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
UP: Unbounded Positive Asymmetric Optimization for Breaking the Exploration-Stability Dilemma
Chongyu Fan, Pengfei Liu, Jingjia Huang, Sijia Liu, Yi Lin
Reinforcement Learning Large Language Models Optimization
  • Introduces Unbounded Positive Asymmetric Optimization (UP) to resolve the exploration-stability dilemma in RL.
  • Formalizes Probability Capacity (Cap) to highlight limitations of existing importance sampling methods.
  • Demonstrates that UP allows for unclipped gradients for positive advantages while maintaining stability for negative advantages.
  • Extensive experiments show UP enhances exploration and reasoning accuracy across diverse RL algorithms and architectures.
Read more
Avoiding unsafe sets when training with Langevin Dynamics
Adam M. Oberman
Theory Optimization
  • The paper provides bounds on the probability of a training trajectory entering a failure region during Langevin dynamics.
  • Equilibrium mass of the failure region is exponentially small in the dimension of the parameter space.
  • A burn-in time of order d is necessary for the in-set probability to stabilize to its static value.
  • Local relaxation rates can reduce the burn-in time for geometrically isolated failure regions.
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 effectively addresses selection bias by jointly modeling selection and outcomes.
  • The proposed deep learning implementation of the Heckman model restores predictive coverage in selected-against regions.
  • The stability of the two-step estimator is superior to that of the joint maximum likelihood estimator when using deep feature maps.
Read more
Federated Physics-Grounded Reinforcement Learning for Distributed Stability Control in Smart Grids
Omar Al-Refai, Ibrahim Shahbaz, Adam Ali Husseinat, Eman Hammad
Reinforcement Learning Federated Learning Optimization
  • FedPPO-PG achieves 100% stabilization in all trials conducted.
  • Mean stability time is reduced by 72.4% compared to previous methods.
  • Control power usage is decreased by 7-14 times relative to a centralized baseline.
  • The framework allows for independent execution of each actor without a central coordinator.
Read more
PatchOptic for Shared-State LLM Workflows with Projected Views and Verified Structured Updates
Zhaoyu Bai, Jiaqi Cai
Large Language Models NLP Theory
  • Introduction of PatchOptic, an interface for managing shared-state LLM workflows.
  • Utilization of projected views and verified updates to ensure local actions are globally valid.
  • Development of PatchBench, a benchmark for evaluating the proposed methodology.
  • Demonstrated improvements in output quality and reduction in leakage and token costs.
Read more
Asymmetric Focal Loss Improves Graph Neural Network Prediction of Drug-Drug Interactions
Faranak Hatami, Mousa Moradi
Graph Learning Optimization
  • ClinicalFocal loss significantly improved model accuracy and F1 score compared to binary cross-entropy.
  • The approach achieved a recall of 90.9% and reduced the false-negative rate from 29.8% to 9.1%.
  • Emphasizing difficult positive interactions enhances DDI prediction capabilities.
  • The methodology allows for safety-oriented DDI screening without altering the model architecture.
Read more
SafeImpute: Reliable Clinical Data Imputation via Conformal Selection
Xinrui He, Mengting Ai, Junting Wang, Curtiss B. Cook, Jingrui He
Graph Learning Time Series Health informatics
  • SafeImpute addresses the problem of reliable clinical data imputation with statistical error control.
  • The framework utilizes an event graph to model irregular clinical visits and employs a two-relation GNN for imputation.
  • Conformal selection is used to ensure that only reliable imputations are released, controlling the false discovery rate.
  • Extensive experiments show that SafeImpute outperforms existing methods in terms of accuracy and reliability.
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
Optimization Theory Efficient ML
  • Introduction of Lorentz Encoding (LE) as a physics-informed framework for CEST MRI reconstruction.
  • Decoupled hybrid architecture combining Hash Encoding for spatial features and LE for spectral features.
  • Significant performance improvement over traditional methods, achieving high PSNR and SSIM with minimal sampling.
  • Demonstrated effectiveness in accurate metabolite mapping (APT, NOE, MT) from sparse data.
