AI-generated summaries

Today's ML research,
without the noise.

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

43 Papers today
8h Update frequency
7 Days of history
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 graph-based approach to model emotional relationships in EEG emotion recognition.
  • Implements three regularization strategies to incorporate psychological proximity into training.
  • Demonstrates architecture-agnostic improvements across multiple deep learning models.
  • Achieves up to +5.42% accuracy and 39% reduction in implausible misclassifications on benchmark datasets.
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Systematic Evaluation of Learning Rate Scheduling Strategies Across Heterogeneous Architectures
Hafsa Mateen, Radu Timofte, Dmitry Ignatov
Optimization Computer Vision Efficient ML
  • Systematic evaluation of 25 LR scheduling strategies across 30 neural network architectures.
  • Architecture-specific preferences for LR schedulers were identified, with CosineAnnealingWarmRestarts and CyclicLR performing best.
  • The study generated 3,938 model variants, contributing to the LEMUR nn-dataset.
  • The best configuration achieved a top-1 accuracy of 86.45%, with many variants exceeding 80% accuracy.
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MPFlow: Learning Budgeted Max-Flow Optimization on the Lightning Network with Deep Graph Reinforcement Learning
Harrison Rush, Vincent Davis, Simone Antonelli, Vikash Singh, Jesse Shrader, Emanuele Rossi
Reinforcement Learning Graph Learning Optimization
  • MPFlow formulates liquidity placement as a budget-constrained combinatorial optimization problem on graphs.
  • The method utilizes a message-passing neural network combined with proximal policy optimization and action masking.
  • A hub-exclusion curriculum is employed to enhance the policy's learning of capacity-aware placements.
  • Extensive experiments show consistent performance improvements over heuristic baselines on the max-flow objective.
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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 governs perturbation amplification in ELM output weights.
  • Condition number provides a quantitative measure of hidden-layer instability.
  • SVD-based methods are more reliable than iterative methods under ill-conditioning.
  • Larger training sample sizes generally improve ELM stability, while excessive hidden width can deteriorate it.
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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 overconfident in their predictions and validates the calibration method empirically.
  • Proposes a new approach for visualizing calibration through reliability diagrams.
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Spectral Analysis of Dueling Q-Learning
Donghwan Lee
Reinforcement Learning Theory
  • Introduces a theoretical framework for understanding unregularized Dueling Q-Learning.
  • Establishes convergence guarantees for the constant step-size recursion.
  • Derives a finite-time error bound for the sampled stochastic version of the algorithm.
  • Clarifies the roles of value and advantage updates in the Q-function decomposition.
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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 results in performance collapse, while random parameter training in the same layers improves accuracy.
  • LoRA (Low-Rank Adaptation) successfully fine-tunes models by updating entire layers rather than isolated parameters.
  • The study validates the structural consistency of Super Weights across diverse inputs.
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Frequency-Domain Multi-Modality Transportation Modeling
Jiewen Deng, Hangchen Liu, Junchen Li, Boyuan Zhang, Renhe Jiang
Time Series Multimodal
  • Introduces a novel framework (FreMo) for multi-modality transportation forecasting.
  • Utilizes frequency-domain analysis to address challenges in traditional time-domain methods.
  • Employs Modality-Wise Frequency Filter (MFF) for spectral refinement and noise suppression.
  • Incorporates Frequency-Guided Synergy Integrator (FSI) for selective information aggregation.
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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 Efficient ML Theory
  • Introduces a hybrid classical-quantum framework for image classification.
  • Utilizes a mixture of experts approach to enhance feature extraction and classification.
  • Demonstrates improved performance on MNIST and Fashion-MNIST datasets.
  • Reduces failure rates of image classification by approximately 50%.
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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 spatial and temporal influences.
  • Utilizes topology attribution and memory backtracking to quantify contributions from neighboring and historical events.
  • Implements Layer-wise Relevance Propagation (LRP) to ensure accurate attribution of event contributions.
  • Demonstrates improved performance over existing explanation methods on multiple temporal graph datasets.
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Principled Analysis of Deep Reinforcement Learning Evaluation and Design Paradigms
Ezgi Korkmaz
Reinforcement Learning Theory
  • Critiques the implicit assumptions in DRL research regarding performance and sample complexity.
  • Introduces theoretical foundations on scaling laws in DRL.
  • Demonstrates through experiments that performance profiles are non-monotonic with respect to sample complexity.
  • Highlights the impact of canonical methodological choices on research conclusions.
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Architecture Generalization with MetaNCA
Meet Barot, Daniel Berenberg, Sina Khajehabdollahi
Efficient ML Optimization Theory
  • Introduction of MetaNCA, a framework for self-organizing neural network weights through local rules.
