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1. Recent Advances in Predictive Modeling with Electronic Health Records

   https://doi.org/10.24963/ijcai.2024/914  

   Wang, Jiaqi; Luo, Junyu; Ye, Muchao; Wang, Xiaochen; Zhong, Yuan; Chang, Aofei; Huang, Guanjie; Yin, Ziyi; Xiao, Cao; Sun, Jimeng; et al (August 2024, International Joint Conferences on Artificial Intelligence Organization)

   The development of electronic health records (EHR) systems has enabled the collection of a vast amount of digitized patient data. However, utilizing EHR data for predictive modeling presents several challenges due to its unique characteristics. With the advancements in machine learning techniques, deep learning has demonstrated its superiority in various applications, including healthcare. This survey systematically reviews recent advances in deep learning-based predictive models using EHR data. Specifically, we introduce the background of EHR data and provide a mathematical definition of the predictive modeling task. We then categorize and summarize predictive deep models from multiple perspectives. Furthermore, we present benchmarks and toolkits relevant to predictive modeling in healthcare. Finally, we conclude this survey by discussing open challenges and suggesting promising directions for future research. 

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2. Times2D: Multi-Period Decomposition and Derivative Mapping for General Time Series Forecasting

   https://doi.org/10.1609/aaai.v39i18.34164  

   Nematirad, Reza; Pahwa, Anil; Natarajan, Balasubramaniam (April 2025, Proceedings of the AAAI Conference on Artificial Intelligence)

   Time series forecasting is an important application in various domains such as energy management, traffic planning, financial markets, meteorology, and medicine. However, real-time series data often present intricate temporal variability and sharp fluctuations, which pose significant challenges for time series forecasting. Previous models that rely on 1D time series representations usually struggle with complex temporal variations. To address the limitations of 1D time series, this study introduces the Times2D method that transforms the 1D time series into 2D space. Times2D consists of three main parts: first, a Periodic Decomposition Block (PDB) that captures temporal variations within a period and between the same periods by converting the time series into a 2D tensor in the frequency domain. Second, the First and Second Derivative Heatmaps (FSDH) capture sharp changes and turning points, respectively. Finally, an Aggregation Forecasting Block (AFB) integrates the output tensors from PDB and FSDH for accurate forecasting. This 2D transformation enables the utilization of 2D convolutional operations to effectively capture long and short characteristics of the time series. Comprehensive experimental results across large-scale data in the literature demonstrate that the proposed Times2D model achieves state-of-the-art performance in both short-term and long-term forecasting. 

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3. Are Time Series Foundation Models Ready to Revolutionize Predictive Building Analytics?

   https://doi.org/10.1145/3671127.3698177  

   Mulayim, Ozan Baris; Quan, Pengrui; Han, Liying; Ouyang, Xiaomin; Hong, Dezhi; Bergés, Mario; Srivastava, Mani (October 2024, ACM)

   Recent advancements in large language models have spurred significant developments in Time Series Foundation Models (TSFMs). These models claim great promise in performing zero-shot forecasting without the need for specific training, leveraging the extensive "corpus" of time-series data they have been trained on. Forecasting is crucial in predictive building analytics, presenting substantial untapped potential for TSFMS in this domain. However, time-series data are often domain-specific and governed by diverse factors such as deployment environments, sensor characteristics, sampling rate, and data resolution, which complicates generalizability of these models across different contexts. Thus, while language models benefit from the relative uniformity of text data, TSFMs face challenges in learning from heterogeneous and contextually varied time-series data to ensure accurate and reliable performance in various applications. This paper seeks to understand how recently developed TSFMs perform in the building domain, particularly concerning their generalizability. We benchmark these models on three large datasets related to indoor air temperature and electricity usage. Our results indicate that TSFMs exhibit marginally better performance compared to statistical models on unseen sensing modality and/or patterns. Based on the benchmark results, we also provide insights for improving future TSFMs on building analytics. 

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4. Energy Demand Forecasting Using Temporal Variational Residual Network

   https://doi.org/10.3390/forecast7030042  

   Ashebir, Simachew; Kim, Seongtae (September 2025, Forecasting)

   The growing demand for efficient energy management has become essential for achieving sustainable development across social, economic, and environmental sectors. Accurate energy demand forecasting plays a pivotal role in energy management. However, energy demand data present unique challenges due to their complex characteristics, such as multi-seasonality, hidden structures, long-range dependency, irregularities, volatilities, and nonlinear patterns, making energy demand forecasting challenging. We propose a hybrid dimension reduction deep learning algorithm, Temporal Variational Residual Network (TVRN), to address these challenges and enhance forecasting performance. This model integrates variational autoencoders (VAEs), Residual Neural Networks (ResNets), and Bidirectional Long Short-Term Memory (BiLSTM) networks. TVRN employs VAEs for dimensionality reduction and noise filtering, ResNets to capture local, mid-level, and global features while tackling gradient vanishing issues in deeper networks, and BiLSTM to leverage past and future contexts for dynamic and accurate predictions. The performance of the proposed model is evaluated using energy consumption data, showing a significant improvement over traditional deep learning and hybrid models. For hourly forecasting, TVRN reduces root mean square error and mean absolute error, ranging from 19% to 86% compared to other models. Similarly, for daily energy consumption forecasting, this method outperforms existing models with an improvement in root mean square error and mean absolute error ranging from 30% to 95%. The proposed model significantly enhances the accuracy of energy demand forecasting by effectively addressing the complexities of multi-seasonality, hidden structures, and nonlinearity. 

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5. Data-Driven Time Series Forecasting for Social Studies Using Spatio-Temporal Graph Neural Networks

   https://doi.org/10.1145/3462203.3475929  

   Li, Yi-Fan; Dong, Bo; Khan, Latifur; Thuraisingham, Bhavani; Brandt, Patrick T.; D'Orazio, Vito J. (September 2021, GoodIT '21: Proceedings of the Conference on Information Technology for Social Good)

   Time series forecasting with additional spatial information has attracted a tremendous amount of attention in recent research, due to its importance in various real-world applications on social studies, such as conflict prediction and pandemic forecasting. Conventional machine learning methods either consider temporal dependencies only, or treat spatial and temporal relations as two separate autoregressive models, namely, space-time autoregressive models. Such methods suffer when it comes to long-term forecasting or predictions for large-scale areas, due to the high nonlinearity and complexity of spatio-temporal data. In this paper, we propose to address these challenges using spatio-temporal graph neural networks. Empirical results on Violence Early Warning System (ViEWS) dataset and U.S. Covid-19 dataset indicate that our method significantly improved performance over the baseline approaches. 

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