Read more
On Explicit Super-Expressive Approximation for Neural Networks
Feng-Lei Fan, Ze-Yu Li, Chen-Yu Wang, Jian-Jun Wang
Theory
  • Introduces the Chinese Remainder Theorem as a mechanism for explicit parameter bounds in neural network approximations.
  • Constructs fixed-architecture networks for Lipschitz and H"older-smooth functions with explicit parameter-error trade-offs.
  • Demonstrates that higher smoothness of target functions reduces the required parameter magnitude, improving scaling laws.
  • Provides the first explicit relation between approximation accuracy and parameter magnitude in super-expressive approximation.
Read more
More Convincing, Not More Correct: Self-Play Reward Hacking of Reference-Free LLM Judges
Chenyu Zhou
NLP Large Language Models Reinforcement Learning
  • Self-play training leads to a significant divergence between judge pass rates and actual accuracy, termed the judge-truth gap.
  • Reference-free judges score plausibility, not correctness, allowing models to exploit false-positive basins.
  • A hidden-anchor audit effectively quantifies the over-reporting of correctness by judges under optimization.
  • The de-anchoring method significantly reduces false-positive rates and prevents the exploitation of plausible but incorrect answers.
Read more
LLM-Driven Neural Network Generation with Same-Family Architecture Guidance: Disentangling Transfer and Adaptation
Kabir Dev Paul Baghel, Radu Timofte, Dmitry Ignatov
Large Language Models Optimization Computer Vision
  • Introduces a source-guided candidate-generation protocol for neural network modifications.
  • Demonstrates improved model accuracy using stronger same-family source models.
  • Separates the effects of recipe transfer and adaptation in neural network generation.
  • Reports significant performance improvements on CIFAR-10 and SVHN datasets.
Read more
EntroPath: Maximum Entropy Path Ensemble Embedding for Manifold Learning
Przemysล‚aw Rola
Graph Learning Theory Efficient ML
  • EntroPath leverages maximum entropy random walks to improve manifold learning by aggregating multiple paths rather than relying on single trajectories.
  • The method provides a free-energy dissimilarity measure that converges to squared geodesic distances, enhancing robustness against graph errors.
  • Scalable extensions for out-of-sample embedding and trajectory inference are introduced, broadening the method's usability.
  • Empirical results indicate that EntroPath outperforms traditional methods like PHATE, HeatGeo, and Isomap, especially in complex manifold structures.
Read more
Strategic Bargaining in Multi-Buyer Markets: Reinforcement Learning from Verifiable Rewards for LLM Negotiations
Shuze Daniel Liu, Claire Chen, Jiabao Sean Xiao, Xin Chen, David Simchi-Levi
Reinforcement Learning Large Language Models Optimization
  • Identifies limitations of standard LLMs in economic decision-making during negotiations.
  • Proposes a reinforcement learning framework that aligns rewards with economic outcomes.
  • Demonstrates improved negotiation strategies through price anchoring and strategic probing.
  • Shows that the trained agent can generalize to unseen buyer behaviors and budget distributions.
Read more
AdaStop: Cost-Aware Early Stopping for DNN Test Selection
Bonan Shen, Wei-Jung Huang, Xin Liu, Jiazhou Gao, Tao Ning
Efficient ML Optimization Theory
  • AdaStop provides a principled stopping criterion for DNN test selection based on cost-benefit analysis.
  • The framework estimates the marginal fault discovery rate and stops labeling when it falls below a calculated threshold.
  • Empirical evaluations show substantial savings in labeling costs while maintaining high fault discovery rates.
  • The approach adapts to varying labeling costs and fault values, making it versatile for different testing scenarios.
Read more
Agon: Competitive Cross-Model RL with Implicit Rival Grading of Reasoning
Vladislav Beliaev
Reinforcement Learning Large Language Models NLP
  • Agon reframes reasoning quality as an implicit reward from a competing model, addressing the lack of labels for good reasoning.
  • The method involves two distinct models trained in a competitive manner, enhancing their reasoning capabilities.
