actionable due to high uncertainty in prediction intervals.
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NL-PAC: Specification Ambiguity and Certified Minimax Risk Floors in LLM-Mediated Supervision
Berkay Anahtarci
NLP Large Language Models Theory
  • Introduction of the NL-PAC framework to address specification ambiguity in LLM supervision.
  • Establishment of a worst-case risk floor that is independent of sample size, linked to the diameter of admissible labels.
  • Certification of risk floors from unlabeled inputs, providing a method for auditing model performance.
  • Empirical audits reveal the limitations of certain prompts in achieving admissibility for coherent readings.
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Gauge dependence and structured-output corruption in sign-branched repetition penalties: measurements across models, inference stacks, and alternative repetition controls
Peter Hollows
NLP Large Language Models Generative Models
  • The multiplicative repetition penalty is gauge dependent, leading to inconsistent effects across different models.
  • A fixed repetition penalty can result in a significant flip rate of generated tokens, affecting model outputs.
  • Applying the repetition penalty to normalized log-probabilities instead of raw logits can eliminate the observed issues.
  • The study highlights the importance of understanding the underlying mechanisms of logit manipulation in LLMs.
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Action-Factored Multi-Agent Reinforcement Learning for Scalable Quantum Device Tuning
Edwin De Nicolo, Rahul Marchand, Cornelius Carlsson, Pranav Vaidhyanathan, Natalia Ares
Reinforcement Learning Optimization Robotics
  • Introduction of QADAPT, a multi-agent reinforcement learning framework for quantum device tuning.
  • Adaptive action-space factorization reduces cross-agent interference and improves sample efficiency.
  • Zero-shot generalization allows the framework to adapt to unseen quantum device sizes without retraining.
  • Empirical evaluations demonstrate superior performance compared to state-of-the-art tuning methods.
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Multi-dimensional training-priority weighting based on physical information propagation paths: a unified residual-weighting framework for physics-informed neural networks
Zhangyi Lian, Xinda Dong, Wenxuan Huo, Weifeng Huang, Gang Zhu, Qiang He
Theory Optimization
  • Introduces a unified framework for training priorities in PINNs based on physical information propagation paths.
  • Demonstrates that standard PINNs do not respect the natural learning order of premise and dependent regions.
  • Utilizes negative-exponential residual weights to enforce training priorities at the loss level.
  • Implements a directional compatibility coefficient for managing multiple training priorities.
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