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
LongStraw: Long-Context RL Beyond 2M Tokens under a Fixed GPU Budget
Changhai Zhou, Kieran Liu, Yuhua Zhou, Qian Qiao, Jun Gao, Harry Zhang, Irvine Lu, Nolan Ho, Lucian Li, Andrew Lei, Cleon Cheng, Steven Chiang, Yihang Zeng, Di Zhang, Rio Yang, Kaijie Chen, Andrew Chen, Pony Ma, Weizhong Zhang, Cheng Jin
Reinforcement Learning Large Language Models Efficient ML
  • Introduces LongStraw, an efficient execution stack for long-context RL training.
  • Achieves training with context lengths exceeding 2 million tokens under fixed GPU budgets.
  • Demonstrates significant memory savings through innovative state management techniques.
  • Validates the approach on two distinct model architectures: Qwen and GLM.
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Implementations of Quantum and Classical Topology-Aligned Architectures for Molecular Property Prediction
James T. Pegg, Hubert Okadome Valencia, Ronin Wu
Graph Learning Efficient ML Theory
  • Introduction of a topology-aligned inductive bias for molecular property prediction.
  • Development of two architectures: Iso-QGNN (quantum) and Iso-CGNN (classical) with identical parameter counts.
  • Competitive performance achieved with only 64 trainable parameters, demonstrating high data efficiency.
  • Both models perform comparably, indicating the inductive bias's significance over the quantum substrate.
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Asymmetric Peak-Aware Loss for Peak-Critical Time Series Forecasting
Theivaprakasham Hari, Yanan Xin, Winnie Daamen, Serge Paul Hoogendoorn, Sascha Hoogendoorn-Lanser
Time Series
  • Introduction of Asymmetric Peak-Aware Loss (APAL) to improve peak-critical forecasting.
  • Development of a peak-critical evaluation protocol that includes tail error and peak metrics.
  • APAL shows improved performance in forecasting rare demand spikes compared to traditional symmetric loss functions.
  • The methodology is model-agnostic and can be applied across various forecasting backbones.
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Microstructure-Conditioned Surrogate Models for Graded Multiscale Optimization of Mycelium Composites
J. Storm, I.B.C.M. Rocha, S. Schyck, K. Masania, F.P. van der Meer
Optimization
  • Introduction of HyPRNN, a microstructure-conditioned surrogate model for multiscale optimization.
  • Demonstrated a 42% reduction in peak stress for optimized graded structures compared to random microstructures.
  • Conditioning on manufacturing variables enhances the model's applicability to complex geometries.
  • The approach enables efficient multiscale simulations with limited data, addressing challenges in traditional methods.
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MESHA: Mechanism-Enforced Sequential Halving for Strategic Linear Bandits
Xin Li, Zixin Zhong
Theory
  • MESHA integrates a uniform sampling rule with an epoch-wise Grim Trigger Condition to combat strategic misreporting by arms.
  • The algorithm proves that arms will comply with the GTC under Nash Equilibrium to maximize their selection probability.
  • MESHA shows a bounded failure probability within a fixed budget, outperforming existing state-of-the-art algorithms in strategic settings.
  • Numerical experiments confirm MESHA's effectiveness compared to baseline methods that rely on optimal design sampling rules.
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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
  • Introduces a decoupled training strategy that eliminates backbone backpropagation.
  • Proposes normalization tuning for efficient domain adaptation.
  • Develops margin-based weighted training for improved classifier performance.
  • Achieves competitive accuracy on medical benchmarks with reduced training time.
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Uncertainty-Aware Sequential Decision Rules for Event-Triggered LLM Invocation in Streaming Systems
Zhaohui Wang
Theory Large Language Models Optimization
  • Introduces a unified risk-based framework for event-triggered LLM invocation.
  • Proves six theoretical results related to trigger policies and risk functions.
  • Empirically validates the framework using real sensor data and compares it against multiple baselines.
  • Demonstrates high diagnostic quality and effective cost sensitivity analysis.
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A Temporal Machine Learning-Based Time-to-Event Model for Predicting ALS Progression and Healthcare Utilization
Zongliang Yue, Qi Li, Terry Heiman-Patterson, Frank Bearoff, Zhaohui Qin, Huanmei Wu
Time Series
  • Development of a digital twin-inspired framework for predicting ALS progression.
