Urban Analytics Lab

National University of Singapore

About us


We are introducing innovative methods, datasets, and software to derive new insights in cities and advance data-driven urban planning, digital twins, and geospatial technologies in establishing and managing the smart cities of tomorrow. Converging multidisciplinary approaches inspired by recent advancements in computer science, geomatics and urban data science, and influenced by crowdsourcing and open science, we conceive cutting-edge techniques for urban sensing and analytics at the city-scale. Watch the video above or read more here.

Established and directed by Filip Biljecki, we are proudly based at the Department of Architecture at the College of Design and Engineering of the National University of Singapore, a leading global university centered in the heart of Southeast Asia. We are also affiliated with the Department of Real Estate at the NUS Business School.

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People

We are an ensemble of scholars from diverse disciplines and countries, driving forward our shared research goal of making cities smarter and more data-driven. Since 2019, we have been fortunate to collaborate with many talented alumni, whose invaluable contributions have shaped and enriched our research group, and set the scene for future developments. The full list of our members is available here.

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Filip Biljecki

Assistant Professor

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Matias Quintana

Research Fellow

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Chenyi Cai

Research Fellow

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Hou Yujun

Research Associate

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Binyu Lei

PhD Researcher

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Winston Yap

PhD Researcher

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Edgardo G. Macatulad

PhD Researcher

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Koichi Ito

PhD Researcher

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Zicheng Fan

PhD Researcher

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Yixin Wu

PhD Researcher

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Liang Xiucheng

PhD Researcher

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Sijie Yang

PhD Researcher

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Yihan Zhu

PhD Researcher

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Yang Chen

Visiting Scholar

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Jiatong Li

Visiting Scholar

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Weipeng Deng

Visiting Scholar

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Gu Youlong

Graduate Student

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Zhou Kun

Graduate Student

Recent publications

Full list of publications is here.

RooFormer: Reconstructing detailed 3D roof models from high-resolution remote sensing imagery using transformer
RooFormer: Reconstructing detailed 3D roof models from high-resolution remote sensing imagery using transformer

Building roofs are essential for various geographical analyses such as solar potential analysis and urban microclimate simulation. Despite growing demand, reconstructing detailed 3D roofs remains challenging due to the complexity of roof geometries and variations in architectural styles. This paper introduces RooFormer, an end-to-end learning framework for reconstructing detailed and textured 3D roof models in mesh format from high-resolution imagery. RooFormer consists of a MaskFormer branch, which identifies and focuses on roof features, and a MeshFormer branch, which predicts detailed roof meshes. In the MeshFormer branch, a local self-attention mechanism is employed to understand mesh features, and a positional embedding layer is designed to integrate geometric and texture features. In addition, to measure the geometric similarity between predicted meshes and ground truth, we develop a loss function that integrates terms from both image and mesh spaces. Compared to existing 3D metrics, the proposed geometric loss term more accurately reflects the geometric differences in meshes. Experiments show that its normalized height error of 0.014 is lower than the 0.034 error of state-of-the-art methods. Visually, the reconstruction accurately reflects the geometric contours and structures of roofs, even with slight occlusions. We also demonstrate its generalization by testing it across various areas. The framework promises to enable richer building modeling and analysis for a wide range of digital city applications.

Make yourself comfortable: Nudging urban heat and noise mitigation with smartwatch-based Just-in-time Adaptive Interventions (JITAI)
Make yourself comfortable: Nudging urban heat and noise mitigation with smartwatch-based Just-in-time Adaptive Interventions (JITAI)

Humans can play a more active role in improving their comfort in the built environment if given the right information at the right place and time. This paper outlines the use of Just-in-Time Adaptive Interventions (JITAI) implemented in the context of the built environment to provide information that helps humans minimize the impact of heat and noise on their daily lives. This framework is based on the open-source Cozie iOS smartwatch platform. It includes data collection through micro-surveys and intervention messages triggered by environmental, contextual, and personal history conditions. An eight-month deployment of the method was completed in Singapore with 103 participants who submitted more than 12,000 micro-surveys and had more than 3,600 JITAI intervention messages delivered to them. A weekly survey conducted during two deployment phases revealed an overall increase in perceived usefulness ranging from 8%–19% over the first three weeks of data collection. For noise-related interventions, participants showed an overall increase in location changes ranging from 4%–11% and a 2%–17% increase in earphone use to mitigate noise distractions. For thermal comfort-related interventions, participants demonstrated a 3%–13% increase in adjustments to their location or thermostat to feel more comfortable. The analysis found evidence that personality traits (such as conscientiousness), gender, and environmental preferences could be factors in determining the perceived helpfulness of JITAIs and influencing behavior change. These findings underscore the importance of tailoring intervention strategies to individual traits and environmental conditions, setting the stage for future research to refine the delivery, timing, and content of intervention messages.

Living upon networks: A heterogeneous graph neural embedding integrating waterway and street systems for urban form understanding
Living upon networks: A heterogeneous graph neural embedding integrating waterway and street systems for urban form understanding

Cities are supported by multiple, interacting networks, most prominently streets, which channel movement and economic exchange, and, in many contexts, waterways, which regulate flows of goods, people, and environmental amenities. Conventional quantitative studies of urban form have tended to privilege streets alone, limiting their ability to capture the full spatial logic of the urban fabric. This paper introduces a Heterogeneous Graph Autoen-coder (HeterGAE) that jointly embeds street and waterway systems, providing a unified, graph-based representation of urban form. Using Singapore as a case study, we train HeterGAE embeddings and employ them in two downstream tasks: predicting daytime and night-time land-surface temperature (LST) and estimating resale prices of public housing. Relative to a baseline model that encodes streets only, the dual-network embeddings improve predictive accuracy by about 20% for both tasks, confirming that natural and built infrastructures make complementary contributions to urban socio-environmental processes. By capturing the interaction between street junctions and waterway nodes within a single latent space, the proposed approach provides a flexible template for GeoAI-assisted urban analytics in diverse settings. The results underscore the value of integrating heterogeneous urban networks in evidence-based planning and highlight the potential of graph-neural techniques for developing more nuanced and sustainable urban strategies.

Multi-objective optimization of food, energy and carbon for vertical agrivoltaic system on building façades
Multi-objective optimization of food, energy and carbon for vertical agrivoltaic system on building façades

Climate change and urbanization present critical challenges to cities, requiring innovative energy and food security strategies. This study introduces a novel agrivoltaic system for building façades in Singapore’s dense urban context, addressing the trade-off between photovoltaic (PV) electricity generation and plant growth under shared solar exposure. By combining field experiments and advanced simulations, a genetic algorithm was employed to optimize PV arrangements, balancing solar exposure conflict for energy production and crop cultivation while also reducing building cooling load. Lettuce (Lactuca sativa) grown under PV shading yielded up to 120 g per plant, meeting commercial standards. Simulations revealed significant building energy benefits, with approximate annual savings of 50 kWh/m2 and CO2 reductions of 35 kg/m2 for every 100 m2 building block. This innovative system integrates renewable energy generation, urban agriculture, and passive cooling, maximizing the utility of vertical surfaces. By efficiently utilizing building surfaces, this approach offers a land-efficient strategy for integrating sustainable food and energy solutions in dense urban areas, contributing to urban resilience and further supporting sustainable development goals.

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