  • Agon achieves significant performance improvements on hard reasoning tasks compared to traditional RL methods.
  • The approach is efficient, using a shared base with low memory overhead while maintaining model divergence.
Read more
Latency-Constrained DNN Architecture Learning for Edge Systems using Zerorized Batch Normalization
Shuo Huai, Di Liu, Hao Kong, Weichen Liu, Ravi Subramaniam, Christian Makaya, Qian Lin
Optimization Efficient ML
  • Introduces a latency-oriented DNN optimization method for edge systems.
  • Utilizes a universal hardware-customized latency predictor for efficient model training.
  • Achieves significant latency reduction while maintaining high accuracy in DNNs.
  • Demonstrates the effectiveness of the method on popular models like GoogLeNet and VGG-19.
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
  • Introduces Self-Review Reinforcement Learning (SRRL) framework for LLMs.
  • Incorporates a self-review mechanism to analyze and improve responses.
  • Utilizes policy gradients for optimizing self-reviews and internalizing improvements.
  • Employs cross-episode memory to enhance learning efficiency by reusing successful reviews.
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 outperforms traditional optimizers like SGD and Adam.
  • Theoretical analysis confirms EISAM's ability to steer parameters toward flatter minima.
Read more
Gauge-Invariant Learnable Spectral Positional Encodings for Directed Graphs via Hermitian Block Krylov Subspaces
Jiaqing Xie, Yuxin Wang
Graph Learning
  • Introduces gauge-invariant learnable spectral positional encodings for directed graphs.
  • Utilizes Hermitian block Krylov subspaces for efficient computation of PEs.
  • Proves that a logarithmic number of block steps suffices for approximation across structured response families.
  • Demonstrates improved performance of magnetic Krylov PEs over traditional direction-blind PEs in empirical tests.
Read more
Hybrid Least Squares/Gradient Descent Methods for MIONets
Jun Choi, Chang-Ock Lee, Minam Moon
Optimization Efficient ML Theory
  • Introduction of a hybrid LSGD method for MIONets to enhance training efficiency.
  • Utilization of Kronecker and Khatri-Rao products to simplify large system matrices.
  • Development of the ALS+Adam algorithm for practical implementation.
  • Demonstration of improved training performance compared to conventional methods.
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 the variance scaling problem in high-dimensional systems by focusing on input-dependent components.
  • Demonstrates that the effective perturbation dimension can be reduced, improving scalability.
  • Maintains the advantages of scalar global feedback while enhancing learning efficiency.
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.
  • Develops the UCB-DPP policy for learning and decision-making in the context of uncertain task handling effectiveness.
  • Proves theoretical guarantees on regret and stability for the proposed policy.
  • Demonstrates superior performance of UCB-DPP over baseline policies through simulations.
Read more
Gradient-free Riemannian Langevin Sampler
Ricardo Baptista, Olivier Zahm
Theory Efficient ML Multimodal
  • GRiLS is a gradient-free MCMC method that improves sampling efficiency for multimodal distributions.
  • The method utilizes a Riemannian metric to enhance transitions between modes, addressing issues of poor mixing.
  • Mean and covariance of the target density are estimated using an ensemble of interacting particles.
  • Empirical results indicate that GRiLS achieves better mixing compared to traditional MCMC methods.
Read more
Collaborative Synthetic Data Generation for Knowledge Transfer in Federated Learning
Maximilian Andreas Hoefler, Karsten Mueller, Wojciech Samek
Federated Learning
  • Introduces FedKT-CSD, a framework for one-shot federated learning with formal privacy guarantees.
  • Utilizes pretrained autoencoders to create a shared latent space for efficient data encoding.
  • Achieves competitive performance compared to existing methods while ensuring differential privacy.
  • Reduces communication overhead by requiring only a single round of data transmission.
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 for how long.
  • Modeling of stochastic order arrivals and queuing dynamics to minimize operational time and inefficiencies.
  • Demonstrated improvements in order-completion rates and reduced recharging times compared to traditional methods.