  • Integration of longitudinal ALSFRS-R data with survival modeling for individualized predictions.
  • Identification of lower limb function as a key predictor for wheelchair access.
  • Implementation of a temporal machine learning model to capture disease progression.
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EMAGN: Efficient Multi-Attention Graph Network via Learned Clustering for Scalable Traffic Forecasting
Mingxing Xu, Rakesh Chowdary Machineni, Ke Liu, Xi Cheng, Chengqi Lu, Xin Hu, Lyuhao Chen, Xiangyu Li, Junwei You, Oliver Gao
Graph Learning Time Series Efficient ML
  • Introduces EMAGN, a scalable traffic forecasting model with linear complexity self-attention.
  • Achieves competitive accuracy while significantly reducing training and inference times.
  • Demonstrates the ability to operate under higher configurations without memory issues.
  • Outperforms existing linear attention models in both accuracy and efficiency.
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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
Time Series Interpretability Multimodal
  • Introduction of MOJO, a joint SSL-SL framework for spike-tokenizing models.
  • Demonstrated superior performance over traditional SL-only models, particularly in few-shot learning scenarios.
  • Enhanced interpretability of neuronal representations and improved performance on classification tasks.
  • Generalization of the framework to human ECoG data, achieving competitive results.
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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 test-time scaling with language model decoding for analog topology generation.
  • The framework employs simulator-guided Monte Carlo Tree Search (MCTS) to enhance the efficiency of topology generation.
  • By filtering structural tokens, EXPLORE reduces simulation trials, making it feasible to scale to higher-complexity circuits.
  • The success rate for generating valid topologies improved from 12% to 65% at a tight tolerance of 0.01.
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Sharp Stability Threshold and Certification for Designing Stable Residual Architectures
Hyemin Gu, Michael Tyrrell, Tuhin Sahai, Markos A. Katsoulakis
Theory Optimization
  • Establishes a stability threshold for residual architectures with the condition q ≤ 1.
  • Demonstrates that exceeding this threshold can lead to divergence in training.
  • Introduces an arithmetic framework for input-magnitude exponents to guide architectural design.
  • Confirms through experiments that architectures with q ≤ 1 train stably, regardless of normalization layers.
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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 Flow likelihood-ratio scoring in mono-Z DM search using CMS open data.
  • Defined signal and control regions based on kinematic properties of events.
  • Set observed upper limits on signal strength for scalar, vector, and axial-vector mediators.
  • Demonstrated the potential of NSFs to model complex event densities in high-energy physics.
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Privacy Leakage in Federated Learning in Radiology Reports: A Comparative Evaluation of Tokenizer-Driven Privacy Risks
Santhosh Parampottupadam, Andres Martinez, Dimitrios Bounias, Sinem Sav, Klaus Maier-Hein, Ralf Floca
Federated Learning NLP Large Language Models
  • Federated learning can lead to significant privacy leakage in radiology reports despite not sharing raw data.
  • Different tokenizer designs influence the extent of privacy leakage, with domain-specific tokenizers like RadBERT performing better in reconstructing clinical terms.
  • Exact sentence reconstruction accuracy ranged from 31% to 44% across different tokenizers and batch sizes.
  • Increased batch sizes generally resulted in lower reconstruction fidelity.
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NeuroGRIP: Retrieval-Augmented Graph Refinement for Knowledge-Grounded EEG Seizure Diagnosis
Lincan Li, Zheng Chen, Yushun Dong
Graph Learning Time Series Interpretability
  • NeuroGRIP integrates external medical knowledge to refine EEG seizure diagnosis graphs.
  • The framework constructs a domain-specific knowledge base from clinical guidelines.
  • It employs large language models for extracting structured biomedical knowledge.
  • NeuroGRIP enhances seizure detection accuracy and interpretability of predictions.
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Federated Explainable Artificial Intelligence: Roles, Architectures, Evaluation, and Open Challenges
Masoume Gholizade, Fabrizio Ruffini, Pietro Ducange, Francesco Marcelloni
Federated Learning Interpretability
  • FedXAI combines privacy-preserving Federated Learning with Explainable AI to enhance model transparency.
  • A multi-axis taxonomy is introduced to categorize FedXAI methods based on various dimensions.
  • Current evaluation practices for FedXAI are fragmented, lacking standardized benchmarks and metrics.
  • Open challenges include explainability under non-IID data and security threats related to explanations.
