toplogo
Log på
indsigt - Operations Research - # Neural Network Ensembles Efficiency

Reliable Uncertainty with Cheaper Neural Network Ensembles: A Case Study in Industrial Parts Classification


Kernekoncepter
Efficient neural network ensembles, such as batch ensemble, offer cost-effective and competitive alternatives to deep ensembles for industrial parts classification.
Resumé

In the field of Operations Research, predictive models often face out-of-distribution scenarios where data distribution differs from training data. Neural networks (NNs) excel in image classification but struggle with overconfident predictions on OOD data. Reliable uncertainty quantification is crucial for NN deployment. Deep ensembles, composed of multiple NNs, provide strong accuracy and uncertainty estimation but are computationally demanding. Efficient NN ensembles like snapshot, batch, and MIMO have emerged as promising alternatives. A case study on industrial parts classification highlights the batch ensemble's cost-effectiveness and competitive performance compared to deep ensembles.

edit_icon

Tilpas resumé

edit_icon

Genskriv med AI

edit_icon

Generer citater

translate_icon

Oversæt kilde

visual_icon

Generer mindmap

visit_icon

Besøg kilde

Statistik
Deep ensemble training time speedup of 7x Batch ensemble test time speedup of 8x Batch ensemble memory savings of 9x
Citater
"Deep ensembles offer robust predictive performance and uncertainty estimates but pose challenges due to computational demands." "Batch ensemble emerges as a cost-effective alternative to deep ensembles with superior performance in both accuracy and uncertainty."

Vigtigste indsigter udtrukket fra

by Arthur Thuy,... kl. arxiv.org 03-18-2024

https://arxiv.org/pdf/2403.10182.pdf
Reliable uncertainty with cheaper neural network ensembles

Dybere Forespørgsler

How can efficient neural network ensembles be applied in other operational research domains beyond industrial parts classification

Efficient neural network ensembles, such as batch ensembles, can be applied in various operational research domains beyond industrial parts classification. For example: Healthcare: In healthcare operations, these ensembles can be utilized for patient diagnosis and treatment prediction. By combining the outputs of multiple models trained on different subsets of data or with different architectures, more accurate predictions can be made regarding patient outcomes. Supply Chain Management: Efficient ensembles can help optimize inventory management by predicting demand fluctuations and identifying potential disruptions in the supply chain. This can lead to better decision-making in terms of procurement, production planning, and distribution strategies. Financial Services: In financial operations research, these ensembles can enhance risk assessment models for investment portfolios or loan approvals. By leveraging diverse models within an ensemble, more robust risk evaluations can be conducted to mitigate financial losses.

What potential drawbacks or limitations might arise from relying solely on batch ensembles for predictive maintenance tasks

While batch ensembles offer significant advantages in terms of computational efficiency and reliable uncertainty estimation compared to deep ensembles, there are potential drawbacks when relying solely on them for predictive maintenance tasks: Limited Diversity: Batch ensembles may struggle to capture a wide range of perspectives due to their shared weight structure. This limitation could result in reduced model performance when faced with complex or novel scenarios that require diverse viewpoints for accurate predictions. Overfitting Concerns: Depending on the dataset and training process, batch ensembles might still face overfitting issues if not properly regularized or diversified during training. Overfitting could lead to inaccurate predictions and unreliable uncertainty estimates. Scalability Challenges: As the complexity of predictive maintenance tasks increases or new types of equipment are introduced into the system, scaling up batch ensemble models may become challenging without sacrificing computational efficiency.

How can the concept of diversity quality in neural network ensembles be translated into improving decision-making processes outside the realm of operations research

The concept of diversity quality in neural network ensembles can be translated into improving decision-making processes outside the realm of operations research by: Risk Management: In finance or insurance sectors, utilizing ensemble methods with high diversity quality can provide more robust risk assessments by considering a broader range of possible outcomes. This approach enhances decision-making under uncertain conditions where traditional models may fall short. Medical Diagnosis: When making critical medical decisions based on diagnostic tests or imaging data, incorporating diverse opinions from ensemble members with high diversity quality ensures a comprehensive evaluation leading to more accurate diagnoses and treatment plans. Disaster Response Planning: Ensembling techniques focusing on diversity quality could improve disaster response planning by offering varied perspectives on potential scenarios. Decision-makers would benefit from a range of forecasts generated by diverse models within an ensemble when preparing contingency plans for natural disasters or emergencies.
0
star