AI-generated summaries

Today's ML research,
without the noise.

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

48 Papers today
8h Update frequency
7 Days of history
On the effectiveness of reward functions in reinforcement learning for confidence calibration of large language models
Chee Heng Tan, Zhuoyi Lin, Mehul Motani, Wee Sun Lee
NLP Large Language Models Reinforcement Learning
  • Introduces the concept of non-hackable confidence reward schemes for LLMs.
  • Demonstrates the phenomenon of confidence reward hacking in practical datasets.
  • Establishes a spectrum of reward schemes to balance accuracy and confidence calibration.
  • Suggests treating the choice of reward scheme as a hyperparameter for optimization.
Read more
EquiFiLM: Charge-Conditioned Equivariant Force Fields via Feature-wise Linear Modulation
Samuel Sahel-Schackis, Ken-ichi Nomura, Aiichiro Nakano, Matthias F. Kling, Thomas Linker
Graph Learning Theory Efficient ML
  • EquiFiLM extends equivariant MLFFs to include continuous external conditioning, enhancing their applicability to non-equilibrium scenarios.
  • The method utilizes a lightweight FiLM block that preserves E(3)-equivariance and requires minimal additional training data.
  • E-MACE, the model developed using EquiFiLM, achieves substantial reductions in force and energy RMSE compared to traditional models.
  • The approach is adaptable to other equivariant MLFFs and can incorporate various external scalar variables.
Read more
Adversarial LassoNet: Robust Feature Selection via Stability-Driven Sparse Learning
Zhen Huang, Peicheng Xu, Junbiao Pang, Yulong Zheng
Optimization Theory
  • AdLNet integrates adversarial perturbations into the hierarchical sparsity mechanism of LassoNet.
  • The framework encourages feature selection that is both predictive and stable under local perturbations.
  • Experiments show a 4.4% improvement in out-of-distribution robustness and a 6.3% increase in feature support reproducibility.
  • AdLNet achieves a 5.3% test accuracy gain and a 6.0% AUC improvement on a lung cancer screening dataset compared to traditional methods.
Read more
Two Black Boxes, One Solver: Encoder Probing and Decoder Attribution for Neural Multi-Attribute VRP under Hard-Mask and Recourse Decoders
Sohaib Afifi
Optimization Interpretability Graph Learning
  • Introduces a dual-protocol for probing encoder representations and attributing decoder decisions in MAVRP solvers.
  • Demonstrates that graph inductive bias enhances representational predictability and decoder sanity.
  • Finds that the Mixture-of-Experts encoder represents constraints in a distributed manner.
  • Shows that the RECOURSE decoder can generate useful make-feasible counterfactuals, unlike the HARD-MASK decoder.
Read more
Masked Generative-Contrastive Representation Learning for Cross-Dataset EEG-Based Emotion Recognition
Huqin Weng, Jiayang Huang, Yimin Wen, Jie Du, Chi-Man Vong, Chuangquan Chen
Time Series Generative Models Graph Learning
  • MGCRL is the first framework to integrate masked generative and contrastive learning for EEG emotion recognition.
  • The region-aware spatiotemporal encoder enhances feature learning by addressing varying EEG channel configurations.
  • Generative learning via JEPA improves noise robustness and captures fine-grained emotional representations.
  • Contrastive learning boosts emotion discrimination and generalization across subjects.
Read more
Learning Sparsest Linear Causal DAGs with Latent Confounders via Higher-Order Cumulants
Ming Cai, Hisayuki Hara
Graph Learning Theory Interpretability
  • Introduces a finite-sample algorithm for recovering the sparsest DAG in canonical LvLiNGAMs.
  • Implements a new update rule that directly residualizes observed variables, enhancing performance.
  • Develops a sequential procedure for identifying exact parent-child relationships.
  • Demonstrates superior finite-sample performance through simulations and real data analyses.
Read more
Self-Review Reinforcement Learning (SRRL) with Cross-Episode Memory and Policy Distillation
Muhammad Zain Amin, Kibele Sebnem Yildirim
Reinforcement Learning Large Language Models
  • SRRL integrates a self-review mechanism into reinforcement learning episodes to enhance learning from sparse feedback.