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The Hyperspherical Geometry of CLIP Latent Space: A Semantic Mixture Model
Zijie Yu, Gaowen Liu, Ramana Rao Kompella, Philip S. Yu, Yue Song
Multimodal
  • Introduces MovMF-CLIP, a model that captures the hyperspherical geometry of CLIP latent space using Mixtures of von Mises–Fisher distributions.
  • Demonstrates that Gaussian-based models inadequately represent the multimodal and directional nature of CLIP embeddings.
  • Achieves significant improvements in long-tailed and OOD detection, reducing false positive rates substantially.
  • Provides intrinsic interpretability by allowing embeddings to be decomposed into sparse combinations of semantic prototypes.
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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 targets to improve species identification in bioacoustics.
  • The model employs a multi-task learning approach to jointly train on species identification and metadata prediction.
  • Extensive experiments reveal that metadata significantly enhances model performance across various datasets.
  • The study provides insights into the importance of different metadata modalities and their effects on training.
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Analytical study of the optimal combination of binary classifiers based on classifiers-induced partitioning of the training set
Jean-Marc Brossier, Olivier Lafitte
Theory Optimization Efficient ML
  • Establishes conditions for the existence and uniqueness of the minimum of convexified empirical risk.
  • Derives analytical formulas for optimal weights, avoiding iterative optimization methods.
  • Introduces the concept of Ï•-frontiers to assess classifier stability and data quality.
  • Analyzes the implications of classifier-induced partitioning on the training set structure.
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What's in a Smoothness Constant? Tighter Rates for Local SGD with Bounded Second-order Heterogeneity
Kumar Kshitij Patel, Rustem Islamov, Sebastian U Stich, Aurelien Lucchi, Eduard Gorbunov, Lingxiao Wang
Optimization Federated Learning Theory
  • Establishes first convergence guarantees for Local SGD under bounded second-order heterogeneity in general convex settings.
  • Introduces a trajectory-dependent control of heterogeneity, improving upon traditional uniform bounds.
  • Demonstrates that Local SGD can outperform Mini-batch SGD without restrictive assumptions on first-order heterogeneity.
  • Provides nearly tight upper and lower bounds for Local SGD performance.
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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 method for long-horizon reinforcement learning tasks.
  • The approach utilizes a frozen reference model to evaluate intermediate actions without needing additional critics.
  • Significant performance improvements were observed on closed-web and open-web benchmarks.
  • TRACE enables faster convergence and earlier improvements in learning curves compared to traditional methods.
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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 inputs and categorical outputs.
  • The model outperforms traditional baselines in predicting next-period normalized returns in financial sequences.
  • Continuous-input representation improves performance over discrete-token branches while maintaining categorical objectives.
  • Full-sequence autoregressive supervision enhances model training compared to last-position training.
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Muse: Representation Geometry of Muon Beyond Normalized Momentum
Da Chang, Qiankun Shi, Lvgang Zhang, Di He, Yaoshuai Ma, Ganzhao Yuan, Yongxiang Liu
Optimization Large Language Models Theory
  • Muse optimizers introduce a representation-indexed view of Muon-style optimization.
  • Different matrix representations significantly affect the optimizer's geometry and performance.
  • Balanced non-native representations can match the performance of native representations in training.
  • Shorter dimensions in matrix representations weaken scaling and singular-channel support.
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Accuracy-Preserving Stability Regularization for Large-Scale Retail Demand Forecasting
Jize Li, Jiani He, Dishu Yang, Dingyan Shang, Jingjing Liu, Shiqi Huang
Time Series
  • Introduces a training-time penalty for consecutive forecasts to improve forecast stability.
  • Demonstrates that stability regularization can enhance forecast stability without significantly degrading point accuracy.
  • Evaluates the proposed method using a temporal-structured pipeline with various operational features.
  • Shows improvements in Forecast Stability Score over XGBoost while keeping RMSE changes minimal.
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Accelerating A/B-Tests with Counterfactual Estimation: Reducing Variance through Policy Overlap
Olivier Jeunen
Theory Efficient ML
  • Introduces a novel A/B-testing protocol leveraging policy overlap to reduce variance.
  • Establishes a variance dominance theorem proving that the proposed estimators outperform the standard Difference-in-Means estimator.
  • Identifies an optimal traffic allocation strategy based on policy divergence.
