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Secure sensing in AIoT

Main contributors from the group: Qun Song (topic coordinator), Zhenyu Yan

Image modified from this, credit goes to the source. Also refer to this paper for background

By 2025, it is estimated that there will be more than 41.6 billion networked IoT devices. These IoT devices generate 79.4 zettabyes data yearly, which is almost twice of today’s whole Internet (44 zettabytes). Transmitting such massive IoT data to the clouds for centralized processing will face communication bandwidth bottleneck. In addition, the communication networks will introduce uncertain time delays that are undesirable for many applications. To cope with these grand challenges, edge computing moves the computation on the IoT data closer to the data sources. Specifically, the IoT sensors and the last-mile data aggregators, acting as edge nodes, will undertake a significant portion of the computation on the IoT data; only data summaries and commands will be exchanged between the edge nodes and the cloud servers through the Internet when needed. As such, a hybrid computing paradigm consisting of edge computing at the front end and cloud computing at the back end will prevail along with the formation of IoT as a global infrastructure.

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Privacy-preserving sensing in AIoT

Main contributors from the group: Linshan Jiang (topic coordinator), Chaojie Gu, Mengyao Zheng (alumnus), Dixing Xu (alumnus)

Privacy-Preserving Machine Learning in IoT

As explained in our post, a hybrid computing paradigm consisting of edge computing at the front end and cloud computing at the back end will prevail along with the formation of IoT as a global infrastructure. In addition, the deep neural network-based learning and inference will be important for improving the sensing performance of IoT systems. In a number of scenarios, the IoT edge and the cloud back end need to work together to implement AI-empowered sensing, during which privacy-sensitive data generated at the edge may be exchanged between the edge and the cloud. The group has ongoing research on designing and evaluating privacy-preserving learning and inference approaches in AIoT systems. Our challenge paper (PDF) provides a taxonomy of the existing privacy-preserving learning and inference approaches.

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Powerline radiation sensing

Main contributors from the group: Zhenyu Yan(topic coordinator), Qun Song, Rongrong Wang, Xu Liu, Linshan Jiang

Electric power distribution networks penetrate into all civil infrastructures. The service powerlines emit both electric fields and magnetic fields. The electric fields are induced by the voltages of the powerlines, and the magnetic fields are induced by the currents going through the powerlines. Because the power networks provide alternating currents at a nominal frequency (e.g., 50Hz in Singapore), the electric and magnetic fields emitted from the service powerlines also oscillate at the nominal frequency.

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LoRa radio sensing

Main contributors from the group: Chaojie Gu (topic coordinator), Linshan Jiang, Dongfang Guo

Low-power wide-area networks (LPWANs) form an important class of wireless networks for many geographically distributed Internet-of-Things (IoT) objects. LPWANs form a new pole in the spectrum of power consumption versus communication ranges, as shown in the figure below. LPWANs’ long-range communication capabilities will increase the degree of connectivity of IoT and enable deep penetration of networked intelligence into urban territories (e.g., wide areas, buildings, and underground structures) that have challenged the existing low-power short-range wireless technologies. Among various LPWAN technologies, we primarily focus on LoRaWAN due to its various advantages, such as the use of license-free industrial, scientific, and medical (ISM) frequency band, open data link layer specification, and low cost (several US dollars per unit).

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Building sensing

Main contributors from the group: Duc Van Le (topic coordinator), Rongrong Wang, Yingbo Liu (alumnus)

We study the problems of sensing the environment conditions in a building and controlling various actuators to reduce the building’s energy consumption and maintain certain environmental condition levels when the load (e.g., IT equipment, human occupants) of the building varies over time. Dr. Rui Tan has early research works on residential power disaggregation by deploying wireless sensors in a nearly ad hoc way [1, 2], temperature field prediction [3] and cooling control [4] in computer rooms. At present, the group is actively conducting research for improving the energy efficiency of data centers in Singapore’s tropical condition with year-round high temperatures and high humidity levels.

