AI-generated summaries

Today's ML research,
without the noise.

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

50 Papers today
8h Update frequency
7 Days of history
Cross-Modal Generative Framework for Signal Translation from Fetal-Maternal Electrocardiograms to Fetal Doppler Waveforms
Tongli Su, Alireza Rafiei, Marly van Assen, Reza Sameni, Gari D. Clifford, Faezeh Marzbanrad, Nasim Katebi
Generative Models Multimodal Time Series
  • Introduction of a cross-modal generative framework for synthesizing fetal Doppler waveforms from fECG.
  • Demonstration of the importance of selective attention to maternal ECG for improved Doppler reconstruction.
  • Development of a composite loss function that balances pointwise error, derivative error, and correlation for waveform accuracy.
  • Significant reduction in PSD MSE and heart-rate error compared to baseline methods, indicating improved model performance.
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Collate: Collaborative Neural Network Learning for Latency-Critical Edge Systems
Shuo Huai, Di Liu, Hao Kong, Xiangzhong Luo, Weichen Liu, Ravi Subramaniam, Christian Makaya, Qian Lin
Federated Learning Efficient ML Optimization
  • Collate framework allows collaborative learning of heterogeneous models for edge systems.
  • Dynamic zeroizing-recovering method adjusts local model architectures to meet latency constraints.
  • Proto-corrected aggregation scheme effectively combines models from different edge devices.
  • Improvements in accuracy of 1.96% and 3.09% for extended and shrunk models, respectively.
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Structure Learning on Clustered Data
Ryan Thompson, Matt P. Wand, Veerabhadran Baladandayuthapani
Graph Learning Optimization Theory
  • Introduces a new framework for learning DAGs that accounts for cluster-specific variations.
  • Extends classical mixed models to structure learning, ensuring acyclicity in the combined graph.
  • Develops a first-order optimization method with provable convergence for scalable learning.
  • Establishes statistical identifiability and asymptotic recovery of the true structure.
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Contravariance Theory: Strong Alignment for Minimal Solutions to Hard Tasks
Dan Yamins, Aran Nayebi
Theory
  • Weak alignment of DNN representations can guarantee strong alignment of privileged axes.
  • Hierarchical alignment in DNNs leads to the emergence of privileged axes through task optimization.
  • The choice of metric for inter-network comparison is less sensitive with strong tasks.
  • Convergent evolution between artificial networks and biological systems is likely.
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Write-Protected Discrete Bottlenecks for Language-Grounded World Models: A Structural Limitation and Sufficient Fix
Jiayi Fang
Robotics NLP Multimodal
  • Language gradients entering discrete bottlenecks lead to a structural trade-off affecting learning and diversity.
  • A three-layer architectural fix is proposed to address the identified limitations in language-grounded world models.
  • The proposed architecture achieves high semantic grounding accuracy while being computationally efficient.
  • The findings challenge the end-to-end scaling paradigm in embodied AI, emphasizing the need for architectural separation.
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When Thinking Hurts: Epistemic Signals in the Reasoning Chains of Visual Language Models
Mayank Singal
Multimodal Large Language Models Interpretability
  • First empirical characterization of answer entropy behavior in thinking-mode VLMs across three model families.
  • Demonstrated that thinking chain entropy is a superior predictor compared to answer entropy.
  • Identified structured abstention affecting a significant percentage of queries.
  • Proposed a practical abstention gate that enhances accuracy without extra inference costs.
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Graph-Regularized Deep Learning for EEG-Based Emotion Recognition with Psychologically-Grounded Label Structure
Dongyang Kuang, Zizheng Ma, Yushan Zhang, Xiaocong Zeng
Graph Learning Time Series Audio & Speech
  • Introduces a novel graph-based regularization approach for EEG emotion recognition.
  • Incorporates psychological proximity into training objectives to improve classification accuracy.
  • Demonstrates architecture-agnostic benefits across multiple deep learning frameworks.
  • Achieves up to +5.42% accuracy improvement and 39% reduction in implausible misclassifications.
