AI-generated summaries

Today's ML research,
without the noise.

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

53 Papers today
8h Update frequency
7 Days of history
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 enables the identification of governing equations from limited and noisy data.
  • The method provides interpretable models, enhancing understanding of system dynamics.
  • Case studies demonstrate SINDy's effectiveness in practical engineering scenarios.
  • The tutorial format allows for gradual learning and application of SINDy techniques.
Read more
A Noise-Robust Elicit-to-Optimize Framework for Distortion Riskmetrics via Inverse Reinforcement Learning
Yang Liu, Yuhao Liu, Yunran Wei
Reinforcement Learning Optimization Theory
  • Introduces a noise-robust framework integrating IRL and RL for risk preference elicitation and optimization.
  • Develops an adaptive Bayesian IRL method to handle noisy observed decisions and stochastic actions.
  • Establishes a finite set of questions for identifying distortion riskmetrics with proven convergence rates.
  • Implements a model-free RL algorithm that optimizes policies under conditional distortion riskmetrics.
Read more
A Minimal Interpretable Architecture for Zero-Shot Reconstruction of Dynamical Systems
Christoph Jürgen Hemmer, Florian Plaswig, Daniel Durstewitz
Time Series Interpretability Efficient ML
  • Introduction of DynaBase, a minimal two-parameter model for zero-shot dynamical system reconstruction.
  • DynaBase achieves competitive performance with significantly fewer parameters compared to existing models.
  • The model allows for closed-form solutions for prediction errors and direct optimization on reconstruction measures.
  • Different training strategies lead to fundamentally different model behaviors, emphasizing the importance of tailored training for dynamical systems.
Read more
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 decision-making.
  • The framework was validated in a live pilot with a major airline, resulting in significant revenue increases.
  • COAT addresses the need for interpretable and auditable AI systems in high-stakes business environments.
  • The approach demonstrates the practical value of integrating operations research with AI for decision support.
Read more
Position: Explainability Research Must Prioritize Foundations over Ad-hoc Methods
Michal Moshkovitz, Suraj Srinivas, Lesia Semenova, Nave Frost, Cyrus Rashtchian, Valentyn Boreiko, Shichang Zhang, Himabindu Lakkaraju, Cynthia Rudin, Jennifer Wortman Vaughan
Interpretability
  • Current XAI methods often lack real-world impact and are discarded without guiding action.
  • Foundational issues in XAI research include unclear definitions, evaluation criteria, and practical applications.
  • A human-centered approach is essential for making explanations understandable and actionable for stakeholders.
  • The paper proposes a checklist to guide the development of XAI towards a more structured and effective paradigm.
Read more
Multi-Axis Max@K Reinforcement Learning for Representative Diversity in Text-to-Image Generation
Ku Onoda, Paavo Parmas, Hiroki Furuta, Soichiro Nishimori, Yuta Oshima, Shohei Taniguchi, Yutaka Matsuo
Generative Models Reinforcement Learning Computer Vision
  • Introduces multi-axis max@K as a reinforcement learning objective for improving diversity in T2I generation.
  • Formulates the problem of limited diversity as target-mode coverage, focusing on visually distinct modes.
  • Demonstrates improved fairness in generated images without sacrificing quality or text alignment.
  • Validates the method through controlled experiments and real-world applications using SD3.5-M.
Read more
Augmentations for Robust and Efficient Imitation Learning in Streamed Video Games
Somjit Nath, Abdelhak Lemkhenter, Pallavi Choudhury, Chris Lovett, Katja Hofmann, Sergio Valcarcel Macua, Lukas Schäfer
Computer Vision Reinforcement Learning Efficient ML
  • Introduction of streaming augmentations to address visual artifacts in imitation learning.
  • Demonstrated significant performance improvements in agents trained with these augmentations.
  • Agents showed enhanced robustness to network lag and compression artifacts.
  • Utilization of predictive inverse dynamics models (PIDM) for efficient training.
Read more
RENEW: Towards Learning World Models and Repairing Model Exploitation from Preferences
Logan Mondal Bhamidipaty, Mykel Kochenderfer, Subramanian Ramamoorthy
Reinforcement Learning Robotics Efficient ML
  • RENEW addresses model exploitation in offline RL by using human preferences instead of expert demonstrations.