  • Utilization of a Weight Transformer architecture for local interactions in weight updates.
  • Demonstrated ability to generate diverse neural network architectures without backpropagation.
  • Generalization to unseen architectures, with improved performance through architectural diversity in training.
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DeepPySR -- A Symbolic Regression Framework with Dynamic Pruning, Pareto Selection, and Hierarchical Composition for Real-World Scientific Discovery
Fuling Chen, Kevin Vinsen, Phillip Melton, Rae-Chi Huang
Interpretability
  • DeepPySR provides a transparent alternative to black-box models by directly generating interpretable mathematical expressions.
  • The framework effectively addresses high-dimensional data challenges through dynamic variable pruning and hierarchical composition.
  • DeepPySR outperforms existing symbolic regression methods and traditional machine learning models across various scientific datasets.
  • The integration of a principled Pareto selection criterion enhances the selection of optimal models without extensive retraining.
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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 offer speed-ups but requires careful capability evaluation.
  • Many relaxed approaches depend on high-quality drafter models, which may not be suitable for lightweight applications.
  • The paper provides a unified framework for understanding various relaxed speculative decoding methods.
  • Benchmarking of relaxed approaches reveals significant differences in performance across different settings.
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Provably Optimal Learning Algorithms for Assistance Games
Nivasini Ananthakrishnan, Mark Bedaywi, Michael I. Jordan, Stuart Russell, Nika Haghtalab
Reinforcement Learning Theory Optimization
  • Introduces the concept of assistance regret for measuring performance in assistance games.
  • Presents decentralized algorithms achieving (1 - 1/e)-approximate assistance regret at a rate of ˜O(T^(3/4)).
  • Establishes computational intractability for achieving better than (1 - 1/e) regret approximation.
  • Demonstrates optimization of algorithms in a pseudo-decentralized setting for improved performance.
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SLORR: Simple and Efficient In-Training Low-Rank Regularization
David GonzΓ‘lez-MartΓ­nez, Shiwei Liu
Efficient ML Computer Vision Large Language Models
  • SLORR introduces a stateless, architecture-preserving framework for low-rank regularization.
  • The method avoids the computational burden of SVDs and cached quantities.
  • SLORR improves compressibility of neural networks with less than 8% training overhead.
  • The framework is validated across vision and language modeling tasks, showing superior performance retention post-compression.
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Understanding Layer Patching in Model Size Interpolation
Sara Kangaslahti, Jonathan Geuter, Nihal V. Nayak, Marco Fumero, Francesco Locatello, David Alvarez-Melis
NLP Large Language Models Optimization
  • Formalization of student patching as an optimization problem over interpolation curves.
  • Exhaustive study of patching orders reveals that simple strategies can yield strong performance.
  • Introduction of KLPatch, a greedy algorithm that approximates optimal layer patching efficiently.
  • Demonstration that patching order is a critical design choice for model size interpolation.
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A Transdiagnostic Space of Disorder Like Phenotypes in Reinforcement Learning Agents
Hari Prasad
Reinforcement Learning
  • Introduces a dose-controllable method for modeling psychological disorders in RL agents.
  • Demonstrates emergent properties of disorders, including a two-dimensional affective space.
  • Finds distinct recovery patterns for different types of disorders when manipulating parameters.
  • Validates the framework across multiple environments, confirming its generalizability.
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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, identifying three distinct patterns.
  • Thinking chain entropy is a more reliable predictor than answer entropy in VLMs, particularly in Qwen and GLM models.
  • Structured abstention affects a significant portion of queries, with implications for model reliability.
  • A practical abstention gate can significantly improve accuracy without incurring additional inference costs.
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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 is redefined as increasing competence in changing environments rather than just mitigating forgetting.
  • The authors introduce a unified framework for evaluating continual learning methods across different axes of change.
  • Different methods (prompt-based, distillation, context compression, reinforcement learning) exhibit unique strengths and weaknesses.
  • Understanding the nature of environmental change is crucial for determining the appropriate continual learning strategy.
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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, addressing catastrophic forgetting.
  • The framework employs recursive consolidation to preserve knowledge from previous tasks effectively.
  • ReCoLoRA-TaskBank serves as an upper bound for performance by isolating task branches.
  • Experimental results show ReCoLoRA achieves better performance than several existing methods with fewer trainable parameters.
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Federated Deep Learning for Privacy-Preserving Cardiovascular Disease Risk Prediction
Hyunho Mo, Djura Smits, Mahlet A. Birhanu, Maarten J.G. Leening, Daniel Bos, Pim van der Harst, Esther E. Bron
Federated Learning
  • Federated learning allows for collaborative model development without sharing sensitive patient data.
  • The study integrates two diverse cohorts to improve cardiovascular disease risk prediction.