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Evaluating the Generalizability of Foundation Models for Extreme Environmental Events: Case Study of California Wildfire PM2.5
Yongcan Huang, Li Jiang, Ze Yu Liu
Time Series
  • First systematic benchmark of time series foundation models for extreme wildfire PM2.5 forecasting.
  • Fully-trained BiLSTM models consistently outperform TSFMs in all evaluation metrics.
  • Zero-shot TSFMs improve over naive persistence but struggle with extreme out-of-distribution conditions.
  • LoRA fine-tuning enhances performance but does not surpass fully-trained baselines.
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CAAD: Causality-Aware Multivariate Time Series Anomaly Detection via Multi-Scale Alignment and Structural Causal Consistency
Xin Wang, Yunshi Wen, Yanan He, Haotian Xu, Youlan Zhao, Michel Ferreira Cardia Haddad, Tengfei Ma
Time Series
  • CAAD introduces a causality-aware approach to anomaly detection, focusing on causal consistency rather than just temporal similarities.
  • The framework employs multi-scale temporal alignment to capture both fine-grained dynamics and coarse-grained trends.
  • Continuous causal verification is achieved through gradient-based Granger signals, allowing real-time detection of causal breakdowns.
  • Dual-perspective anomaly scoring combines dynamic and relational causal scores to enhance sensitivity to stealthy anomalies.
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ArtMine: Discovering and Formalizing Artistic Processes
Kaustubh Kumar, Ashutosh Ranjan, Vivek Srivastava, Blessin Varkey, Shirish Karande
Generative Models Multimodal Theory
  • Introduces artistic process discovery as a computational problem for generative AI.
  • Proposes ArtMine, integrating evidence construction, abductive reasoning, and self-reflection for artistic process reconstruction.
  • Demonstrates the ability to generate coherent production trajectories from heterogeneous historical evidence.
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Stop Guessing When to Stop Testing: Efficient Model Evaluation with Just Enough Data
Ofir Arviv, Kristjan Greenewald, Yotam Perlitz, Hadar Mulian, Michal Shmueli-Scheuer, Leshem Choshen
Efficient ML Theory
  • Fixed-size benchmarks are inefficient for diverse model evaluation needs.
  • The proposed adaptive evaluation framework uses sequential testing to optimize evaluation efficiency and reliability.
  • The framework allows users to define stopping criteria based on their specific evaluation objectives.
  • Empirical results show significant cost savings while maintaining statistical significance.
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LLT: Local Linear Transformer for PDE Operator Learning
Oded Ovadia, Eli Turkel
Efficient ML Theory Optimization
  • LLT combines linear global attention with local spatial mixing to improve PDE operator learning.
  • The architecture incorporates coordinate and geometry information to enhance performance.
  • LLT demonstrates competitive accuracy and significantly reduced training time compared to existing methods.
  • The model is scalable to large unstructured meshes, as evidenced by its application to a car aerodynamics dataset.
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Efficient Safety Alignment of Language Models via Latent Personality Traits
Mohamed Amine Merzouk, Nolan Smyth, Damiano Fornasiere, Linh Le, David Williams-King, Adam Oberman
NLP Large Language Models Efficient ML
  • Introduction of Latent Personality Alignment (LPA) as a novel method for safety alignment in LLMs.
  • LPA achieves near-zero attack success rates on harmful prompts while preserving model utility.
  • The training process is lightweight, requiring significantly fewer examples compared to traditional methods.
  • Extensive ablation studies clarify the factors contributing to LPA's robustness and efficiency.
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Super Weights in LLMs and the Failure of Selective Training
Shreyas Subramanian, Adewale Akinfaderin, Akarsha Sehwag
Large Language Models Efficient ML Theory
  • Super Weights do not universally lead to improved training outcomes when targeted in isolation.
  • Training Super Weights and their neighborhoods fails, while randomly chosen parameters in the same layers succeed.
  • LoRA's low-rank updates across entire layers outperform isolated training of Super Weights.
  • The study validates the structural consistency of Super Weights across diverse inputs.