  • The framework uses policy gradients to optimize self-reviews and internalizes improvements into the base policy.
  • Cross-episode memory allows the model to reuse successful self-reviews for similar tasks, improving learning efficiency.
  • SRRL outperforms traditional RLVR methods in final reward performance on the GSM8K benchmark.
Read more
EntroPath: Maximum Entropy Path Ensemble Embedding for Manifold Learning
Przemysław Rola
Graph Learning Theory Optimization
  • EntroPath utilizes maximum entropy random walks to enhance manifold learning by aggregating multiple diffusion paths.
  • The method provides a free-energy dissimilarity formulation that effectively approximates geodesic distances.
  • EntroPath shows significant advantages over traditional methods, especially in non-uniformly sampled manifolds.
  • The paper introduces scalable extensions for practical applications in trajectory inference and out-of-sample embedding.
Read more
CollabEval: Statistically Efficient Collaborative Model Evaluation via Matrix Completion
Adam Fisch, Daniel Deutsch, Joshua Maynez, Alekh Agarwal, Jonathan Berant, William Cohen, Amir Globerson, Jacob Eisenstein
Efficient ML Theory Generative Models
  • CollabEval treats model evaluation as a matrix completion problem, leveraging historical data to improve efficiency.
  • The method guarantees unbiased estimates and valid confidence intervals using control variates derived from imputed scores.
  • Empirical results show that CollabEval can reduce confidence interval widths by up to 30% compared to classical methods.
  • The approach requires minimal additional cost, as it avoids the need for generating model outputs for skipped prompts.
Read more
Statistically Meaningful Geometry and Gauge Symmetry Breaking: A Geometric Foundation for Scientific Discovery and Intelligence Emergence
Bing Cheng, Yi-Shuai Niu, Howell Tong, Shing-Tung Yau
Theory
  • Introduction of Statistically Meaningful Geometry (SMG) as a framework for understanding over-parameterized models.
  • Demonstration of gauge symmetry breaking (GSB) as a critical factor for genuine intelligence emergence.
  • Non-parametric deconstruction methods for analyzing core variables in machine learning systems.
  • Mathematical formalization of connections that relate geometry to intelligence and scientific discovery.
Read more
Unsupervised Anomaly Detection of Information Operations Users via Behavioral and Language Patterns
Sishun Liu, Sajal Halder, Ke Deng, Yan Wang, Xiuzhen Zhang
NLP Large Language Models Multimodal
  • TENSOR is an unsupervised approach that formulates IO user detection as an anomaly detection problem.
  • The method leverages both temporal behavioral patterns and language patterns from user post timelines.
  • A Temporal Point Process (TPP) is utilized to capture abnormal user behaviors associated with IOs.
  • The introduction of a novel evidence function enhances the detection accuracy by refining TPP outputs.
Read more
Hyperparameter Transfer in Graph Neural Networks
Gage DeZoort, Boris Hanin
Graph Learning Optimization Theory
  • Developed a framework for hyperparameter transfer in GNNs, enabling optimization of large models based on smaller counterparts.
  • Identified graph-dependent first-layer correction factors for SGD, enhancing early training performance.
  • Explored the effects of message passing normalizations on transfer behavior in GNNs, advocating for a global normalization strategy.
  • Adapted AdamW parameterization for joint transfer of weight decay and learning rate, improving training efficiency.
Read more
Co-Adaptive Multi-Task LoRA: Transfer-Aware, Label-Free Control of Domain Participation
Wei Zhang, Lin Tang, Ming Zhao, Yuxuan Wang
NLP Large Language Models Efficient ML
  • Introduces CODA, a co-adaptive controller for multi-task LoRA that optimizes domain participation.
  • Utilizes label-free signals to assess domain competence and cross-domain transfer affinities.
  • Demonstrates improved performance over traditional methods while using half the data.
  • Proves that the competence signal effectively tracks domain risk and informs participation decisions.