Read more
Converge to Surprise: Evolutionary Self-supervised Image Clustering
Canlin Zhang, Xiuwen Liu
Computer Vision Optimization Theory
  • Introduction of a surprise score that measures the non-randomness of model outputs under the maximum entropy hypothesis.
  • Development of the 'converge-to-surprise' optimization scheme combining evolution strategy and gradient descent.
  • Achievement of new state-of-the-art results in non-parametric self-supervised image clustering on benchmark datasets.
  • Demonstration that the surprise score cannot generally be reduced to a per-step loss function, highlighting a fundamental limitation of traditional methods.
Read more
Nonlinear Bandit
Tianshuo Zheng, Ting Wu, Zhi-Hua Zhou, Keqin Liu
Theory Optimization
  • Introduction of the EHM algorithm for heavy-tailed GLB problems with optimal regret and low computational complexity.
  • Extension of the algorithm to piecewise constant contexts with the PGLB-EHM variant, maintaining similar regret bounds.
  • Development of the NB-EHM algorithm for nonlinear bandit problems, achieving sublinear regret without restrictive assumptions.
  • Demonstration of the robustness of the proposed algorithms under heavy-tailed distributions.
Read more
Gimitest: A Comprehensive Tool for Testing Reinforcement Learning Policies
Dennis Gross, Quentin Mazouni, Helge Spieker, Arnaud Gotlieb
Reinforcement Learning
  • Gimitest provides a comprehensive framework for testing RL policies in various environments.
  • The tool supports both single-agent and multi-agent reinforcement learning scenarios.
  • Gimitest integrates with existing gym frameworks, allowing for customizable testing setups.
  • The effectiveness of Gimitest is demonstrated through practical applications in popular RL environments.
Read more
K-ABENA: K-Adaptive Backpropagation with Error-based N-exclusion Algorithm : (Compensated Loss-Based Sample Exclusion with Unbiased Gradient Estimation)
Jean-Francois Bonbhel
Optimization Efficient ML Theory
  • K-ABENA reduces training costs by excluding low-loss samples from the backward pass.
  • The method provides a design-unbiased gradient estimator using Horvitz-Thompson reweighting.
  • A convergence guarantee for SGD is established, showing O(1/โˆšT) decay of the expected squared gradient norm.
  • Empirical results indicate K-ABENA achieves 28-54% savings in computation while maintaining high accuracy.
Read more
Modeling Normal Is All You Need: Joint Latent Clustering for Anomaly Detection in Multimodal Cyber-Physical Systems
Alexander Apartsin, Yehudit Aperstein
Multimodal Time Series
  • Introduces the MIIM framework to characterize the structure of normal behavior in CPS.
  • Develops a detector that combines latent representation learning with Gaussian-mixture clustering.
  • Evaluates the method using a fair protocol that avoids common pitfalls in anomaly detection metrics.
  • Achieves state-of-the-art results on multiple CPS datasets, particularly in challenging scenarios.
Read more
The Optimal Sample Complexity of Learning Autoregressive Chain-of-Thought
Zhiyuan Li
Theory
  • Establishes the sample complexity bounds for learning autoregressive Chain-of-Thought traces.
  • Introduces parity dimension as a refined measure for controlling sample complexity.
  • Demonstrates that learning full autoregressive CoT traces is statistically as easy as learning local next-token rules.
  • Provides a worst-case optimal dependence on the DS dimension for sample complexity.
Read more
Hypergraph Neural Stochastic Diffusion: An SDE Framework for Uncertainty Estimation
Zhiheng Zhou, Mengyao Zhou, Dengyi Zhao, Xingqin Qi, Guiying Yan
Graph Learning Theory
  • Introduces Hypergraph Neural Stochastic Diffusion (HyperNSD) for uncertainty estimation in hypergraphs.
  • Models hypergraph representations as stochastic processes to capture uncertainty evolution.
  • Employs a learnable drift function and stochastic forcing function for effective uncertainty quantification.
  • Demonstrates theoretical stability and convergence of the proposed framework.