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Predicting Male Fertility Using Machine Learning: A Semen Parameters Based Analysis with the VISEM Dataset
Shahnawaz Qureshi, Raja Khurram Shahzad, Muhammad Fozan, Emal Kawal, Syed Aziz Shah, Sattam Al-Anazi, Syed Muhammad Zeeshan Iqbal
  • Machine learning can classify male fertility status with high accuracy based on semen parameters.
  • The Nearest Centroid classifier achieved the highest accuracy (94.2%) among over 40 tested algorithms.
  • The study utilized the VISEM dataset, which includes semen samples from 85 participants.
  • Machine learning models can provide objective assessments, reducing observer bias in traditional semen analysis.
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Towards the Explainability of Temporal Graph Networks via Memory Backtracking and Topological Attribution
Yazheng Liu, Xi Zhang, Sihong Xie, Hui Xiong
Graph Learning Interpretability Time Series
  • Introduces a framework for explainability in Temporal Graph Networks that considers both memory updates and spatial interactions.
  • Utilizes topology attribution and memory backtracking trees to quantify contributions of neighboring and historical events.
  • Implements Layer-wise Relevance Propagation (LRP) to ensure the total contributions match model predictions.
  • Demonstrates improved explanation fidelity compared to existing methods through extensive experiments.
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MatBind: A Shared Embedding Space for Multimodal Materials Characterization
Le Yang, Anoop K. Chandran, Jona Γ–streicher, Evgenii Sovetkin, Adrian Mirza, Sebastien Bompas, Bashir Kazimi, Pascal Friederich, Stefan Kesselheim, Kevin Maik Jablonka, Stefan Sandfeld
Multimodal
  • MatBind aligns four key materials modalities into a unified embedding space.
  • The framework enables zero-shot retrieval between modality pairs not explicitly trained together.
  • Materials are organized according to meaningful properties without explicit supervision.
  • Combining modalities at query time improves retrieval performance significantly.
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Spectral Analysis of Dueling Q-Learning
Donghwan Lee
Reinforcement Learning Theory
  • Introduces a theoretical framework for analyzing unregularized Dueling Q-Learning.
  • Establishes convergence guarantees for both deterministic and stochastic versions of the algorithm.
  • Utilizes switching linear system theory to derive error bounds and convergence conditions.
  • Clarifies the roles of value and advantage updates in the Q-function decomposition.
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A law of robustness for two-layer neural networks with arbitrary weights
Yitzchak Shmalo
Theory
  • Proves a conjectured law of robustness for two-layer neural networks with arbitrary weights.
  • Establishes a Lipschitz constant lower bound for fitting noisy labels in high-dimensional data.
  • Introduces a function-space covering method to address the challenges posed by unbounded weights.
  • Demonstrates the results hold for various continuous piecewise-linear activations, particularly ReLU.
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KronQ: LLM Quantization via Kronecker-Factored Hessian
Donghyun Lee, Yuhang Li, Ruokai Yin, Priyadarshini Panda
NLP Large Language Models Efficient ML
  • KronQ integrates gradient covariance into the quantization pipeline, enhancing performance over traditional methods.
  • The framework introduces bidirectional incoherence processing to optimize weight distribution across dimensions.
  • A new sensitivity metric for mixed-precision allocation is derived from Hessian traces, allowing for better resource allocation.
  • Empirical results show significant improvements in perplexity for LLaMA models, particularly at low bit-widths.
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Multi-Modal, Multi-Environment Machine Teaching for Robust Reward Learning
Ali Larian, Qian Lin, Chang Zong Wu, Daniel S. Brown
Reinforcement Learning Robotics Theory
  • Introduces a comprehensive analysis of feedback modalities in machine teaching for reward learning.
  • Develops a hierarchical teaching algorithm (HSCOT) that operates across multiple environments.
  • Demonstrates that comparisons impose stronger constraints on reward functions than demonstrations.
  • Empirical results show lower regret and better generalization with HSCOT compared to uniform teaching methods.
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NFTR: From Provable Mode-Averaging to Geodesic Subgoal Selection in Offline Goal-Conditioned RL
Erdemt Bao, Xing Lei, Jun Chen
Reinforcement Learning Robotics Theory
  • NFTR addresses optimistic bias and mode collapse in HIQL by using Normalizing Flows for subgoal selection.