Read more
Integrating Physics-Informed Neural Networks for Safe Reinforcement Learning in a 1-DoF Helicopter System
Georg Schäfer, Jakob Rehrl, Stefan Huber
Reinforcement Learning Robotics Optimization
  • Integration of a differentiable physics model into the PPO algorithm enhances safety in reinforcement learning.
  • The approach allows for anticipatory safety measures without relying solely on complex reward shaping.
  • Evaluation on a 1-DoF helicopter system shows a trade-off between safety constraint satisfaction and task performance.
  • The method demonstrates potential for real-world applications in industrial control systems.
Read more
GRAFT: Grafted Reference Audio for Fine-grained Pronunciation in Zero-shot Text-to-Speech
Antonis Asonitis, Francesco Verdini, Aref Farhadipour, Vijeta Avijeet, Pierre-Edouard Honnet, Marzieh Razavi, Juan Pablo Zuluaga Gomez
Audio & Speech
  • GRAFT enables per-word pronunciation control in TTS without additional parameters.
  • It utilizes voice conversion to disentangle pronunciation from speaker identity.
  • The system significantly improves pronunciation accuracy for rare and difficult words.
  • GRAFT outperforms existing zero-shot TTS systems in multiple languages.
Read more
Self-Supervised Implicit CEST Reconstruction via Physics-Informed Lorentz Encoding
Dexuan Li, Yupeng Wu, Chenglong Wang, Hanlin Liu, Hui Zhen, Jianqi Li, Guang Yang
Theory Optimization Efficient ML
  • Introduction of Lorentz Encoding (LE) as a physics-informed framework for CEST MRI reconstruction.
  • Decoupled hybrid architecture combining spatial and spectral encoding to enhance reconstruction quality.
  • Demonstrated significant performance improvements over state-of-the-art methods under extreme sampling conditions.
  • Achieved high PSNR (57.58 dB) and SSIM (0.9994) metrics in in vivo experiments.
Read more
Learning When to Automate: Queue Control in Human-AI Service Systems
Giovanni Montanari, Marco Scarsini, Vianney Perchet
Theory Optimization
  • Introduces a novel queueing model for human-AI service systems that couples automation and human scheduling decisions.
  • Proposes the UCB-DPP policy, which effectively learns unknown parameters while managing queue dynamics.
  • Demonstrates theoretical guarantees of sublinear regret and stability in human-service queues.
  • Shows through simulations that UCB-DPP outperforms existing baseline policies in various scenarios.
Read more
Heckman-Corrected Epistemic Uncertainty: Selection on Unobservables Defeats Importance Weighting
Gunner Levi Howe
Theory
  • Importance weighting fails to correct for selection on unobservables, leading to biased predictions.
  • Heckman's two-equation model provides a robust framework for addressing selection bias in machine learning.
  • The proposed deep Heckman UQ method significantly improves predictive coverage in selected-against regions.
  • The stability of the joint maximum likelihood estimator requires careful warm-up scheduling.
Read more
Deep Reinforcement Learning for Dynamic Battery Management of Autonomous Order Pickers
Taniya Shaji, Abhay Sobhanan, Christof Defryn
Reinforcement Learning Robotics Optimization
  • Development of a multi-agent DRL framework using PPO for optimizing AMR routing and charging in warehouses.
  • Incorporation of a comprehensive action space for charging decisions, including when to recharge, which station to use, and duration of charging.
  • Dynamic modeling of order drop-off decisions to minimize unnecessary travel time for AMRs.
  • Explicit modeling of stochastic order arrivals and queuing dynamics at charging stations.
Read more
Scalable Perturbation Learning for Online Self-Supervised Echo State Networks
Taiki Yamada, Kantaro Fujiwara
Time Series Efficient ML Theory
  • Introduces a perturbation-based learning rule for online self-supervised learning in Echo State Networks.
  • Addresses variance scaling issues in high-dimensional systems by focusing on input-dependent components.
  • Demonstrates improved scalability and efficiency for online learning in ESNs.
  • Provides a theoretical foundation through orthogonal decomposition of the self-supervised cost function.