  • Proposes the Δ-MRDR estimator for minimizing ATE estimation variance.
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CoDiffGRN: Rethinking Gene Regulatory Network Inference via the BEELINE-KGC Benchmark and Co-evolutionary Discrete Diffusion
Jiaze Song, Runhao Zhao, Minghao Xu, Bin Cui, Wentao Zhang
Graph Learning
  • Introduces BEELINE-KGC, a new benchmark for GRN inference that emphasizes inductive generalization and top-K ranking.
  • Presents CoDiffGRN, a co-evolutionary discrete diffusion model that captures the conditional nature of gene regulations.
  • Implements a cell-cluster-based discretization strategy to enhance the robustness of predictions for unseen genes.
  • Demonstrates significant improvements in regulatory discovery compared to existing state-of-the-art methods.
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HyperShadow: A Benchmark for Detecting 3D Projections of Higher-Dimensional Spatial Objects
Akshay Sasi
Computer Vision Theory
  • HyperShadow is the first benchmark for detecting 3D projections of higher-dimensional spatial objects.
  • Traditional intrinsic-dimension estimation methods fail to accurately identify shadows, achieving only 71-73% accuracy.
  • A compact learned point network achieves 96.2% accuracy in detecting projections.
  • The rigidity witness statistic effectively separates classes with an AUROC of 0.982.
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Scalable Training of Continuous-Time Spiking Neural Networks with Differentiable Spike-Time Discretization
Yusuke Sakemi, Tomoya Takeuchi, Takeo Hosomi, Kazuyuki Aihara
Efficient ML Theory Time Series
  • Introduces a memory-efficient framework for training continuous-time SNNs using differentiable spike-time discretization (DSTD).
  • Reduces memory consumption from O(NoutNin) to O(NoutM) for time-to-first-spike coding.
  • Implements synfire-chain-inspired temporal regularization to improve layer-wise firing organization and reduce dead-neuron issues.
  • Achieves up to 100-fold reduction in peak memory and 20-fold decrease in training time compared to traditional methods.
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Task-Oriented Sensing and Covert Transmissions for Collaborative Multi-AUV Systems
Xueyao Zhang, Chenyang Yan, Bo Yang, Xuelin Cao, Zhiwen Yu, Bin Guo, George C. Alexandropoulos, Merouane Debbah, Chau Yuen
Reinforcement Learning Robotics Optimization
  • Introduction of the SVR-MARL framework for multi-AUV systems.
  • Focus on practical communication constraints rather than idealized models.
  • Demonstration of improved task efficiency in covert operations.
  • Emphasis on the utility of sensed information for cooperative tasks.
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Decoding Market Emotion from Blockchain Activity: A Data-Driven Sentiment Classifier
Arthur G. Bubolz, Abreu Quevedo, Giancarlo Lucca, Rafael A. Berri, Eduardo Borges, Bruno L. Dalmazo
NLP Time Series Interpretability
  • Integration of blockchain data with social media sentiment to explain market behavior.
  • Focus on sentiment analysis rather than price prediction.
  • Gradient Boosting (XGBoost) achieved an F1-score of around 0.84 for sentiment classification.
  • SHAP values were used for model interpretability, enhancing transparency.
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Explainable Geospatial AI for Satellite Ground Station Siting Using LiDAR-Derived Terrain Intelligence
Shohini Sarkar, Smithi Mahendran, Rishi Chudasama, Varun Mannam, Arav Luthra, Yuvraj Rekhi, Vivek Nadig, Arsh Goenka
Interpretability
  • Introduces a machine learning framework for predicting Representative Clutter Height (RCH) using LiDAR and open geospatial data.
  • Achieves a mean absolute error of 1.79 m, significantly improving upon traditional fixed clutter height methods.
  • Utilizes LightGBM for its accuracy and efficiency, along with SHAP for feature attribution analysis.
  • Demonstrates the potential for improved site selection and reduced uncertainty in satellite ground station siting.
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Supervised Fine-Tuning vs. In-Context Learning: An Equilibrium Analysis of LLM Personalization under Congestion
Fengzhuo Zhang, Zhuoran Yang, Dirk Bergemann
Large Language Models NLP Theory
  • SFT and ICL are optimal in different regimes influenced by pretraining coverage and data quality.
  • Congestion from multiple users can flip the performance ranking of SFT and ICL.
