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In Proceedings of 28th International Workshop on Intelligent Computing in Engineering, EG-ICE 2021, 2021
Imagine building performance prediction as a dynamic Lego set, where each block represents a distinct component of the design. Just as Lego pieces can be assembled in countless ways to create varied structures, our component-based machine learning (CBML) approach offers a modular and scalable solution for predicting time-series energy performance in building designs. Dive into our manuscript to uncover how we’ve redefined building performance simulation with CBML, ensuring accurate hourly energy predictions that pave the way for optimized equipment sizing, efficient energy demand control, and balanced network loads.
Chen, X., Singh, M.M. & Geyer, P. (2021). Component-based machine learning for predicting representative time-series of energy performance in building design. In 28th International Workshop on Intelligent Computing in Engineering, EG-ICE 2021. Berlin, Germany.
In Proceedings of 28th International Workshop on Intelligent Computing in Engineering, EG-ICE 2021, special issue, 2021
Introducing a cutting-edge approach to bridging the persistent energy performance gap in the building industry: By synergistically merging domain knowledge from building simulations with the prowess of machine learning, our hybrid-model forecasting framework not only delivers enhanced prediction accuracy but also provides a deeper understanding of the underlying reasons for discrepancies in building energy consumption. Drawing on real-world data from an office building in Shanghai, this manuscript showcases how the integration of first-principles with data-driven methods can pioneer a new path to minimizing energy disparities.
Chen, X., Guo, T., & Geyer, P. (2021). A hybrid-model forecasting framework for reducing the building energy performance gap. In 28th International Workshop on Intelligent Computing in Engineering, EG-ICE 2021. Berlin, Germany, 2021, special issue on Advanced Engineering Informatics.
暖通空调; Heating Ventilating & Air Conditioning, 2022
A thorough overview of carbon neutrality in the EU regarding policy framework, technology support, economics foundation, and recycling strategy.
陈夏,张怡卓,蔡晓烨.欧盟-德国建筑碳中和前沿[J].暖通空调,2022,52(3):25-38. Chen X., Zhang Y., & Cai X. (2022). Frontiers of carbon neutrality in EU-German building sector, Heating Ventilating & Air Conditioning, TU-023; X322.
Applied Energy, 2022
Drawing inspiration from the human nervous system’s estimation process, we present a key framework designed to revolutionize how we approach complex decision-making challenges across various domains. This framework seamlessly integrates uncertainty quantification, cutting-edge machine learning techniques, and first-principles models, fostering a dynamic and ongoing interaction with users. We elaborated this framework into the building design scenario. More than just a decision aid, it lays the foundational principles for integrating domain knowledge with machine learning and propelling the frontier of intelligence augmentation. It’s not just about making informed decisions, but about enhancing our capability to interact with, interpret, and innovate from the vast data-driven landscapes of the modern world.
Chen, X., & Geyer, P. (2022). Machine assistance in energy-efficient building design: A predictive framework toward dynamic interaction with human decision-making under uncertainty. Applied Energy, 307, 118240.
Online Demo
In Proceedings of Passive and Low Energy Architecture, PLEA 2022, 2022
Leveraging the confluence of simulation, first-principles models, and machine learning, we introduce a pioneering approach that marries the strengths of feedforward and feedback loops. Think of it as a reinforcement learning paradigm: we construct a dynamic environment, allowing the model to adapt and perform optimally. This synergy crafts a dynamic and highly efficient building system control strategy, all conceptualized within a ‘gray-box’ framework. By embedding dynamic prior knowledge of building system characteristics, we not only enhance the model’s behavior but also tap into previously unexplored energy-saving potentials, paving the way for the future of optimized built environments.
Chen X., Cai X., Kümpel A., Müller D., & Geyer P., (2022). Dynamic Feedforward Strategy Development for Building Heating System based on AI Forecasting and Simulation. In Passive and Low Energy Architecture, PLEA 2022, Santiago de Chile, Chile.
Advanced Engineering Informatics, 2022
An intuitive way to combine knowledge-based simulation for data enrichment while introducing extra information to machine learning models. This hybrid-model framework ensures that both domain knowledge and data are well utilized, reducing the effort in detail modeling, and minimizing the performance gap in prediction.
Chen, X., Guo, T., Kriegel, M., & Geyer, P. (2022). A hybrid-model forecasting framework for reducing the building energy performance gap. Advanced Engineering Informatics, 52, 101627.
In Proceedings of 29th International Workshop on Intelligent Computing in Engineering, EG-ICE 2022, special issue, 2022
This research implements a practice of the integration between a data-driven model and knowledge-based methods within the same context in the early phases of building design. The objective is to enhance decision-making to achieve augmented intelligence, ensuring both energy efficiency and minimal environmental impact in the given scenario.
Chen X., Saluz U., Staudt J., Margesin M., Lang W., & Geyer P. (2022). Integrated data-driven and knowledge-based performance evaluation for machine assistance in building design decision support, In the 29th International Workshop on Intelligent Computing in Engineering, EG-ICE 2022. Aarhus, Denmark.
Energy and Buildings, 2022
In the design and decision-making process, distinguishing between correlation and causation is not just a philosophical mindset but a crucial methodological consideration. As we transition from intuition-driven decisions to data-driven methodologies, it’s necessary to discover potential patterns directly from the raw data rather than rely heavily on potentially biased or incorrect prior knowledge. This manuscript underscores the significance of enabling machine learning models to conduct causal reasoning, ensuring that answers to “What-if” questions are unbiased.