Read more
Teacher Supervision over Representation Equivalence Classes
Sang Il Han
NLP Large Language Models Theory
  • Knowledge distillation should focus on matching output functions rather than internal representations.
  • Pretrained representations are identifiable only up to an equivalence class, making absolute feature matching ill-posed.
  • Capability transfer is determined by class invariants, not by the specific coordinates of features.
  • Empirical results show that matching output distributions restores model capability, while matching internal representations does not.
Read more
SpecGradFilter: A Spectral Gradient Filtering Framework for Taming Federated Heterogeneity
Liyang Yuan, Yibo Yang, Dandan Guo, Peter Richtarik, Zhouchen Lin
Federated Learning Optimization Theory
  • Introduction of the 'Spectral Bias of Drift' concept in Federated Learning.
  • Development of SpecGradFilter to suppress low-frequency gradient components.
  • Demonstration of superior performance in Non-IID settings compared to existing methods.
  • Flexibility of SpecGradFilter allows integration into existing federated learning pipelines.
Read more
Low-Overhead Error-Corrected QCNNs Using Bivariate Bicycle Codes
Alejandro Rosales, Animesh Yadav
Theory Efficient ML Optimization
  • Introduces a low-overhead QEC technique for QCNNs using bivariate bicycle codes.
  • Demonstrates that unprotected QCNNs struggle with convergence under realistic noise levels.
  • Shows that the distance-4 BB code can improve learning rates and convergence in QCNNs.
  • Validates the effectiveness of the proposed QEC method through simulations.
Read more
Canopy: A Heterograph Foundation Model for Metabolic Engineering
Jake Bowden, Laurence Legon, Satnam Surae
Graph Learning Multimodal Optimization
  • CANOPY integrates ten diverse data sources into a unified knowledge graph for metabolic engineering.
  • The model utilizes domain-specific foundation models for multi-modal feature encoding.
  • A Heterogeneous Graph Transformer is employed for self-supervised pretraining.
  • CANOPY outperforms traditional tabular models and homogeneous GNNs in fermentation titer prediction.
Read more
Level-Crossing Density as a Mesh-Free High-Frequency Auxiliary Loss for Implicit Neural Representations
Gunner Levi Howe
Computer Vision Theory Generative Models
  • Introduces a mesh-free auxiliary loss based on Rice level-crossing density for INRs.
  • Addresses the spectral bias problem in neural representations by focusing on high-frequency content.
  • Validates the proposed loss against existing methods, showing significant improvements in performance.
  • Demonstrates robustness to irregular supervision and gradient-target quality.
Read more
Reward Granularity in RLVR: Comparing Process and Outcome Reward Structures for Mathematical Reasoning in Small Language Models
Anagha Radhakrishna Palandye, Rebecca Glick, Osheen Kaul
NLP Large Language Models Reinforcement Learning
  • Process-only rewards significantly improve accuracy and reasoning trace validity compared to outcome-only rewards.
  • Hybrid reward configurations can yield conflicting optimization signals, particularly in low-process/high-outcome setups.
  • Error analysis reveals different failure modes for process and outcome models, affecting the quality of reasoning outputs.
  • The study emphasizes the importance of reward granularity as a critical design decision in RLVR frameworks.
Read more
Evaluating Time Series Foundation Models for Electricity Price Forecasting: Contamination Risk, Distributional Shifts, and Covariate Dependence
Zhenghua Pan, Ahmed Aziz Ezzat
Time Series
  • TSFMs demonstrate strong performance in electricity price forecasting, often surpassing general-purpose models.
  • The effectiveness of TSFMs is significantly influenced by the availability of covariate information.
  • A two-dataset benchmarking framework is proposed to mitigate contamination risks in model evaluation.
  • Ensemble methods combining TSFMs and domain-specific approaches may yield improved forecasting results.
Read more
Graph Convolutional Attention: A Spectral Perspective on Graph Denoising and Diffusion
Shervin Khalafi, Igor Krawczuk, Sergio Rozada, Charilaos Kanatsoulis, Antonio G Marques, Alejandro Ribeiro
Graph Learning Theory Efficient ML
  • Linear attention is suboptimal for graph denoising due to its averaging of spectral properties.