  • The proposed DLHF framework allows for direct supervision of world model dynamics based on human feedback.
  • RENEW improves sample efficiency and reduces catastrophic forgetting compared to naive DLHF.
  • The method effectively targets regions of model uncertainty to enhance learning.
Read more
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 based on five specification choices.
  • Identifies common failure modes in attribution methods linked to their underlying assumptions.
  • Introduces a ten-item reporting checklist to improve transparency in feature attribution studies.
  • Highlights the mathematical basis for disagreements among different attribution methods.
Read more
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 leverage different matrix representations to enhance Muon-style optimization.
  • The choice of representation significantly influences the geometry of the optimizer and its convergence properties.
  • Balanced non-native representations can match the performance of native representations in training scenarios.
  • Reducing the shorter dimension in matrix representations weakens optimization performance.
Read more
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 produce extreme outputs, even from seemingly innocuous data.
  • A new 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.
Read more
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 a graph-based approach to learn spot-level representations.
  • Significant improvements in clustering concordance were observed with the addition of scMultiome RNA.
  • Further modalities enhanced spatial contiguity but sometimes reduced agreement with RNA-derived labels.
Read more
Mutable Low-Rank Sketches for Retrain-Free Recommendation
Hector J. Garcia, Nick Clayton
Efficient ML Theory
  • Introduction of mutable sketches for real-time user embedding updates without retraining.
  • Theoretical proof of monotonic improvement in prediction accuracy with new observations.
  • Significant performance improvements in RMSE and update speed compared to traditional methods.
  • Demonstrated effectiveness of norm-proportional sampling in sparse data environments.
Read more
Gate-Zero Growth: A Geometric Framework for Function-Preserving Continual Learning
Dante Lok
NLP Large Language Models Theory
  • Introduction of gate-zero growth as a function-preserving operator for continual learning.
  • Demonstrates near-zero forgetting in a Transformer model through controlled geometric properties.
  • Establishes a unified framework that connects various existing methods under a shared geometric analysis.
  • Provides empirical validation of the framework's predictions regarding function preservation.
Read more
RTS Smoother-Guided Learning of Physics-Based Neural Differential Models
Ahmet Demirkaya, Georgios Stratis, Tales Imbiriba, Zachary D. Danziger, Deniz Erdogmus
Time Series Theory Interpretability
  • Introduces a hybrid neural-physics framework for modeling dynamical systems with incomplete dynamics.
  • Utilizes a two-stage iterative algorithm combining RTS smoothing and neural network parameter estimation.
  • Demonstrates improved latent-state reconstruction and long-horizon prediction across various dynamical systems.
  • Retains interpretability by keeping known ODE components explicit while learning unknown dynamics.
Read more
Branching Policy Optimization: Sandbox-Native Language Agent Reinforcement Learning
Bowei He, Yankai Chen, Xiaokun Zhang, Xue Liu
Reinforcement Learning Large Language Models Optimization
  • BPO leverages the deterministic nature of sandboxes to improve rollout efficiency.
  • The algorithm reduces variance in advantage estimation by using sibling returns.
  • Empirical results show BPO outperforms traditional methods like GRPO and RLOO.
  • BPO achieves similar performance with fewer policy updates and lower gradient variance.
Read more
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 a key concept in understanding learning sketches.
  • Establishes the existence of a final INC coalgebra and proves uniqueness of stabilized behavior.
  • Demonstrates the applicability of LINCS to various ML settings, including deep learning and reinforcement learning.
Read more
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 for market analysis.
  • Focus on explaining market sentiment rather than predicting prices.
  • Gradient Boosting (XGBoost) achieved an average F1-score of 0.84.
  • Use of SHAP for model interpretability, enhancing transparency.
Read more
Multimodal Semantic-Aware Contrastive Learning For False Negative Mitigation in 3D Medical Imaging
Sara Ketabi, Matthias W. Wagner, Cynthia Hawkins, Uri Tabori, Birgit Betina Ertl-Wagner, Farzad Khalvati
Multimodal
  • Introduces MseaCL to mitigate false negatives in multimodal contrastive learning for 3D medical imaging.