Chen, X., Abualdenien, J., Singh, M. M., Borrmann, A., & Geyer, P. (2022). Introducing causal inference in the energy-efficient building design process. Energy and Buildings, 277, 112583.
In Proceedings of 30th International Workshop on Intelligent Computing in Engineering, EG-ICE 2023, 2023
This manuscript introduces a recommendation system as an application extension practice for machine assistance in the sustainable building design domain. By involving multi-objective optimization processes, this system aims to be the bridge between intricate evaluations and tangible, sustainable outcomes in building engineering for achieving holistic sustainability objectives.
Chen, X., & Geyer, P. (2023). Sustainability recommendation system for building design alternatives under multi-objective scenarios, accepted by 30th International Workshop on Intelligent Computing in Engineering, EG-ICE 2023, London, UK.
Online Demo
In Proceedings of 18th International IBPSA conference and Exhibition, Building Simulation 2023, 2023
Proposing a paradigm to systematically embed prior knowledge and domain insights into data-driven models, addressing domain-specific challenges through three levels of knowledge integration: modeling knowledge for system description, inductive logic and disentanglement for extrapolation, and abstract reasoning and deductive logic for representation. We demonstrated this paradigm in the context of building engineering.
Chen, X., & Geyer, P. (2023). Pathway toward prior knowledge-integrated machine learning in engineering. arXiv preprint arXiv:2307.06950.
Biomedical Signal Processing and Control, 2023
Are the limits of our language the limits of our world? Just as we use words to share ideas, our brains have their own unique language, spoken through electrical signals. To better understand this language, this research focuses on developing cutting-edge deep learning methods: EEGNeX, a tool for decoding brain signals to explore how a blend of technology and neuroscience might just change the way we communicate.
Chen, X., Teng, X., Chen, H., Pan, Y., & Geyer, P. (2024). Toward reliable signals decoding for electroencephalogram: A benchmark study to EEGNeX. Biomedical Signal Processing and Control, 87, 105475.
Developments in the Built Environment, 2023
This research proposes a symbiosis pattern between human intelligence and machine capabilities with the importance of causal analysis in preventing biases in data-driven models and prior knowledge: the necessity of understanding the underlying connections – the why and how – behind each element to accurately solve the engineering puzzle.
Chen, X., Sun, R., Saluz, U., Schiavon, S. and Geyer, P., 2023. Using causal inference to avoid fallouts in data-driven parametric analysis: A case study in the architecture, engineering, and construction industry. Developments in the Built Environment, p.100296.
Applied Energy, 2024
This paper demonstrates the general applicability of the knowledge-integration machine learning framework. It is showcased through real-world PEMWE case studies, highlighting its potential to drive sustainable energy solutions and pave the way for prior knowledge alignment in specialist AI systems.
Chen, X., Rex, A., Woelke, J., Eckert, C., Bensmann, B., Hanke-Rauschenbach, R., & Geyer, P. (2024). Machine learning in proton exchange membrane water electrolysis — A knowledge-integrated framework. Applied Energy, 371, 123550.
Knowledge-Based Systems, 2024
In the engineering domain, most systems are composed of the same basic components with diverse compositions. By disentangling the compositionality from the system and embedding it into the model organization, we actually can construct a set of finite “Lego-Block” to predict infinite combinations. We proved that Component-based Machine Learning (CBML) turns the extrapolation problem at the system level into the interpolation problem at the component level in a more flexible and less data-reliance manner.
Chen, X., Singh, M.M. and Geyer, P., 2024. Utilizing domain knowledge: robust machine learning for building energy performance prediction with small, inconsistent datasets. Knowledge-Based Systems, p.111774
Advanced Engineering Informatics, 2024
Introducing a groundbreaking intersection of systems engineering and deep learning: our component-based, data-driven model. This unique approach not only adapts to the inherent structure of systems engineering but also prioritizes domain knowledge, ensuring that our models are interpretable and aligned with engineering principles. Dive deep into our innovative methodology that bridges the gap between the vast potential of AI and the meticulous precision of engineering design.
Geyer, P., Singh, M. M., & Chen, X. (2024). Explainable AI for engineering design: A unified approach of systems engineering and component-based deep learning demonstrated by energy-efficient building design. Advanced Engineering Informatics, 62, 102843.
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Master/Bachelor course, Technische Universität Berlin, Digital architecture and sustainability, 2020
The aim of teaching is to prepare future architects and civil engineers for the challenges of digitization and sustainability. The basis of teaching in the department is the teaching of digital methods in construction with all technical and disciplinary aspects. Integrated into digital models, engineering calculations and simulations of key performance aspects such as energy efficiency and life cycle analysis for sustainability are taught. This includes methodological knowledge and application competence in the following fields:
Master course, Leibniz Universität Hannover, Sustainable Building Systems, 2022
Computers changed the way we think, design and build architecture. Computers tools allow architects to explore new aesthetics, simulate the performance of their design, or automate their design tasks in a way never seen before. Artificial Intelligence (AI) is one of the latest development in that field with great potential for real-time design assistance in the architectural practice. It may completely change the way humans (co)operate with machines.