  • Spectral Attention provides a theoretical framework that outperforms linear attention based on spectral diversity.
  • Graph Convolutional Attention (GCA) is introduced as a permutation-equivariant mechanism that implements spectral denoising effectively.
  • The softmax operation enhances denoising by approximating projections onto clean eigenspaces.
Read more
DynaVieW: Schema-Guided World Modeling for Understanding Hierarchical Visual Dynamics
Silin Gao, Hao Zhao, Zeming Chen, Sepideh Mamooler, Antara Raaghavi Bhattacharya, Qiyu Wu, Hiromi Wakaki, Yuki Mitsufuji, Li Mi, Syrielle Montariol, Antoine Bosselut
Multimodal Computer Vision Large Language Models
  • DynaVieW enhances visual dynamic understanding in multimodal LLMs by learning interleaved state-transition sequences.
  • The model employs a mixture-of-experts architecture with selective attention for robust learning.
  • DynaVieW achieves superior performance in visual narrative generation and world simulation tasks.
  • The schema-guided approach allows for better controllability and consistency in generated visual outputs.
Read more
InvWeaver: Deductive Feedback for Invariant Synthesis in Interacting-Loop Programs
Guangyuan Wu, Weining Cao, Zehui Tan, Yuan Yao, Hengfeng Wei, Taolue Chen, Xiaoxing Ma
Theory
  • INVWEAVER effectively synthesizes invariants for multi-loop programs, overcoming limitations of previous methods focused on single loops.
  • The framework utilizes a loop-level call graph to manage inter-loop dependencies and enhance context-aware reasoning.
  • A WP-guided refinement mechanism allows for the propagation of proof obligations, improving the accuracy of synthesized invariants.
  • Experimental results show INVWEAVER solves 72 out of 82 multi-loop benchmark problems, outperforming competitors by a significant margin.
Read more
Punching Above Their Weight: Classification-Head Fine-Tuning of Tiny Language Models (TLMs) for Verifiable Multiple-Choice Tasks
Bhavesh Sood, Jaromir Savelka
NLP Large Language Models Efficient ML
  • Introduction of Tiny Language Models (TLMs) for consumer device deployment.
  • Classification-head fine-tuning significantly outperforms label generation methods.
  • TLMs can achieve state-of-the-art performance on multiple benchmarks despite their smaller size.
  • The study highlights the importance of fine-tuning approaches in maximizing TLM performance.
Read more
PDEFlow: Autonomous Agentic PDE Pipelines for Neural Operator Learning and Solver-Free Inference
Akshat Jani, Prathamesh Gadekar, Sakhinana Sagar Srinivas, Venkataramana Runkana
Optimization Theory Efficient ML
  • PDEFlow automates the conversion of user-defined PDEs into neural operator pipelines.
  • The framework integrates problem specification, data generation, training, and inference in a single workflow.
  • Utilizes a stateful input graph to handle user inputs and modifications effectively.
  • Demonstrates the ability to generate solver-backed datasets and perform solver-free inference.
Read more
How Far is Too Far? Defining the Distance Threshold for Verification Siamese Networks
Heloísa Dias Viotto, Cauê Samonek, Lucas Garcia Pedroso, Marcos Sunye, André Abed Grégio, Paulo Lisboa de Almeida
Computer Vision
  • Proposes an unsupervised method for estimating verification thresholds in Siamese networks.
  • Models embedding distances as a bimodal function to identify the optimal threshold.
  • Eliminates the need for labeled data, allowing for dynamic updates in deployment.
  • Achieves an average verification accuracy of 94% across multiple datasets.
Read more
Learning to Control LLM Agent Harnesses with Offline Reinforcement Learning
Haiwen Yi, Xinyuan Song
Large Language Models Reinforcement Learning
  • The execution harness of LLM agents is proposed as a learnable control layer.
  • A Harness MDP framework is introduced to formalize the control decisions made by a lightweight controller.
