The talks will be in-person.
Stanford Robotics and Autonomous Systems Seminar series hosts both invited and internal speakers. The seminar aims to bring the campus-wide robotics community together and provide a platform to overview and foster discussion about the progress and challenges in the various disciplines of Robotics. This quarter, the seminar is also offered to students as a 1 unit course. Note that registration to the class is NOT required in order to attend the talks.
The course syllabus is available here. Go here for more course details.
The seminar is open to Stanford faculty, students, and sponsors.
Attedence Form
For students taking the class, please fill out the attendance form: https://tinyurl.com/robotsem-fall-25 when attending the seminar to receive credit. You need to fill out 7 attedence to receive credit for the quarter, or make up for it by submitting late paragraphs on the talks you missed via Canvas.
Seminar Youtube Recordings
All publically available past seminar recordings can be viewed on our YouTube Playlist. Registered students can access all talk recordings on Canvas.
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Schedule Fall 2025
Date | Guest | Affiliation | Title | Location | Time |
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Fri, Sep 26 | Feifei Qian | USC | Make Every Step an Experiment: Towards Terrain-aware, High-mobility Robots for Planetary Explorations | Gates B01 | 3:00PM |
Abstract
In this talk, I will present our recent progress in two main directions. First, I will show that by strategically eliciting the force responses from loose regolith, robots could generate desired ground reaction forces and achieve substantially improved locomotion performance on deformable substrates. Second, I will show that by leveraging the high force transparency of direct-drive actuators, robots can use their legs as proprioceptive sensors to opportunistically determine the terramechanical properties of regolith from every step. |
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Fri, Oct 03 | Yang Gao | THU | Manipulation Data Pyramid: From Human Video Pretraining to Physical RL | Gates B01 | 3:00PM |
Abstract
Scaling laws are now often seen as a key ingredient on the path toward general intelligence. But in robotics, progress is slowed by one major obstacle: the lack of abundant, high-quality data. In this talk, I introduce a data pyramid strategy designed to tackle this challenge by making the most of diverse data sources. The idea is simple but powerful: combine internet-scale datasets, human teleoperation data, and robot-collected experiences so that each strengthens and fills in the gaps of the others. |
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Fri, Oct 10 | Simone Schürle‑Finke | ETHz | Design, Synthesis, Control, and Tracking of Soft Magnetic Microrobots for Targeted Therapeutic Delivery | Gates B01 | 3:00PM |
Abstract
Effective delivery of therapeutics remains a central challenge in medicine, particularly when interventions must navigate complex and dynamic biological environments. Magnetic microrobots offer a promising solution, providing untethered locomotion and the ability to actively steer toward target sites. Among actuation strategies, rotational magnetic fields provide scalable torque-based propulsion, enabling continuous motion and agile navigation even under physiologically relevant flow conditions. In this presentation, I will highlight two complementary microrobotic platforms. Biohybrid microrobots based on bacteria combine autonomous chemotactic sensing with external torque-based control, allowing them to navigate tissues while maintaining responsiveness to applied magnetic fields. Synthetic bioinspired microrobots, constructed from biodegradable hydrogels with anisotropic magnetic nanoparticle patterns, exploit torque-driven propulsion to achieve efficient transport and directional control in vascular models and other constrained environments. To further improve targeting, I will introduce a strategy for spatially restricting rotating magnetic fields, focusing torque delivery to specific regions to enhance precision and reduce off-target effects. Complementing this, we integrate inductive feedback for real-time tracking, capturing magnetic phase lag and swarm synchronization to enable closed-loop control of microrobotic motion and collective behavior. Together, these advances—from torque-driven actuation and programmable magnetic design to spatially focused control and real-time feedback—demonstrate a versatile, scalable approach for microscale robotic systems in targeted therapeutics, paving the way toward clinical translation. |
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Fri, Oct 17 | Nick Gravish | UCSD | TBD | Gates B01 | 3:00PM |
Abstract
TBD |
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Fri, Oct 24 | Student Speaker | Stanford | TBD | Gates B01 | 3:00PM |
Abstract
TBD |
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Fri, Oct 24 | Student Speaker | Stanford | TBD | Gates B01 | 3:00PM |
Abstract
TBD |
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Fri, Oct 31 | Ashutosh Saxena | Torque AGI | TBD | Gates B01 | 3:00PM |
Abstract
TBD |
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Fri, Nov 07 | Yuke Zhu | UT Austin | TBD | Gates B01 | 3:00PM |
Abstract
TBD |
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Fri, Nov 21 | Jitendra Malik | UCB | TBD | Gates B01 | 3:00PM |
Abstract
TBD |
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Fri, Dec 05 | Nadia Figueroa | UPenn | TBD | Gates B01 | 3:00PM |
Abstract
TBD |
Sponsors
The Stanford Robotics and Autonomous Systems Seminar enjoys the support of the following sponsors.