  • Deep survival models trained through federated learning show superior performance compared to local models.
  • The approach maintains patient privacy while enhancing model generalizability across different populations.
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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
  • Introduces a novel approach to neural network training that incorporates partial dependence for improved interpretability.
  • Demonstrates that models trained with this method perform better and are more data-efficient than unconstrained models.
  • Aligns model interpretations with prior domain knowledge, enhancing the reliability of explanations.
  • Focuses on regression tasks, particularly in dynamical systems forecasting, expanding the application of explanation-guided learning.
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Open-ended Multi-agent Autocurricula via Visual Inspection of Policies with Multi-modal LLMs
Lorenzo Pantè, Andrea Fanti, Roberto Capobianco
Reinforcement Learning Computer Vision Multimodal
  • Introduction of Visual Inspection of Policies (VIP) for open-ended RL curricula.
  • VIP leverages episode videos processed by a Video Language Model (VLM) for task recommendations.
  • Empirical validation on the StarCraft Multi-Agent Challenge (SMAC) shows superior performance compared to traditional methods.
  • Demonstrates the importance of visual cues in assessing agent behavior and task difficulty.
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Predicting Pseudo-nitzschia harmful algal blooms along the Portuguese Coast using satellite-derived predictors
Ayman Bnoussaad, El Khalil Cherif, Ligia Pinto, Ramiro Neves, Alexandra D. Silva, Alexandre Bernardino
Time Series
  • Developed a machine-learning framework for predicting Pseudo-nitzschia HABs using satellite data.
  • Implemented a strict cross-validation strategy to prevent data leakage.
  • Achieved a ROC–AUC of 0.77 Β± 0.06 with Extra Trees model using biological predictors.
  • Identified key predictors including lagged sea surface temperature and chlorophyll-a.
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Towards Efficient Large Language Model Serving: A Survey on System-Aware KV Cache Optimization
Jiantong Jiang, Peiyu Yang, Rui Zhang, Feng Liu
NLP Large Language Models Efficient ML
  • The survey categorizes KV cache optimization techniques into temporal, spatial, and structural dimensions.
  • It highlights the importance of KV cache optimization for efficient LLM serving, particularly as model sizes and input lengths increase.
  • The authors propose a novel behavior-oriented perspective for analyzing KV cache optimization methods.
  • Future research opportunities are identified, particularly in cross-behavior co-design and behavior-objective links.
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Vanilla SGD with Momentum Survives Heavy-Tailed Noise: Convergence Analysis without Gradient Clipping or Normalization
Ryusei Yamada, Naoki Sato, Hideaki Iiduka
Optimization Theory
  • First theoretical guarantee of convergence for vanilla SGD with momentum under heavy-tailed noise.
  • Convergence rates established for strongly convex, convex, and nonconvex functions without gradient clipping or normalization.
  • Demonstrated that the condition Ξ½ + 1 ≀ p is crucial for stable convergence.
  • Results indicate that vanilla SGD with momentum can serve as a baseline for future algorithmic improvements.
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Uncertainty-gated selection for block-sparse attention
Thomas Rossi
NLP Large Language Models Efficient ML
  • Introduces a value-of-information router to enhance block-sparse attention in long-context models.
  • Achieves significant improvements in recall rates compared to traditional top-k selection methods.
  • The router is agnostic to the scoring backbone and can be combined with existing methods.
  • Demonstrates consistent performance across multiple models and architectures.
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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 is a rich resource for data analysis, often overlooked in favor of 2D visualizations.
  • Standard graph algorithms (PageRank, k-core decomposition, clustering coefficient) can provide valuable insights into data structure.
  • Graph-based analyses yield results that are competitive with traditional clustering methods.
  • The approach bridges dimensionality reduction techniques and network science, enhancing data sensemaking capabilities.
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Learning $ ext{AC}^0$ under Locally Sampleable Graphical Models
Weiming Feng, Xiongxin Yang, Yixiao Yu, Yiyao Zhang
Theory Graph Learning
  • Introduces a quasipolynomial-time learner for AC0 under locally sampleable graphical models.
  • Circumvents the polynomial growth requirement from previous works.
  • Establishes a new low-degree approximation technique for Gibbs distributions.
  • Applies the framework to hard-core and Ising models on bounded-degree graphs.
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Trustworthy Machine Learning through the Lens of Combinatorial Optimization: Survey and Research Perspectives
Thibaut Vidal, Julien Ferry
Optimization Theory Interpretability
  • Trustworthy ML requires more than just predictive accuracy; it necessitates transparency, interpretability, and fairness.
  • Combinatorial optimization offers a framework for addressing trustworthiness in ML, providing global guarantees and formal certificates.
  • The Rashomon effect allows for the selection of models that meet trustworthiness criteria without sacrificing performance.