  • The methodology employs offline reinforcement learning with advantage-weighted regression, focusing on terminal rewards.
  • A distinction is made between final task quality and harness process quality, with implications for learning behavior.
Read more
Leveraging Extragradient for Effective Sharpness-Aware Minimization in Deep Learning
Yao Fu, Chunxia Zhang, Junmin Liu, Yihang Jin, Haishan Ye, Yuanao Yang
Optimization Theory Efficient ML
  • EISAM improves upon SAM by incorporating an extragradient-inspired two-step update process.
  • The optimizer enhances generalization performance and reduces sensitivity to hyperparameters.
  • Extensive experiments show EISAM consistently outperforms traditional optimizers like SGD and Adam.
  • Theoretical analysis confirms that EISAM achieves flatter minima, leading to better generalization.
Read more
Heterogeneous Graph Condensation via Role-Aware Clustering
Fuyan Ou, Yulin Hu, Ye Yuan
Graph Learning Efficient ML Optimization
  • HGC-RC is designed specifically for heterogeneous graphs, addressing the limitations of existing condensation methods.
  • The framework utilizes role-aware clustering to differentiate between target and non-target nodes, enhancing classification performance.
  • HGC-RC achieves high compression rates while maintaining task performance, outperforming optimization-heavy baselines.
  • The method is computationally efficient, avoiding expensive iterative optimization processes.
Read more
GraphBU: MILP Instance Generation with Graph-Native Block Units
Xiaolei Guo, Chenyu Zhou, Jianghao Lin, Dongdong Ge
Optimization Graph Learning Theory
  • GraphBU is the first graph-native block unit generator for MILP instance generation.
  • It preserves the structural properties of the original MILP instances, enhancing feasibility and statistical similarity.
  • The methodology includes interface detection and compatibility-checked replacement of block units.
  • The generated instances improve the performance of downstream learning-based solvers.
Read more
Intuitionistic Fuzzy Graph Embedded Random Vector Functional Link with Multiview Learning
Vrushank Ahire, Yogesh Kumar, M.A. Ganaie
Graph Learning Theory Efficient ML
  • Introduction of intuitionistic fuzzy sets into the RVFL framework for better uncertainty handling.
  • Incorporation of graph embedding to preserve geometric relationships within data.
  • Utilization of multiview learning to combine information from multiple feature sets.
  • Statistical analyses confirm significant improvements in classification performance over existing models.
Read more
$\mathbf{\lambda}$-VAE: Variance Equalization for Posterior Collapse
Girum Demisse
Generative Models Theory Computer Vision
  • Identifies two causes of posterior collapse in VAEs: gradient imbalance and information gap.
  • Proposes λ-VAE, which modifies the reparameterization step to achieve variance equalization.
  • Demonstrates significant reductions in collapsed dimensions and improvements in reconstruction quality across multiple datasets.
  • Establishes a closed-form optimal exponent for scaling noise, controlled by a single hyperparameter.
Read more
SplineNet: An Isogeometric Deep Learning Method for Complex Shells
Shizhou Luo, Xiaodong Wei
Theory Interpretability Optimization
  • Introduction of SplineNet for integrating CAD and CAE in deep learning frameworks.
  • Utilization of watertight spline representations for exact geometric descriptions.
  • Ability to operate in both data-free and data-driven modes for enhanced flexibility.
  • Demonstration of effectiveness through numerical examples involving complex geometries.
Read more
AdaptiveSD A Stability-Aware, Runtime-Adaptive Speculative Decoding Framework with Multi-Policy Orchestration for CPU-Constrained LLM Inference
Sadra Saremi
NLP Large Language Models Efficient ML
  • AdaptiveSD integrates a closed-loop control architecture for adaptive speculative decoding.
  • The framework prioritizes resource preservation over raw throughput, addressing the limitations of fixed draft depths.
  • Achieves 68-82% speculative efficiency while maintaining low levels of wasted compute.
  • Effectively manages latency variance and resource usage, preventing system failures.