  • Incorporates semantic similarity from radiology reports to improve representation learning.
  • Demonstrates significant performance improvements in downstream tasks, particularly in pediatric brain tumor classification.
  • Enhances model explainability by aligning learned representations with clinically relevant features.
Read more
CASP: Learning-Augmented Offline Approximation with Verifiable Certificates and Bounded-Loss PAC Guarantees
Haifeng Li, Mo Hai
Optimization Theory Efficient ML
  • CASP framework allows for safe pruning of search space using verifiable certificates.
  • The correctness of the optimization process is independent of prediction quality.
  • Quantitative theory of confidence filtering shows significant performance improvements.
  • Learning of certificate parameters is efficient and bounded by sample complexity.
Read more
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 lightweight defense against black-box adversarial attacks.
  • RLS maintains model accuracy while significantly reducing the success rate of state-of-the-art attacks.
  • The paper presents the Pendulum attack, highlighting vulnerabilities in existing non-randomized defenses.
  • Experiments demonstrate RLS's effectiveness across multiple datasets and attack types.
Read more
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
  • Contrastive disagreement is proposed as a more reliable token-level correctness signal than entropy.
  • CPO effectively addresses the zero-advantage problem in RLVR, enabling more informative gradients.
  • The framework enhances reasoning capabilities in in-domain tasks while preserving out-of-domain performance.
  • CPO unifies diverse on-policy distillation variants under a single correctness-informed objective.
Read more
Accelerating A/B-Tests with Counterfactual Estimation: Reducing Variance through Policy Overlap
Olivier Jeunen
Theory Efficient ML
  • Introduces Δ-OPE framework to A/B-testing, allowing for unbiased ATE estimation.
  • Proves that the proposed estimators dominate the standard Difference-in-Means estimator under conditions of policy overlap.
  • Identifies optimal traffic allocation strategies based on policy divergence.
  • Develops Δ-MRDR estimator to minimize ATE estimation variance directly.
Read more
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 unified, model-agnostic framework for optimizing long-term user engagement in recommendation systems.
  • Develops an offline screening framework to identify session-level behaviors that predict future retention.
  • Proposes model-agnostic downstream reward signals based on user action patterns, enhancing the practicality of long-term optimization.
  • Demonstrates significant improvements in user engagement and retention through online A/B testing across multiple platforms.
Read more
Evaluating Epistemic Uncertainty: Beyond OOD Detection and Active Learning
Jakub Paplhám, Willem Waegeman, Eyke Hüllermeier, Vojtěch Franc
Theory Optimization
  • Unifies selective classification and epistemic reject-option into a single optimization framework.
  • Demonstrates that Bayes-optimal scorers for OOD detection, active learning, and regret-minimization reject different input space regions.
  • Proposes a new diagnostic for uncertainty disentanglement based on distance to the Pareto-optimal surface.
  • Finds significant discrepancies between decision-theoretic rankings and proxy-task rankings in uncertainty quantification methods.
Read more
Trajectory-Aware Flow Matching for Topology Optimisation
Shusheng Xiao, Jinshuai Bai, Hyogu Jeong, Yunfei Xi, Yilin Gui, YuanTong Gu
Generative Models Optimization
  • Introduction of Flow Matching-based Topology Optimisation (FMTO) framework for efficient topology generation.
  • Development of trajectory-aware formulation that incorporates intermediate states for improved design exploration.
  • Demonstration of enhanced generation stability with moderate trajectory weighting.
  • Numerical results indicate superior performance in compliance, volume-fraction satisfaction, and topology fidelity.
Read more
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-derived data.
  • Achieves significant accuracy improvements over traditional fixed clutter height methods, with a MAE of 1.79 m.
  • Utilizes SHAP for feature attribution, identifying critical predictors influencing RCH.
  • Demonstrates the model's global deployability and applicability in RF planning and site selection.
Read more
Counterfactuals for Feature-Weighted Clustering
Richard J. Fawley, Renato Cordeiro de Amorim
Interpretability
  • Introduction of VoICE, the first mechanism for incorporating feature weights into counterfactual explanations for clustering.
  • Extension from pairwise boundary projections to full weighted Voronoi-region projections for counterfactual generation.