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Acoustic and imagery sensing

Main contributors from the group: Wenjie Luo (topic coordinator), Qun Song, Chaojie Gu, Zhenyu Yan, Duc Van Le, Siyuan Zhou, Jiale Chen, Qiping (Joy) Yang

The acoustic and imagery sensing modalities provide abundant information about the sensed target. As a result, the volume of an acoustic/imagery signal sample is often high and the data processing to extract useful information requires intensive computing. Such characteristics introduce various system challenges in data acquisition, computing, storage, and network transmission on networked sensing platforms with constrained processing capabilities, network bandwidth, and bounded energy supply.

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Conference and workshop papers

2025

  1. Rolling in the Deep: Exploiting Rolling Shutter Effect Against Stereo Depth Estimation in Drones.
    Dongfang Guo, Rui Tan. The 11th Workshop on Micro Aerial Vehicle Networks, Systems, and Applications (DroNet), co-located with ACM MobiSys, June 27, 2025, Anaheim, CA, USA.
    PDF

  2. Low-Carbon Autonomous Driving Computing via Adaptive Solar Batteries.
    Siyuan Zhou, Zimo Ma, Rui Tan. The 31st IEEE International Conference on Embedded and Real-Time Computing Systems and Applications (RTCSA), August 20-22, 2025, Singapore.
    PDF

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Journal papers

2025

  1. RoboCam: Model-Based Robotic Visual Sensing for Precise Inspection of Mesh Screens.
    Siyuan Zhou, Duc Van Le, Linshan Jiang, Zhuoran Chen, Xiaohua Peng, Daren Ho, Jianmin Zheng, Rui Tan.
    ACM Transactions on Sensor Networks (TOSN). In press.
    Preprint

2024

  1. Impacts of Increasing Temperature and Relative Humidity in Air-Cooled Tropical Data Centers.
    Duc Van Le, Jing Zhou, Rongrong Wang, Rui Tan, Fei Duan.
    IEEE Transactions on Sustainable Computing In press.
    Preprint
    Data

  2. A Collaborative Visual Sensing System for Precise Quality Inspection at Manufacturing Lines.
    Jiale Chen, Duc Van Le, Rui Tan, Daren Ho.
    ACM Transactions on Cyber-Physical Systems (TCPS). In press.
    Special Issue: Best Papers of ICCPS 2023.
    Preprint

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Thesis

  1. Exploiting Induced Skin Electric Potential for Body-Area IoT System Functions.
    Zhenyu Yan     PDF
  2. Exploiting LoRaWAN for Efficient and Resilient IoT Networks.
    Chaojie Gu PDF
  3. Lightweight Privacy-Preserving Deep Learning and Inference in IoT.
    Linshang Jiang PDF
  4. Improving Security of Autonomous Cyber-Physical Systems against Adversarial Examples.
    Qun Song PDF
  5. Exploiting Sensor and Process Characteristics to Tackle Label Scarcity in AIoT Sensing.
    Wenjie Luo PDF

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Book chapters

  1. Artificial Intelligence of Things for Industrial Visual Sensing Systems in HP’s Factories.
    Duc Van Le, Siyuan Zhou, Joy Qiping Yang, Jiale Chen, Daren Ho, Rui Tan.
    Digital Manufacturing, Vol. 2. Elsevier.

  2. Lightweight Privacy-Preserving Machine Learning and Inference.
    Linshan Jiang and Rui Tan.
    Intelligent IoT for the Digital World (Eds. Yang Yang, Xu Chen, Rui Tan, Yong Xiao). Wiley. In production.

  3. Time Synchronization Management for Wide-Area Applications.
    Zhenyu Yan, Yang Li, and Rui Tan.
    Intelligent IoT for the Digital World (Eds. Yang Yang, Xu Chen, Rui Tan, Yong Xiao). Wiley. In production.

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Technical report

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