Naomi Stricker

Naomi Stricker
PhD Student
Alumni
ETH Zurich
Bringing energy harvesting to dependable distributed control is accompanied by fascinating challenges but ultimately enables diverse new applications.

Naomi Stricker is a PhD candidate in the Computer Engineering Group at ETH Zurich. Her research focuses on energy harvesting Internet-of-Things systems and their design, optimization, and reliability. She further explores the application of energy harvesting systems in the domain of automation and control. Before starting her PhD in 2018, she worked in industry in California, USA in the area of helicopter simulators. She completed both her bachelor’s and master’s in Electrical Engineering and Information Theory at ETH Zurich in 2014 and 2016, respectively. 

Scientific Publications

Published
Robustness of predictive energy harvesting systems: Analysis and adaptive prediction scaling
IET Computers & Digital Techniques
Vol 16 No 4 Pages 106-124
Published
Secure Communication with Batteryless Sensors
2022 11th Mediterranean Conference on Embedded Computing (MECO)
Pages 1-4
Published
Demo Abstract: DPP3e: A Harvesting-based Dual Processor Platform for Advanced Indoor Environmental Sensing
2022 21st ACM/IEEE International Conference on Information Processing in Sensor Networks (IPSN)
Pages 495-496
Published
Poster Abstract: Selective Flooding-Based Communication for Energy Harvesting Networks
2022 21st ACM/IEEE International Conference on Information Processing in Sensor Networks (IPSN)
Published
Accurate Onboard Predictions for Indoor Energy Harvesting using Random Forests
2022 11th Mediterranean Conference on Embedded Computing (MECO)
Pages 1-6
Published
Robust Resource-Aware Self-Triggered Model Predictive Control
IEEE Control Systems Letters
Pages 1724-1729
Published
Joint Energy Management for Distributed Energy Harvesting Systems
SenSys '21: Proceedings of the 19th ACM Conference on Embedded Networked Sensor Systems
Pages 575-577
Published
Resource-Aware Stochastic Self-Triggered Model Predictive Control
IEEE Control Systems Letters
Vol 6 Pages 1262 – 1267

Research projects as Researcher

Titolo
Principal Investigators

Reliable Wireless Network Infrastructure

Sommario

In this project, we will investigate new models and methods to map and implement distributed applications to computation and communication resources while considering scalability, adaptability, low resource availabilities, low power and high dependability: Combine wireless multi-hop communication principles based on synchronous transmissions with long-range, low power protocols, e.g., LoRa. Investigate fault tolerant and fully distributed control mechanisms for network management like communication scheduling and bandwidth allocation. The approaches studied will be based on synchronous transmissions, analysis of distributed real-time systems and end-to-end real-time cyber-physical systems.

Reliable Wireless Network Infrastructure

In this project, we will investigate new models and methods to map and implement distributed applications to computation and communication resources while considering scalability, adaptability, low resource availabilities, low power and high dependability: Combine wireless multi-hop communication principles based on synchronous transmissions with long-range, low power protocols, e.g., LoRa. Investigate fault tolerant and fully distributed control mechanisms for network management like communication scheduling and bandwidth allocation. The approaches studied will be based on synchronous transmissions, analysis of distributed real-time systems and end-to-end real-time cyber-physical systems.

151
1f80d52c-d169-49d2-9356-03a426764ba4

Dependable Distributed and Hierarchical Control under Energy Constraints

Sommario

We will investigate the theoretical and practical challenges of using energy harvesting to power nodes distributed control systems. Combining energy sources such as temperature and vibration with battery systems and wireless links enables the placement of sensor nodes where they are needed for the best data quality, regardless of the availability of wired power or communication. In the context of the NCCR, we will jointly investigate some of the open challenges in the design of autonomous, energy-neutral automation systems. In a second phase, we will investigate suitable demonstrators and applications such as wireless sensing and control in motor control and energy systems.

Dependable Distributed and Hierarchical Control under Energy Constraints

We will investigate the theoretical and practical challenges of using energy harvesting to power nodes distributed control systems. Combining energy sources such as temperature and vibration with battery systems and wireless links enables the placement of sensor nodes where they are needed for the best data quality, regardless of the availability of wired power or communication. In the context of the NCCR, we will jointly investigate some of the open challenges in the design of autonomous, energy-neutral automation systems. In a second phase, we will investigate suitable demonstrators and applications such as wireless sensing and control in motor control and energy systems.

116
64602cdc-7659-4ea1-a39f-1ded30d42b54

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