  • Development of a constrained optimization framework that ensures counterfactual validity and incorporates actionability constraints.
  • Implementation of a homothetic contraction mechanism to enhance robustness and stability of counterfactuals.
Read more
Adaptive Runge-Kutta Step Control Buys Training Loss, Not Generalization: An Honest Compute-Matched Study of RK-Adam Optimizers
Akhilesh Gogikar
Optimization Theory
  • The RK3(2)-Adam variant underperforms compared to standard Adam in training loss under compute-matched conditions.
  • The adaptive control mechanism in the RK variant is ineffective without modifications.
  • Repairing the controller can lead to improved training loss but does not enhance test accuracy.
  • Gradient averaging serves as an implicit regularizer, outperforming other optimizers in specific scenarios.
Read more
MESHA: Mechanism-Enforced Sequential Halving for Strategic Linear Bandits
Xin Li, Zixin Zhong
Theory
  • MESHA integrates a naive uniform sampling rule with an epoch-wise Grim Trigger Condition to address strategic misreporting in linear bandits.
  • The algorithm is proven to maintain performance guarantees under weaker assumptions compared to previous methods.
  • State-of-the-art BAI algorithms fail in strategic environments due to their reliance on optimal design-based sampling rules.
  • Numerical experiments validate that MESHA outperforms existing baselines in identifying the best arm effectively.
Read more
PAC Learning in Turn-Based Stochastic Games with Reachability Objectives: A Decentralized Private Approach via Expected Conditional Distance
Ali Asadi, Krishnendu Chatterjee, Pavol Kebis
Reinforcement Learning Theory
  • Introduces decentralized and private learning for TBSGs with reachability objectives.
  • Generalizes the Expected Conditional Distance (ECD) parameter for TBSGs.
  • Establishes polynomial sample complexity bounds for learning algorithms.
  • Demonstrates that adversarial learning is infeasible in TBSGs with reachability objectives.
Read more
BadWAM: When World-Action Models Dream Right but Act Wrong
Qi Li, Xingyi Yang, Xinchao Wang
Robotics
  • Identification of World-Action Drift Attack as a specific vulnerability in WAMs.
  • Development of BadWAM, a unified framework for modeling and evaluating WAM-specific adversarial attacks.
  • Demonstration of significant task degradation in WAMs under adversarial conditions.
  • Introduction of two attack types: action-only and imagination-preserving, each targeting different aspects of WAM vulnerabilities.
Read more
Certified Domain Consistency for Multi-Domain Retrieval: Label-Free Per-Domain Contamination Control with Conformal Risk Guarantees
Jayakumar Manoharan
Theory
  • C3R provides a label-free per-domain contamination certificate, addressing the limitations of existing methods.
  • The method guarantees a reduction in contamination without requiring domain labels at inference time.
  • C3R demonstrates superior performance in retaining recall while controlling contamination compared to traditional methods.
  • The paper introduces BEIR-MIX, a public benchmark for evaluating multi-domain contamination.
Read more
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
  • Introduces Grad2Fair, a method for achieving fairness in GNNs without demographic data.
  • Develops GradDist, a gradient-based metric to quantify bias in graph predictions.
  • Demonstrates that gradient distributions of misclassified nodes can reveal demographic biases.
  • Shows superior performance of Grad2Fair over existing fairness methods in experiments.
Read more
Value Leakage: An LLM's Answers Are Silently Shaped by Its Own Values
Jan Betley, Johannes Treutlein, Jan Dubiński, Harry Mayne, Karol Gałązka, Niels Warncke, Anna Sztyber-Betley, Owain Evans
NLP Large Language Models
  • Covert value leakage occurs when LLMs' responses are influenced by their own values without disclosure.
  • Different types of biases were identified, including moral preferences and favoritism towards the developing company.
  • The study introduces a new evaluation framework to measure and quantify value leakage in LLMs.
  • Significant differences in value leakage were observed across various frontier models.
Read more
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, a framework for long-context RL training under fixed GPU budgets.
  • Demonstrates significant memory savings by optimizing the training graph and response replay.
  • Validates the approach on multiple model architectures, achieving up to 4.46M token contexts.