Read more
FourierQK: Spectral Preprocessing of Query-Key Projections Improves Transformer Attention
Athanasios Zeris
NLP Large Language Models
  • FFT-based spectral preprocessing of query-key projections improves transformer attention performance.
  • Significant reduction in validation loss observed, with multi-frequency spectral attention achieving a 79% reduction.
  • Improvements are specific to spectral preprocessing; other methods do not yield measurable gains.
  • The approach preserves the standard attention mechanism while enhancing it through frequency-domain filters.
Read more
The Key to Going Linear: Analysis-Driven Transformer Linearization
Anna Kuzina, Paul N. Whatmough, Babak Ehteshami Bejnordi
NLP Large Language Models Efficient ML
  • Isolated analysis of linearization mechanisms in a frozen-backbone setting.
  • Delta-based mechanisms outperform gated updates by capturing key-dependent dynamics.
  • Introduction of practical design choices that reduce performance gaps in linear attention.
  • Demonstrated effectiveness across models with up to 32B parameters.
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 Generative Models
  • Linear attention in graph denoising is suboptimal due to its averaging nature across spectral properties.
  • Spectral Attention improves upon linear attention by leveraging the input graph spectrum.
  • Graph Convolutional Attention (GCA) is introduced as a permutation-equivariant mechanism that implements spectral denoising effectively.
  • The softmax operation enhances denoising by projecting noisy eigenvectors onto the clean eigenspace.
Read more
STST-JEPA: Shallow-Target Spatio-Temporal Joint Embedding Prediction Architecture For EEG Self-Supervised Learning
Roy Segal, Yoni Svechinsky, Tomer Fekete
Time Series
  • Introduction of STST-JEPA, a self-supervised transformer for EEG data.
  • Pretrained on a large dataset, addressing EEG's unique challenges.
  • Achieves a mean absolute error of 3.06 years in age regression.
  • Demonstrates high performance in auxiliary tasks like sex classification.
Read more
Entropy-Guided Tensor Compression for Multimodal Federated Learning on Edge Devices
Quoc Bao Phan, Tuy Tan Nguyen
Federated Learning Multimodal Efficient ML
  • MESH-FL adapts compression strategies based on spectral entropy, improving efficiency in multimodal federated learning.
  • The framework allows for dynamic rank allocation across layers, modalities, and devices, optimizing communication costs.
  • Experimental results indicate substantial improvements in accuracy and communication efficiency compared to traditional methods.
Read more
Intuitionistic Fuzzy Graph Embedded Random Vector Functional Link with Multiview Learning
Vrushank Ahire, Yogesh Kumar, M.A. Ganaie
Graph Learning Theory Multimodal
  • Introduction of intuitionistic fuzzy sets into the RVFL framework for better uncertainty handling.
  • Incorporation of graph embedding to preserve geometric relationships and enhance generalization.
  • Utilization of multiview learning to combine information from multiple feature sets.
  • Statistical analyses confirm significant improvements in classification performance over existing models.
Read more
Two Sides of the Same Coin: Learning the Backdoor to Remove the Backdoor
Qi Zhao, Christian Wressnegger
Computer Vision
  • HARVEY leverages the RCE loss for better dataset splitting, enhancing the identification of poisonous samples.
  • The method introduces a paradigm shift by using a backdoored reference model to differentiate between poisonous and benign samples.
  • HARVEY consistently suppresses backdoor attacks while preserving natural accuracy across multiple datasets and architectures.
  • The approach demonstrates a significant improvement over existing training-time defenses against backdoor attacks.
Read more
Intrinsic-Noise Consolidation: A Doob-Barrier-Conditioned Diffusion Turns Analog Device Noise into a Continual-Learning Resource
Gunner Levi Howe
Theory Efficient ML Optimization
  • Introduces a novel Doob h-transform-based synaptic rule for memory consolidation.
  • Demonstrates that intrinsic noise can enhance memory retention in analog devices.
  • Finds a non-monotonic relationship between noise levels and retention performance.
  • Achieves significant improvements over traditional methods in empirical tests.