  • The triangle-slack score effectively downweights unreliable subgoals based on geometric consistency.
  • NFTR preserves population-level monotonic improvement and provides a clear suboptimality decomposition.
  • Empirical evaluations show substantial performance improvements over HIQL in offline GCRL tasks.
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Spectral Stability of Pseudoinverse-Based Extreme Learning Machine
Bich Van Nguyen, Ngoc Anh Khong
Theory Efficient ML Optimization
  • The smallest singular value of the hidden-layer matrix is crucial for output weight stability in ELM.
  • Condition number provides a quantitative measure of the hidden-layer matrix's instability.
  • SVD-based methods outperform iterative methods in terms of reliability under ill-conditioning.
  • Larger training sample sizes generally improve stability, while larger hidden widths can lead to poorer conditioning.
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Dimensionality Reduction Meets Network Science: Sensemaking on UMAP's kNN Graph
Duen Horng Chau, Donghao Ren, Fred Hohman, Dominik Moritz
Graph Learning
  • UMAP's kNN graph encodes high-dimensional manifold structure lost in 2D projections.
  • Standard graph algorithms can be applied to the kNN graph for enhanced data sensemaking.
  • PageRank, k-core decomposition, and clustering coefficients reveal insights into data representativeness, density, and local cohesion.
  • Graph-based analyses on MNIST and Fashion MNIST datasets show competitive performance compared to traditional clustering methods.
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Steering Neural Network Training through Interpretable Constraints Based on Partial Dependence
Yann Claes, Pierre Geurts, VΓ’n Anh Huynh-Thu
Interpretability Time Series Theory
  • Introduces a novel approach for steering neural network training using partial dependence.
  • Focuses on regression problems rather than classification, addressing a gap in existing literature.
  • Demonstrates improved model performance and data efficiency through the incorporation of domain knowledge.
  • Shows that interpretations from constrained models align better with user-provided knowledge.
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Architecture Generalization with MetaNCA
Meet Barot, Daniel Berenberg, Sina Khajehabdollahi
Efficient ML Theory Graph Learning
  • Introduction of MetaNCA for self-organizing neural network weights through local rules.
  • Utilization of a Weight Transformer architecture for local interactions on computation graphs.
  • Demonstrated generation of diverse neural network architectures without backpropagation.
  • Generalization to unseen architectures, enhancing adaptability and efficiency.
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ReCoLoRA: Spectrum-Aware Recursive Consolidation for Continual LLM Fine-Tuning
Wentao Lu
NLP Large Language Models Efficient ML
  • ReCoLoRA introduces a spectrum-aware framework for continual fine-tuning of LLMs, mitigating catastrophic forgetting.
  • The recursive consolidation mechanism allows for the preservation of knowledge from previous tasks while adapting to new ones.
  • ReCoLoRA outperforms existing low-rank adaptation methods in terms of final average scores and parameter efficiency.
  • The proposed ReCoLoRA-TaskBank variant serves as an upper bound for task retention by isolating task-specific branches.
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Latent Memory Palace: Reasoning for Control as Autoregressive Variational Inference
Chuning Zhu, Eva Xu, Jose Barreiros, Krishnan Srinivasan, Paarth Shah, Abhishek Gupta
Reinforcement Learning Robotics Generative Models
  • Introduces Latent Memory Palace (LMP) for iterative and adaptive reasoning in robotic control.
  • Utilizes autoregressive variational inference to organize control-relevant information in latent space.
  • Demonstrates strong empirical performance in both simulated and real-world robotic tasks.
  • Implements a variable-length action tokenizer (LMP-tok) that improves downstream policy performance.
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Workload-Preserving Differentially Private Synthetic Data for Causal Inference via Maximum-Entropy Calibration
Amir Asiaee, Kaveh Aryan
Theory
  • Introduction of causal workloads designed for differential privacy that focus on orthogonal moments for causal estimators.