  • Highlights the importance of state lifetime and ownership in managing GPU memory.
Read more
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
  • CARPRT introduces class-aware prompt reweighting to improve zero-shot image classification.
  • The method captures class-specific prompt relevance without requiring labeled training data.
  • Empirical results show CARPRT outperforms existing class-agnostic reweighting methods.
  • The approach highlights the significance of prompt-class dependencies in VLM applications.
Read more
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 instruction tuning and merging.
  • Demonstrates significant performance improvements in both verifiable and unverifiable domains.
  • Preserves reasoning capabilities while leveraging large amounts of unused supervised data.
  • Offers a highly cost-effective solution for model adaptation.
Read more
Closed-Loop Knowledge Dynamics: An Operational Framework for Saturation and Escape
Xuening Wu, Shan Yu, Shenqin Yin
NLP Reinforcement Learning Optimization
  • Introduces a three-level operational framework for understanding closed-loop knowledge dynamics.
  • Defines structural change through detectable kernel discrepancies, making it empirically falsifiable.
  • Derives quantitative conditions for escaping saturation in knowledge systems.
  • Applies the framework to case studies in LLMs, RL, and Bayesian optimization.
Read more
Non-vacuous Generalization Bounds for Reinforcement Learning with Verifiable Rewards
Yuxuan Zhu, Rohan Alur, Daniel Kang
Reinforcement Learning Large Language Models Theory
  • Establishment of non-vacuous generalization bounds for RLVR fine-tuning.
  • Introduction of the Progressive RLVR framework for efficient model compression.
  • Demonstration of significant performance retention with high compression rates.
  • Empirical validation across multiple real-world domains.
Read more
Kernel weighted importance sampling for off-policy evaluation in contextual bandits
Joshua Spear, Matthieu Komorowski, Rebecca Pope, Neil J Sebire, Erica E.M. Moodie
Reinforcement Learning Theory
  • Introduction of Kernel-WIS, a new estimator for off-policy evaluation in contextual bandits.
  • Kernel-WIS shows asymptotic consistency and outperforms strong baselines, particularly under complex conditions.
  • The method combines the advantages of bounded weighted importance sampling with linearity, leading to reduced variance.
  • The paper emphasizes the importance of addressing behavior policy misspecification in off-policy evaluation.
Read more
Interleaved Noise Injection Improves Clean, Corrupted, and OOD Performance
Matt L. Wiemann, Peter Melchior, Andrew K. Saydjari
Optimization Computer Vision Theory
  • Introduction of interleaved noise curriculum enhances robustness and performance on clean, corrupted, and OOD tasks.
  • Theoretical formulation reveals impulse noise approximates Jacobian regularization, while Gaussian noise acts as a curvature penalty.
  • Gradient-norm stabilization technique prevents gradient volatility during noise injection.
  • Empirical results show significant improvements in accuracy across various datasets and architectures.
Read more
GAttNHP: Group Attention Neural Hawkes Process for Extrapolation Reasoning in Temporal Knowledge Graphs
Xiangni Tian, Kaixian Yu, Runpeng Dai, Niansheng Tang, Hongtu Zhu
Graph Learning Time Series
  • GAttNHP effectively captures long-range temporal dependencies in TKGs.
  • The model incorporates mutual excitation among event chains through a semantic soft-grouping mechanism.
  • NCQ regression offers robust time predictions, addressing issues with heavy-tailed inter-arrival distributions.
  • GAttNHP outperforms existing models on benchmark datasets, especially in challenging long-tail scenarios.
Read more
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 through gradient inversion attacks.
  • Different tokenizer designs (GPT-2, RadBERT, LLaMA-2) affect the extent of privacy leakage, with RadBERT providing the highest reconstruction fidelity.
  • No tokenizer completely mitigates the risk of privacy leakage, emphasizing the need for additional protective measures.
  • The study underscores the necessity of incorporating tokenizer design into privacy evaluations for clinical language models.
Read more
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-event metrics.
  • Demonstration of APAL's effectiveness across multiple forecasting models and datasets.
  • Provision of a diagnostic tool to assess the applicability of APAL based on dataset characteristics.
Read more
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
  • Introduces a method for optimal linear combination of binary classifiers using truth tables.