  • Equilibrium resource consumption is non-monotonic, with various factors affecting congestion levels.
  • Offering both SFT and ICL maximizes platform profits, aligning with observed trends in AI service offerings.
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Counterfactual Optimal Action Trees (COAT): Interpretable Prescriptive Policies from Observational Data
Youssef Drissi, Markus Ettl, Shivaram Subramanian, Wei Sun, Zack Xue
Optimization Interpretability
  • COAT combines counterfactual outcome estimation with mixed-integer optimization for interpretable decision-making.
  • The framework was validated in a live pilot with a major airline, achieving significant revenue increases.
  • COAT addresses the challenge of deploying AI in regulated environments by ensuring decisions are interpretable and compliant.
  • The study illustrates the potential of operations research to enhance AI-driven decision systems.
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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 allows for flexible inner rank expansion, enabling precise control over quantization accuracy.
  • The method can achieve accuracy levels approaching bf16, surpassing limitations of fixed-plane ternary quantization methods.
  • A batched block-ALS GPU algorithm significantly improves computational efficiency while maintaining accuracy.
  • Empirical results show ExTernD's effectiveness on various LLMs, achieving competitive performance metrics.
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Learning in Infinitesimal Non-Compositional Sketches
Sridhar Mahadevan
Theory
  • Introduces LINCS, a categorical framework for addressing non-compositionality in ML.
  • Defines Infinitesimal Non-Compositionality (INC) as an obstruction to factorization in learning sketches.
  • Establishes Tangent Learning Sketches to ensure admissibility of tangent lifts.
  • Proves the existence of a final INC coalgebra and discusses convergence properties.
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Towards a Unified Multidimensional Explainability Metric: Evaluating Trustworthiness in AI Models
Georgios Makridis, Georgios Fatouros, Athanasios Kiourtis, Dimitrios Kotios, Vasileios Koukos, Dimosthenis Kyriazis, Jonh Soldatos
Interpretability
  • Introduction of a unified multidimensional explainability metric for XAI methods.
  • Focus on fidelity, simplicity, and stability as key aspects of explainability.
  • Development of an offline knowledge base for context-dependent evaluation.
  • Demonstration of the framework on three open-source datasets.
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Local Additive Feature Attribution: A Mathematical Taxonomy and Reporting Checklist
Rebecca Afriyie Sarpong, Daniel Commey
Interpretability
  • Proposes a common framework for local additive feature attribution methods.
  • Organizes methods around five specification choices that influence their assumptions and failure modes.
  • Identifies common failure modes linked to the mathematical assumptions of attribution methods.
  • Introduces a ten-item reporting checklist for studies using local additive attributions.
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A Minimal Interpretable Architecture for Zero-Shot Reconstruction of Dynamical Systems
Christoph Jürgen Hemmer, Florian Plaswig, Daniel Durstewitz
Time Series Interpretability Efficient ML
  • DynaBase is a minimal two-parameter model for zero-shot dynamical system reconstruction.
  • It achieves competitive performance with significantly fewer parameters than existing models.
  • The model allows for closed-form solutions for prediction MSE and direct optimization on reconstruction metrics.
  • Different training strategies lead to fundamentally different outcomes in model performance.
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Adaptive Ad Load Design for Sponsored Search Markets: Evidence, Theory, and Deployment
Mohammad Rashid, Hema Yoganarasimhan
Optimization Theory
  • Increasing ad load can significantly raise revenue but may negatively impact user engagement and search conversions.
  • The effects of ad load vary considerably across different queries, with high-ad-conversion queries benefiting more than low-conversion ones.
  • The proposed e-LAAL algorithm effectively adapts ad load in real-time, improving performance over static benchmarks.
  • The study emphasizes the importance of understanding user intent and advertiser composition in ad load design.
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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 for improved robustness in satellite channels.
  • Joint optimization of traffic sign reconstruction and classification tasks.
  • Implementation of a composite perceptual loss for enhanced image quality.
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Auditing Fairness-Privacy Trade-offs: Subpopulation-Level Effects of Fairness-Enhancing Algorithms
Umid Suleymanov, Ilhama Novruzova, Khalid Mammadov, Natavan Hasanova, Murat Kantarcioglu
Theory
  • First systematic audit of how fairness-enhancing algorithms affect subgroup-level privacy risk and utility.