Read more
Physics-Informed Graph Learning with Uncertainty Awareness for Open-Set Domain Generalization in Fault Diagnosis
Jinfeng Zhu, Shiyu Long, Ye Yuan
Graph Learning Time Series Optimization
  • Introduction of PGU-OD framework for open-set domain generalization in fault diagnosis.
  • Development of PISA-Net for robust feature extraction that addresses frequency shifts.
  • Implementation of an uncertainty-aware adaptive graph learning mechanism to manage information propagation.
  • Creation of a dual-criteria decision-making strategy for effective unknown fault rejection.
Read more
OmniFocus: Query-Guided Modality-Balanced Token Compression for Omni-Modal Large Language Models
Shijie Cao, Qingyu Zhang, Boxi Yu, Yuzhong Zhang, Boxi Cao, Yaojie Lu, Hongyu Lin, Xianpei Han, Le Sun
Multimodal Large Language Models Efficient ML
  • OmniFocus mitigates modality bias in token compression by using query-guided importance estimation for both audio and video.
  • The method preserves inter-modal alignment and modality-specific salient evidence, enhancing performance in audio-visual tasks.
  • Experimental results show that OmniFocus outperforms existing token compression methods, achieving favorable accuracy-efficiency trade-offs.
Read more
Exogenous Dropout: A Simple, Strong Baseline for Corruption-Robust Time Series Forecasting with Covariates
Hao Hu, Xue-shan Ai
Time Series
  • Exogenous dropout significantly improves robustness in time series forecasting models against corrupted covariates.
  • The proposed method outperforms complex architectures designed for robustness, demonstrating that simpler interventions can be more effective.
  • The study establishes a comprehensive benchmark for evaluating corruption robustness across multiple domains and corruption types.
  • Architectural boundedness is shown to be unnecessary for achieving robustness, as unbounded models with dropout perform better.
Read more
Decision-Focused Scenario Generation and Selection for Efficient and Robust Grid Dispatch
Yangze Zhou, Yihong Zhou, Thomas Morstyn, Yi Wang
Generative Models Optimization
  • Introduces a decision-focused generative framework for scenario generation in DRO-based grid dispatch.
  • Optimizes generated scenarios based on their impact on operational costs rather than just accuracy.
  • Compatible with mainstream generative models, allowing for flexibility in application.
  • Includes a differentiable scenario selector to enhance computational efficiency.
Read more
Compressed Computation under $L^4$ Loss is likely Computation in Superposition
Francisco Ferreira da Silva, Stefan Heimersheim
Theory Optimization
  • The paper introduces a toy model of compressed computation that operates under L4 loss, demonstrating computation in superposition.
  • The trained network assigns sparse binary codewords to features, allowing for efficient decoding and recovery of performance.
  • A three-scalar parameterization can approximate the network's output, showcasing the potential for simplified representations.
  • The findings validate the use of L4 loss in eliciting computation in superposition, contrasting with traditional L2 loss.
Read more
CompactionRL: Reinforcement Learning with Context Compaction for Long-Horizon Agents
Yujiang Li, Zhenyu Hou, Yi Jing, Jie Tang, Yuxiao Dong
Reinforcement Learning Large Language Models
  • CompactionRL integrates context compaction into long-horizon reinforcement learning for LLMs.
  • The framework optimizes both task execution and summarization actions under a shared task-level reward.
  • Significant performance gains were observed on coding benchmarks, demonstrating the effectiveness of the approach.
  • The method allows LLMs to operate effectively within fixed context budgets, enhancing their utility in long-horizon tasks.
Read more
Knowing When to Stop: Predicting Execution-Consistency Convergence in Text-to-SQL
Yaron Anavi, Mor Aisenberg, Nadav Nesher, Elena Khabibullina, Isabella Cattinelli
NLP Large Language Models Efficient ML
  • Introduces a method for adaptive stopping in Text-to-SQL execution based on consistency convergence.
  • Develops lightweight models that outperform fixed-budget and principled stopping rules.
  • Demonstrates robustness against label noise, indicating practical applicability in production settings.
  • Utilizes run-order permutation as a training augmentation to improve model performance.
Read more