  • Establishes conditions for the existence and uniqueness of the global minimum of convexified empirical risk.
  • Derives explicit formulas for optimal weights, avoiding iterative optimization.
  • Introduces the concept of Ï•-frontiers for assessing classifier stability and data quality.
Read more
Data Driven Block Replacement Scheduling
Aniruddhan Ganesaraman, Vidyadhar Kulkarni
Optimization Theory
  • Introduces data-driven algorithms for block replacement scheduling of machines.
  • Models the problem as a stochastic multi-armed bandit with regret bounds.
  • Develops a Kaplan-Meier renewal algorithm for estimating lifetime distributions.
  • Analyzes average-cost MDPs to establish optimality and cost benchmarks.
Read more
Low-Latency Relay Selection in NR-V2X Vehicular Communications via Graph Isomorphism Networks with Edge Features
Giambattista Amati, Federica Mangiatordi, Emiliano Pallotti, Simone Angelini, Pierpaolo Salvo, Paola Vocca
Graph Learning Optimization
  • Introduces an edge-aware Learning-to-Optimize framework for relay selection in NR-V2X networks.
  • Utilizes Graph Isomorphism Networks with Edge Features to model and optimize relay-link activation.
  • Achieves high accuracy in relay selection while maintaining low inference latency suitable for real-time applications.
  • Demonstrates significant improvements in end-to-end connectivity compared to traditional MILP methods.
Read more
Sharp Stability Threshold and Certification for Designing Stable Residual Architectures
Hyemin Gu, Michael Tyrrell, Tuhin Sahai, Markos A. Katsoulakis
Theory Optimization
  • Introduces the sublinear-growth principle for stability in deep residual architectures.
  • Establishes q ≤ 1 as the threshold for stable training, supported by ODE theory and optimal-control analysis.
  • Develops an arithmetic of input-magnitude exponents for efficient architectural design.
  • Demonstrates that architectures with q ≤ 1 train stably, regardless of normalization layers.
Read more
On-Policy Delta Distillation
Byeongho Heo, Jaehui Hwang, Sangdoo Yun, Dongyoon Han
NLP Large Language Models Reinforcement Learning
  • Introduction of the delta signal as a new distillation reward for on-policy distillation.
  • OPD2 significantly improves upon traditional on-policy distillation methods.
  • Extensive empirical validation across diverse reasoning domains (Math, Science, Code).
  • Demonstrates that OPD2 enables efficient post-training for reasoning LLMs.
Read more
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 accuracy, trustworthiness, and interpretability in battery health estimation.
  • The model consists of three components: a knowledge-guided prior, a monotone residual, and a contextual learning component.
  • TIDE improves estimation accuracy by an average of 19.7% over baseline methods.
  • Symbolic distillation provides a compact and interpretable model representation.
Read more
Learning Who to Treat When Treatment is Missing
Johnna Sundberg, Rayid Ghani, Eli Ben-Michael, Edward Kennedy
Theory Efficient ML Optimization
  • Introduces methods for policy learning under missing treatment data, addressing a significant gap in existing literature.
  • Proves that MAR estimators are more efficient than MCCAR estimators, providing a formal argument against complete-case analysis.
  • Empirical validation shows that correctly specifying the missingness mechanism is critical for unbiased estimation.
  • Offers theoretically grounded tools for practitioners to improve treatment allocation decisions under budget constraints.
Read more
QFireNet: A Quantum-Enhanced U-Net for Wildfire Segmentation from Sentinel-2 Imagery
Jaiman Munshi, Tanvi Tewary, Sawyer Bloom, Aidan Chu, Chetan Maviti, Kyon Winston-Bey, Harshit Badjatia, Farhan Kittur, Vardhan Madhavarapu, Varun Kota, Joshua Kwon, Nazia Rangwala-Vohra, Franz Klein
Computer Vision
  • QFireNet integrates variational quantum circuits into a U-Net architecture to enhance wildfire segmentation.
  • Both quantum models outperform the classical U-Net baseline, indicating potential benefits of quantum machine learning.
  • Data mixing significantly mitigates domain shift issues, improving model performance.
  • The study introduces a compact U-Net architecture with reduced parameters while maintaining performance.
Read more