  • Development of two methods for utilizing causal workloads: direct moment plug-ins and maximum-entropy synthetic data reconstruction.
  • Establishment of theoretical bounds connecting ATE error to workload error, with a detailed decomposition of synthetic data error.
  • Introduction of CAUSAL-AIM for adaptive workload selection and NA+MI for improved confidence interval estimation.
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Deep Learning Method for Stationary Distribution of Reflected Brownian Motion
Jim Dai, Zhanhao Zhang
Theory Efficient ML Optimization
  • Develops a deep learning method for estimating the Laplace transform of high-dimensional reflected Brownian motion.
  • Introduces a tailored loss function and sampling scheme to enhance model performance.
  • Achieves near-perfect prediction accuracy for tail probabilities in high-dimensional settings.
  • Demonstrates the potential of deep learning in analyzing complex stochastic systems.
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Deep Learning for Joint Narrowband Interference Cancellation and Soft Demodulation in OFDM Systems
Emmanouil Kavvousanos, Francky Catthoor, Vassilis Paliouras
Theory Efficient ML Optimization
  • Introduces a deep learning framework for joint NBI cancellation and soft demodulation in OFDM systems.
  • NBI-CNet reduces computational complexity by up to 60% compared to state-of-the-art methods.
  • LLR-CNet enhances soft metric calibration, eliminating error floors from traditional demodulation techniques.
  • Demonstrates robust performance under severe and mild interference conditions.
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Eigenvalue Calibration for Semantic Embeddings of Large Language Models
Sebastian G. Gruber, Nassim Walha, Francis Bach, Florian Buettner
NLP Large Language Models Theory
  • Introduces a novel calibration framework for eigenvalues of semantic embeddings in LLMs.
  • Establishes theoretical foundations linking entropy and risk in the context of eigenvalue calibration.
  • Demonstrates that current LLMs are systematically overconfident in their predictions.
  • Validates the effectiveness of temperature scaling in improving eigenvalue calibration.
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AutoAnchor: Stable Diffusion Unlearning Using Cross-Attention as a Manifold Surrogate
Siyuan Wen, Jiahao Zeng, Ningning Ding
Generative Models Computer Vision Theory
  • AutoAnchor synthesizes manifold-proximal anchors for stable diffusion unlearning.
  • The proposed method addresses the limitations of both anchor-based and anchor-free unlearning techniques.
  • Cross-attention consistency loss is introduced as a surrogate for optimizing manifold proximity.
  • Experimental results indicate up to 31.04% improvement in targeted concept removal.
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Beyond Backpropagation: Monte Carlo Method Can Train Deep Neural Networks
Hong Zhao
Optimization Theory Efficient ML
  • Introduces a gradient-free Monte Carlo method for training deep neural networks.
  • Demonstrates the method's effectiveness without requiring batch normalization or residual connections.
  • Validates the approach on deep networks exceeding 20 layers and various architectures.
  • Highlights the flexibility of the method in supporting discrete weights and unconventional transfer functions.
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Self-Adaptive Anomaly Detection with Reinforcement Learning and Human Feedback in Connected Vehicles
Matthias Weiß, Athreya Hosahalli Prakash, Maurice Artelt, Falk Dettinger, Nasser Jazdi, Michael Weyrich
Reinforcement Learning Robotics Time Series
  • Introduces a self-adaptive anomaly detection framework for connected vehicles.
  • Integrates reinforcement learning with human feedback for continuous adaptation.
  • Utilizes a factorized DQN for selecting appropriate detectors based on service dependencies.
  • Demonstrates effective performance in a real-world connected vehicle testbed.
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PIT-SUN: A Deployable Empirical Marginal Transform Framework with Expectation-Consistent Recovery for Regression in Recommender Systems
Mingyu Zhao, Zhaohan Li, Zhenxiong Miao, Xu Zhang, Dewei Leng, Yanan Niu, Kun Gai
Theory Optimization
  • PIT-SUN addresses the instability of gradients in traditional MSE methods for complex target distributions.
  • The framework employs a single empirical marginal table to define key components for expectation-consistent recovery.
  • Empirical validation shows robust improvements in performance metrics across diverse datasets.