  • Recent advances in CO techniques can be applied to various post-training tasks, enhancing the robustness and fairness of ML systems.
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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 materials modalities into a unified embedding space, facilitating cross-modal retrieval.
  • The framework allows for emergent zero-shot retrieval, outperforming directly trained modality pairs in some cases.
  • Materials are organized in the embedding space according to physically meaningful properties without explicit supervision.
  • Combining multiple modalities at query time enhances retrieval performance and resolves ambiguities.
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Reinforcing the Generation Order of Multimodal Masked Diffusion Models
Yidong Ouyang, Zhe Wang, Sourav Bhabesh, Dmitriy Bespalov
Generative Models Multimodal Optimization
  • Existing confidence-based strategies do not improve image generation quality and multimodal reasoning.
  • A learnable control block is proposed to optimize generation order using Group Relative Policy Optimization (GRPO).
  • The method shows significant improvements in text-to-image alignment and multimodal understanding benchmarks.
  • The research highlights the necessity of advanced order control mechanisms in multimodal tasks.
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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 study provides exact solutions for gradient descent dynamics using special functions.
  • Learning dynamics exhibit a constant linear convergence rate across all depths.
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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
  • Linear attention architectures can significantly reduce computational costs compared to traditional softmax attention.
  • Kimi Delta Attention with the Muon optimizer achieved the best validation loss among the architectures tested.
  • Gated DeltaNet demonstrated the highest training throughput, highlighting the trade-off between efficiency and accuracy.
  • Cross-Layer Value Routing (CLVR) provides a lightweight method for improving performance in DeltaNet-style architectures.
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Scalable and Trustworthy Earth Observation Foundation Models
Syed Usama Imtiaz, Mitra Nasr Azadani, Nasrin Alamdari
Computer Vision Multimodal Reinforcement Learning
  • Foundation models (FMs) are crucial for adapting to diverse downstream tasks in Earth observation.
  • Remote sensing data require specialized models due to their unique physical and operational characteristics.
  • Evaluation of RSFMs should consider not just accuracy but also transferability and physical plausibility.
  • Case studies demonstrate the practical implications of RSFMs in environmental monitoring.
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ArtMine: Discovering and Formalizing Artistic Processes
Kaustubh Kumar, Ashutosh Ranjan, Vivek Srivastava, Blessin Varkey, Shirish Karande
Generative Models Interpretability Multimodal
  • ArtMine shifts the focus from modeling completed artworks to reconstructing creative processes from historical evidence.
  • The framework integrates deep-research-based evidence construction with Peircean abductive reasoning.
  • A case study demonstrates the feasibility of using fragmented documentary evidence to infer structured artistic workflows.
  • ArtMine supports the development of interpretable and auditable representations of artistic processes.
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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 effectively maps non-Gaussian residuals to reliable soft metrics.
  • Demonstrates significant performance improvements under severe interference conditions.
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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 that limits performance.
  • A three-layer architectural fix is proposed to overcome the identified limitations.
  • The proposed solution achieves high grounding accuracy across various architectures and environments.
  • The findings challenge the end-to-end scaling paradigm in embodied AI.
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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 imputation.
  • The model employs a variable-rate masking strategy during training to enhance robustness to cross-cohort variability.
  • Incorporating patients from incomplete cohorts during model development can improve predictive performance.
  • SHIFT shows strong generalization across multiple cohorts, even with severe cross-cohort panel mismatches.
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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
  • Proposes an adaptive evaluation framework to replace fixed-size benchmarks.
  • Utilizes sequential testing to balance efficiency and reliability in model evaluation.
  • Demonstrates significant cost savings (up to 80%) while maintaining statistical significance.
  • Allows users to define stopping criteria based on practical evaluation needs.
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Robust Bayesian Decision Making under Adversarial Uncertainty
Haripriya Harikumar, Sammie Katt, Yasir Zubayr Barlas, Samuel Kaski
Theory Optimization
  • Focus on decision stability rather than just nominal optimality in experimental design.
  • Introduction of adversarially robust decision-aware experimental design framework.
  • Validation through experiments showing improved stability and reliability of decisions.
  • Emphasis on the influence of hidden or weakly modeled adversarial variables on decision-making.
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Ensemble Diversity Optimization for Subjective Supervision
Xia Cui, Ziyi Huang, N. R. Abeynayake
NLP Optimization Theory
  • EDO optimizes ensemble structure and diversity to handle annotator disagreement in subjective NLP tasks.
  • The framework uses a signed diversity regularizer to control the balance between preserving and suppressing disagreement.
  • EDO significantly improves probabilistic calibration and maintains competitive performance on subjective classification tasks.
  • The method is model-agnostic and can be integrated into various predictive models.
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