  • Extension of the Likelihood Ratio Attack (LiRA) for subgroup-specific privacy auditing.
  • Characterization of the interaction between Differential Privacy and fairness interventions.
  • Demonstration that fairness and privacy are not inherently conflicting objectives.
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Grad2Fair: A Gradient-driven Approach for Graph Fairness without Demographics
Yuchang Zhu, Zezhong Xie, Huizhe Zhang, Huazhen Zhong, Jintang Li, Liang Chen, Zibin Zheng
Graph Learning
  • Grad2Fair provides a solution for achieving fairness in GNNs without demographic information.
  • The method utilizes gradient distributions of misclassified nodes to infer and mitigate bias.
  • GradDist is introduced as a metric to quantify bias in gradient distributions.
  • Experimental results show that Grad2Fair outperforms traditional fairness methods.
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PolyQ: Codesigning End-to-End Quantization Framework for Scalable Edge CPU LLM Inference
Hyunwoo Oh, Suyeon Jang, Hanning Chen, KyungIn Nam, Sanggeon Yun, Ryozo Masukawa, Mohsen Imani
Large Language Models Efficient ML
  • PolyQ enables flexible, activation-aware channel-wise mixed-precision quantization for CPUs.
  • The framework reduces activation reorder traffic by up to 70.8% and maintains low latency.
  • It improves perplexity by 2.4–32.1% over previous methods at a 3-bit target.
  • PolyQ supports a wide range of bit-widths, allowing for better adaptation to diverse deployment scenarios.
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Self-Improving is Often Sudden: Enlightenment-style Finetuning for Large-Scale Models
Jing-Xiao Liao, Tianwei Zhang, Yu-Hao Jiang, Feifei Zhang, Hang-Cheng Dong, Feng-Lei Fan
Large Language Models Multimodal Efficient ML
  • Introduces the concept of 'Enlightenment' for self-improvement in large-scale models.
  • Proposes a training-free post-tuning method that modifies internal shortcuts without weight updates.
  • Demonstrates significant performance improvements across multiple benchmarks for both language and vision-language models.
  • Emphasizes the importance of sudden capability boosts akin to human 'aha moments'.
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CARPRT: Class-Aware Zero-Shot Prompt Reweighting for Black-Box Vision-Language Models
Ruijiang Dong, Zesheng Ye, Jianzhong Qi, Lei Feng, Feng Liu, Gang Niu, Masashi Sugiyama
Computer Vision Multimodal
  • Introduces CARPRT for class-aware prompt reweighting in zero-shot image classification.
  • Demonstrates that prompt relevance varies significantly across different classes.
  • Develops a training-free method to derive class-specific prompt weights using only unlabeled images.
  • Shows that CARPRT outperforms traditional class-agnostic reweighting methods.
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Heavy-Tailed Flow Matching via Random Clocks
Zhouhao Yang, Yezhen Wang, Kenji Kawaguchi, Vladimir Braverman, Haoyang Cao
Generative Models Theory Efficient ML
  • HTFM provides a unified framework for heavy-tailed flow matching using random clocks.
  • The model allows for the generation of various heavy-tailed distributions while retaining Gaussian properties under conditioning.
  • Truncated logsignature features enable efficient representation of clock paths, facilitating practical implementation.
  • Empirical results show significant improvements in sample quality and tail-statistic recovery compared to traditional methods.
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An Introduction to Sparse Identification of Nonlinear Dynamics for Engineering Applications
Yao Cheng Li, Ana Larrañaga, Steven L. Brunton, Urban Fasel
Time Series Interpretability Robotics
  • SINDy effectively identifies governing equations from small datasets, enhancing interpretability in engineering applications.
  • The method is adaptable to various challenges, including noise and sparsity in data, through its extensions.
  • Case studies demonstrate SINDy's practical application in complex engineering problems, such as UAV dynamics and thermosyphon heat exchange.
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Innocuous-Seeming Data, Latent Ideology: Ideological Generalisation in Finetuned LLMs
Robert Graham, Edward Stevinson, Yariv Barsheshat
NLP Large Language Models
  • Finetuning on narrow, moderation-passing datasets can lead to broad ideological shifts in unrelated domains.
  • The phenomenon of ideological generalisation can result in extreme outputs, including endorsements of harmful ideologies.
  • A methodology is proposed to quantify the breadth and amplification of ideological generalisation.