  • The methodology emphasizes the need for a coordinated approach to target transformation and recovery.
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Selective Left-Shift: Turning Test-Time Compute and Difficulty-based Curation into Training Data for Low-Resource Code Generation
Didula Samaraweera, Anjana Supun, Srinath Perera
NLP Large Language Models Reinforcement Learning
  • Introduces a three-phase pipeline for improving code generation in low-resource programming languages.
  • Decouples syntax acquisition from algorithmic reasoning to address data scarcity and inference costs.
  • Utilizes offline data synthesis and verification strategies to generate high-quality training examples.
  • Achieves significant performance improvements on benchmark datasets with reduced data and cost.
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Image classification via a quantum-inspired strategy involving a mixture of experts
Kumari Jyoti, Rohith Babu, Apoorva D. Patel
Computer Vision Theory Efficient ML
  • Introduces a hybrid classical-quantum framework for image classification.
  • Utilizes a mixture of experts approach to enhance classification accuracy.
  • Demonstrates a significant reduction in failure rates for image classification tasks.
  • Shows that the quantum-inspired strategy is computationally feasible on GPU workstations.
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Ensemble Diversity Optimization for Subjective Supervision
Xia Cui, Ziyi Huang, N. R. Abeynayake
NLP Optimization Theory
  • Introduces Ensemble Diversity Optimization (EDO) for subjective NLP tasks.
  • EDO optimizes ensemble structure and diversity through a unified differentiable objective.
  • Employs a signed diversity regularizer to manage annotator disagreement effectively.
  • Demonstrates significant improvements in probabilistic calibration and alignment with annotator distributions.
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Linear Attention Architectures: Mechanisms, Trade-offs, and Cross-Layer Routing
Tommaso Cerruti, Tim Rieder, George Rowlands, Lingfeng Jin, Imanol Schlag
NLP Large Language Models Efficient ML
  • Introduces a unified framework for comparing softmax and linear attention architectures.
  • Demonstrates that Kimi Delta Attention with Muon optimizer achieves the lowest validation loss.
  • Gated DeltaNet shows the highest normalized training throughput among the architectures tested.
  • Presents Cross-Layer Value Routing (CLVR) as a lightweight mechanism that improves validation loss.
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Principled Analysis of Deep Reinforcement Learning Evaluation and Design Paradigms
Ezgi Korkmaz
Reinforcement Learning Theory
  • Critiques the implicit assumption of monotonic performance relationships in DRL research.
  • Introduces theoretical foundations on scaling laws affecting algorithm design and evaluation.
  • Demonstrates through experiments that many DRL algorithms are biased due to flawed evaluation paradigms.
  • Calls for a reevaluation of canonical methodological choices in DRL to improve research accuracy.
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A Practical Investigation of Training-free Relaxed Speculative Decoding
Guoxuan Xia, Luka Ribar, Paul Balanca
NLP Large Language Models Efficient ML
  • Relaxed speculative decoding can yield significant speed-ups but requires careful evaluation of model capabilities.
  • A unified framework for relaxed speculative decoding helps clarify the relationships and implementations of various methods.
  • Benchmarking across different inference settings allows for fair comparisons of relaxed decoding approaches.
  • Many relaxed approaches depend on a high-quality drafter model, limiting their applicability for lightweight scenarios.
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Optimal Learning Rate Scaling Depends on Data in Deep Scalar Linear Networks
Yedi Zhang, Peter E. Latham, Leena Chennuru Vankadara, Andrew Saxe
Theory Optimization
  • Optimal learning rate scaling in deep scalar linear networks is data-dependent.
  • Data-agnostic scaling rules fail to transfer effectively across network depths.
  • The proposed data-dependent scaling leads to constant linear convergence rates.
  • Similar effects are observed in deep scalar linear networks with residual connections.
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Who Gets Missed in the Tail? Thresholded Subgroup Underdiagnosis in Long-Tailed Chest X-ray Classification
Ha-Hieu Pham, Hai-Dang Nguyen, Dang P. M. Cao, Thanh-Huy Nguyen, Min Xu, Trung-Nghia Le, Ulas Bagci, Huy-Hieu Pham
Computer Vision
  • Introduces the concept of thresholded class-subgroup underdiagnosis as a measure of fairness in CXR classification.