Read more
UASPL: Uncertainty-Aware Self-Paced Learning with Evidential Neural Networks
Yifan Zhang, Yuxin Hu, Zhuobin Hao, Xiaozhuan Gao, Lipeng Pan
Theory Interpretability Efficient ML
  • UASPL is the first SPL method to integrate model-generated evidential uncertainty with label-fitting loss.
  • The sample selection process in UASPL is interpretable and aligns with the self-paced learning principle.
  • UASPL can be adapted to various SPL variants, demonstrating its generality.
  • Experimental results show significant improvements in classification performance over traditional SPL methods.
Read more
Fingerprint, Not Blueprint: How Positional Schemes Set the Default Spectral Algebra of Attention
Li Hengyu
NLP Large Language Models Theory
  • Introduces a matched-null spectral framework for analyzing the QK operator in attention heads.
  • Demonstrates that positional encoding schemes significantly influence the spectral properties of attention heads.
  • Finds that the strongest previous-token heads are spectrally rotational under RoPE, contrasting with other schemes.
  • Establishes that the positional scheme acts as a 'fingerprint' that shapes the attention mechanism's behavior.
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 comprehensive knowledge graph for metabolic engineering.
  • The model employs domain-specific foundation models for multi-modal feature encoding.
  • Self-supervised pretraining enhances the predictive capabilities of the Heterogeneous Graph Transformer.
  • CANOPY outperforms traditional tabular methods and homogeneous GNNs in fermentation titer prediction.
Read more
When Do Geometric Algebra Layers Beat Scalarization? A Controlled Study on SO(3)-Equivariant Vector Laws
Fabien Polly
Robotics Theory Efficient ML
  • Geometric algebra networks do not outperform scalarization for single-stage laws.
  • For compositional laws, geometric algebra networks significantly outperform scalarization in low-data scenarios.
  • No tested model effectively extrapolates invariant magnitudes, indicating a limitation in current approaches.
  • The study provides a controlled benchmark to assess the contributions of geometric algebra in equivariant learning.
Read more
TriRoute: Unified Learned Routing for Joint Adaptive Attention, Experts, and KV-Cache Allocation
Andrii Balashov, Olena Ponomarova
NLP Large Language Models Efficient ML
  • TriRoute integrates attention resolution, expert selection, and KV-cache allocation into a single learned controller.
  • The architecture is trained end-to-end, allowing for dynamic adjustments based on token characteristics.
  • TriRoute outperforms traditional methods in terms of efficiency and robustness, particularly for rare and complex tokens.
  • The approach mitigates routing collapse through a coupling-aware balancing loss and a unified budget constraint.
Read more
Empirical Minimal-Realisation Compression of Deep Neural Networks via Controllability-Observability Tests
Anis Hamadouche, Amir Hussain
Efficient ML
  • Introduces a control-theoretic perspective for DNN compression focusing on hidden-state dynamics.
  • Develops empirical tests for reachability and observability to assess hidden-state redundancy.
  • Proposes realised C-balanced compression that directly reduces layer widths based on empirical ranks.
  • Demonstrates substantial state and parameter compression on benchmark datasets with minimal accuracy loss.
Read more
Breaking Structural Isolation: Scalable Graph Clustering via Community-Aware Sampling and Structural Entropy
Jingyun Zhang, Hao Peng, Jianxin Li, Angsheng Li, Philip S. Yu
Graph Learning
  • SCISE effectively mitigates the structural isolation problem in graph clustering.
  • The SECC operator enhances community cohesion by optimizing structural information.
  • CSampE improves sampling by incorporating global community context into mini-batches.
  • StructCL refines edge weights to guide the learning of discriminative representations.
Read more
Design-CP: Context Parallelism for Design of Protein Nanoparticles
Lorenzo Tarricone, Helen E. Eisenach, Aiko Muraishi, Charlotte M. Deane
Generative Models
  • Introduction of Design-CP, a context-parallel inference method for RFD3.
  • Demonstration of improved scalability for designing large symmetric protein assemblies.
  • Successful application of symmetry constraints to enhance sample quality.
  • Feasibility of octahedral nanoparticle design on modest multi-GPU setups.
Read more