  • The effects of ideological generalisation replicate across different model families and evaluation methods.
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Lyapunov Guidance: A Unified Framework for Stabilizing Generative Flows
Jingdong Zhang, Xinze Li, Yize Jiang, Luan Yang, Minkai Xu, Junhong Liu
Generative Models Theory Reinforcement Learning
  • Introduces LyaGuide, a Lyapunov-guided framework for stabilizing generative flows.
  • Establishes a theoretical equivalence between guided flow matching and Lyapunov control.
  • Incorporates a pseudo-projection operator to enforce stability guarantees.
  • Supports both model-driven and data-driven guidance settings.
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Long-term User Engagement Optimization through Model-agnostic Downstream Rewards Learning
Dingsu Wang, Filip Ryzner, Kelly He, Armando Ordorica, David Woo, Aditya Mantha, Liyao Lu, Usha Amrutha Nookala, Haoran Guo, Jiacong He, Olafur Gudmundsson, Matt Chun, Krystal Benitez, Dhruvil Deven Badani, Yijie Dylan Wang
Optimization Reinforcement Learning
  • Introduces a model-agnostic framework for optimizing long-term user engagement in recommendation systems.
  • Develops an offline screening framework to identify predictive session-level behaviors for retention.
  • Proposes complementary downstream reward signals derived from user action patterns.
  • Demonstrates the effectiveness of the framework through online A/B testing on Pinterest.
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Branching Policy Optimization: Sandbox-Native Language Agent Reinforcement Learning
Bowei He, Yankai Chen, Xiaokun Zhang, Xue Liu
Reinforcement Learning Large Language Models NLP
  • Introduction of Branching Policy Optimization (BPO) as a sandbox-native RL algorithm.
  • BPO utilizes a single tree structure for rollouts, reducing variance in advantage estimation.
  • Proven unbiased advantage estimator with lower variance compared to traditional methods.
  • Empirical results show significant performance improvements over existing algorithms.
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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 improved knowledge tracing.
  • Decomposition of student interactions into ability and proficiency phases for better modeling.
  • Utilization of a multi-branch Transformer architecture to capture phase-specific knowledge states.
  • Causal analysis revealing biases in traditional phase-agnostic KT models.
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Beyond Entropy: Correctness-Aware Advantage Shaping via Contrastive Policy Optimization
Weiwen Xu, Jia Liu, Hou Pong Chan, Long Li, Deng Cai, Min Chen, Hao Zhang
Reinforcement Learning Large Language Models Optimization
  • CPO introduces contrastive disagreement as a more reliable token-level correctness signal than entropy.
  • The framework effectively addresses the zero-advantage problem in RLVR.
  • CPO enhances reasoning capabilities significantly over existing entropy-based methods.
  • The theoretical foundation of CPO unifies various On-policy Distillation approaches under a correctness-driven perspective.
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CASP: Learning-Augmented Offline Approximation with Verifiable Certificates and Bounded-Loss PAC Guarantees
Haifeng Li, Mo Hai
Optimization Theory Efficient ML
  • CASP uses verifiable certificates to ensure correctness in offline NP-hard optimization without relying solely on prediction quality.
  • The framework allows for the learning of certificate parameters from a bounded number of samples, improving sample efficiency.
  • Filtering predictions based on verifiable confidence significantly enhances performance compared to traditional methods.
  • The approach maintains optimality under distribution shifts, demonstrating robustness against prediction errors.
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LATTICE: Graph Self-Supervised Learning for Multimodal Spatial Omics Integration
Jagan Mohan Reddy Dwarampudi, Veena Kochat, Suresh Satpati, Kunal Rai, Tania Banerjee
Graph Learning Multimodal
  • LATTICE integrates multiple spatial omics modalities into a unified framework.
  • The framework employs self-supervised learning techniques to enhance representation learning.
  • Evaluation on melanoma data shows improved clustering and spatial contiguity with additional modalities.
  • LATTICE highlights the importance of multimodal integration for comprehensive biological insights.
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Integration Matters: Rollout-Based Training for Constrained Diffusion Models
Xiaoxuan Liang, Saeid Naderiparizi, Berend Zwartsenberg, Frank Wood
Generative Models Robotics Optimization
  • Introduces a fine-tuning framework that optimizes constraint satisfaction during the denoising process.