  • Demonstrates that traditional performance metrics can obscure significant subgroup-specific underdiagnosis.
  • Implements a diagnostic ladder to analyze the impact of class-level losses, subgroup weighting, and threshold selection.
  • Shows substantial reductions in false negative rates for rare classes through tailored weighting and thresholding strategies.
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SHIFT: Survival Prediction from Incomplete and Heterogeneous Genomic Data
Muhammet Sami Yavuz, Ayhan Can Erdur, Sabri Mustafa Kahya, Benedikt Wiestler, Jana Lipkova
Theory
  • SHIFT is a transformer-based model that predicts survival from incomplete genomic data without the need for imputation.
  • The model employs a variable-rate masking strategy during training to improve robustness to cross-cohort data variability.
  • Incorporating incomplete cohorts in model training can enhance predictive performance on external datasets.
  • SHIFT demonstrates strong generalization across different cancer types and heterogeneous genomic panels.
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Modular Pretraining Enables Access Control
Ethan Roland, Murat Cubuktepe, Erick Martinez, Stijn Servaes, Keenan Pepper, Mike Vaiana, Diogo Schwerz de Lucena, Judd Rosenblatt, Addie Foote, Cem Anil, Alex Cloud
Large Language Models Efficient ML Theory
  • Introduces GRAM, a method for modular pretraining that enables selective capability management in AI models.
  • Demonstrates that GRAM can effectively disable specific capabilities while preserving others, outperforming traditional methods like post-hoc unlearning.
  • Shows significant cost reductions in training compared to training multiple models for different capabilities.
  • Evaluates GRAM across various domains, including virology and cybersecurity, confirming its robustness and effectiveness.
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Uncertainty-gated selection for block-sparse attention
Thomas Rossi
NLP Large Language Models Efficient ML
  • Introduces a value-of-information approach to improve block-sparse attention selection.
  • Enhances recall by expanding the selection set for uncertain queries without extra parameters.
  • Demonstrates compatibility with existing block-scoring methods like Quest.
  • Achieves significant performance improvements on standard benchmarks.
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When Does Continual Learning Require Learning
Anne Harrington, Nayan Saxena, Michael Murphy, Anastasia Borovykh, Zeyu Yun, Sridhar Kamath, Ara Eindra Kyi, Trevor Darrell, Jitendra Malik, Yutong Bai
Large Language Models NLP Reinforcement Learning
  • Continual learning in LLMs should focus on increasing competence as the environment changes.
  • The authors introduce a unified framework to evaluate various continual learning methods.
  • Different learning strategies exhibit unique strengths and weaknesses depending on the nature of change.
  • Prompt-based methods are quick to adapt but degrade on future tasks, while distillation methods are stable but slow to update.
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Frequency-Domain Multi-Modality Transportation Modeling
Jiewen Deng, Hangchen Liu, Junchen Li, Boyuan Zhang, Renhe Jiang
Time Series Multimodal
  • FreMo effectively addresses the limitations of existing time-domain methods by leveraging frequency domain characteristics.
  • The Modality-Wise Frequency Filter (MFF) enhances the quality of spectral components for each modality.
  • The Frequency-Guided Synergy Integrator (FSI) enables selective information sharing across modalities based on frequency reliability.
  • FreMo outperforms state-of-the-art methods in multi-modality transportation forecasting across diverse scenarios.
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Dynamics of Gradient Descent with Large Step Size Near a Manifold of Flat Minima
Lachlan Ewen MacDonald, RenΓ© Vidal
Optimization Theory
  • Generalizes previous convergence results for GD with large step sizes to vector-valued outputs.
  • Establishes a normal form for GD dynamics near a manifold of flat minima.
  • Introduces a novel method for solving singular partial differential equations relevant to the analysis.
  • Demonstrates that flat minima form a fiber bundle structure, enhancing understanding of optimization landscapes.
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