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Main Authors: Amnuaypongsa, Worachit, Suparanonrat, Yotsapat, Wanitchollakit, Pana, Songsiri, Jitkomut
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.18492
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author Amnuaypongsa, Worachit
Suparanonrat, Yotsapat
Wanitchollakit, Pana
Songsiri, Jitkomut
author_facet Amnuaypongsa, Worachit
Suparanonrat, Yotsapat
Wanitchollakit, Pana
Songsiri, Jitkomut
contents This paper proposes a multi-step probabilistic forecasting framework using a single neural-network based model to generate simultaneous point and interval forecasts. Our approach ensures non-crossing prediction intervals (PIs) through a model structure design that strictly satisfy a target coverage probability (PICP) while maximizing sharpness. Unlike existing methods that rely on manual weight tuning for scalarized loss functions, we treat point and PI forecasting as a multi-objective optimization problem, utilizing multi-gradient descent to adaptively select optimal weights. Key innovations include a new PI loss function based on an extended log-barrier with an adaptive hyperparameter to guarantee the coverage, a hybrid architecture featuring a shared temporal model with horizon-specific submodels, and a training strategy. The proposed loss is scale-independent and universally applicable; combined with our training algorithm, the framework eliminates trial-and-error hyperparameter tuning for balancing multiple objectives. Validated by an intra-day solar irradiance forecasting application, results demonstrate that our proposed loss consistently outperforms those in current literature by achieving target coverage with the narrowest PI widths. Furthermore, when compared against LSTM encoder-decoder and Transformer architectures--including those augmented with Chronos foundation models--our method remains highly competitive and can be seamlessly adapted to any deep learning structure.
format Preprint
id arxiv_https___arxiv_org_abs_2604_18492
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Barrier-enforced multi-objective optimization for direct point and sharp interval forecasting
Amnuaypongsa, Worachit
Suparanonrat, Yotsapat
Wanitchollakit, Pana
Songsiri, Jitkomut
Machine Learning
Systems and Control
This paper proposes a multi-step probabilistic forecasting framework using a single neural-network based model to generate simultaneous point and interval forecasts. Our approach ensures non-crossing prediction intervals (PIs) through a model structure design that strictly satisfy a target coverage probability (PICP) while maximizing sharpness. Unlike existing methods that rely on manual weight tuning for scalarized loss functions, we treat point and PI forecasting as a multi-objective optimization problem, utilizing multi-gradient descent to adaptively select optimal weights. Key innovations include a new PI loss function based on an extended log-barrier with an adaptive hyperparameter to guarantee the coverage, a hybrid architecture featuring a shared temporal model with horizon-specific submodels, and a training strategy. The proposed loss is scale-independent and universally applicable; combined with our training algorithm, the framework eliminates trial-and-error hyperparameter tuning for balancing multiple objectives. Validated by an intra-day solar irradiance forecasting application, results demonstrate that our proposed loss consistently outperforms those in current literature by achieving target coverage with the narrowest PI widths. Furthermore, when compared against LSTM encoder-decoder and Transformer architectures--including those augmented with Chronos foundation models--our method remains highly competitive and can be seamlessly adapted to any deep learning structure.
title Barrier-enforced multi-objective optimization for direct point and sharp interval forecasting
topic Machine Learning
Systems and Control
url https://arxiv.org/abs/2604.18492