  • Aligns training with sampling by incorporating online rollout information into the training objective.
  • Demonstrates improved constraint satisfaction while maintaining high-quality sample generation.
  • Validates the method on practical tasks such as bouncing ball trajectories and traffic scene predictions.
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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
  • ShortOPD effectively recovers performance in pruned LLMs by focusing on effective rollout lengths.
  • The method demonstrates significant improvements in generation scores across various tasks compared to traditional recovery methods.
  • ShortOPD reduces training time and token usage while maintaining high-quality outputs.
  • The approach addresses the issue of suffix repetition that hampers recovery in compressed models.
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Depth-Dependent Hidden-State Collapse in Dynamical System Autoencoders for LiDAR Point-Cloud Classification
Patricia Medina, Hy P. G. Lam
Computer Vision Theory
  • Identification of a hidden-state collapse in DSAE architectures at encoder depth K = 5.
  • Demonstration that total hidden scatter is bounded by hidden-state variance, affecting class separation.
  • Evaluation of DSAE performance across different feature settings and classifiers.
  • Product Coefficients do not improve classification performance or prevent hidden-state collapse.
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Leveraging Instruction Tuning and Merging for Reasoning Model Adaptation
Yu-Du Feng, Niels Mündler-Sasahara, Mark Vero, Martin Vechev
NLP Large Language Models Reinforcement Learning
  • Introduces a practical adaptation method for RLMs using only input-output supervision.
  • Proposes a lightweight IFT-and-merge technique to adapt RLMs without requiring verifiers.
  • Demonstrates that the merging technique preserves reasoning capabilities while improving task-specific performance.
  • Evaluates the method across four RLMs and two tasks, showing superior cost-effectiveness compared to existing baselines.
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Random Logit Scaling: Defending Deep Neural Networks Against Black-Box Score-Based Adversarial Example Attacks
Hamid Dashtbani, Mehdi Dousti Gandomani, AmirMahdi Sadeghzadeh
Computer Vision Theory Efficient ML
  • Introduction of Random Logit Scaling (RLS) as a defense against black-box adversarial attacks.
  • RLS is a lightweight, plug-and-play solution that preserves model accuracy while reducing attack success rates.
  • Demonstration of RLS's effectiveness through experiments on CIFAR-10 and ImageNet datasets.
  • Introduction of the Pendulum attack to expose vulnerabilities in existing non-randomized defenses.
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ChronoQG: Towards a Temporally Expressive and Hop-Bounded Benchmark for Temporal Knowledge Graph Question Generation
Xuemeng Liu, Zhengpin Li, Wanpeng Tang, Haotong Xie, Wentao Zhang
NLP Graph Learning Time Series
  • ChronoQG is the first benchmark specifically designed for Temporal Knowledge Graph Question Generation (TKGQG).
  • The framework incorporates a detailed taxonomy of temporal constraints and sampling methods to ensure temporally faithful question generation.
  • Evaluation results indicate that current LLM-based methods struggle with preserving temporal constraints, especially in multi-constraint scenarios.
  • ChronoQG provides a substantial dataset of 16,011 verified questions for testing TKGQG methods.
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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
  • Identifies the structural mechanics of irrelevant conditions in decision trees.
  • Establishes a framework for relevance-aware rule deletion based on theoretical foundations.
  • Introduces a multi-layered approach to diagnose the relevance of path conditions.
  • Achieves substantial simplification of decision tree rules while maintaining reliability.
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TIDE: Trustworthy and Interpretable Battery Degradation Estimation with Contextual Learning and Symbolic Distillation
Wen Yang Tan, Jiawei Li, Fang Liu, Wei Zhang, Sumei Sun, Peng Cheng Wang, Elisa Y. M. Ang
Interpretability Time Series Optimization
  • TIDE integrates knowledge and operational data for improved battery SoH estimation.
  • The model features three components: a knowledge-guided prior, a monotone residual, and a contextual learning component.
  • TIDE achieves a 19.7% improvement in estimation accuracy over existing methods.
  • The approach emphasizes the importance of trustworthiness and interpretability in battery health assessments.
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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 framework for RF spectrogram anomaly detection.
  • Development of a validation-locked five-stage ablation protocol for systematic evaluation.
  • Demonstration of QKS's superiority over classical anomaly detection methods.
  • Real-world validation using actual measured RF signals and quantum hardware.
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