Nazish Naeem scite author profile

Mechanical search is a robotic problem where a robot needs to retrieve a target item that is partially or fullyoccluded from its camera. State-of-the-art approaches for mechanical search either require an expensive search process to find the target item, or they require the item to be tagged with a radio frequency identification tag (e.g., RFID), making their approach beneficial only to tagged items in the environment.We present FuseBot, the first robotic system for RF-Visual mechanical search that enables efficient retrieval of both RFtagged and untagged items in a pile. Rather than requiring all target items in a pile to be RF-tagged, FuseBot leverages the mere existence of an RF-tagged item in the pile to benefit both tagged and untagged items. Our design introduces two key innovations. The first is RF-Visual Mapping, a technique that identifies and locates RF-tagged items in a pile and uses this information to construct an RF-Visual occupancy distribution map. The second is RF-Visual Extraction, a policy formulated as an optimization problem that minimizes the number of actions required to extract the target object by accounting for the probabilistic occupancy distribution, the expected grasp quality, and the expected information gain from future actions.We built a real-time end-to-end prototype of our system on a UR5e robotic arm with in-hand vision and RF perception modules. We conducted over 180 real-world experimental trials to evaluate FuseBot and compare its performance to a state-ofthe-art vision-based system named X-Ray [10]. Our experimental results demonstrate that FuseBot outperforms X-Ray's efficiency by more than 40% in terms of the number of actions required for successful mechanical search. Furthermore, in comparison to X-Ray's success rate of 84%, FuseBot achieves a success rate of 95% in retrieving untagged items, demonstrating for the first time that the benefits of RF perception extend beyond tagged objects in the mechanical search problem.

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FuseBot: Mechanical Search of Rigid and Deformable Objects via Multi-Modal Perception

Boroushaki

Dodds

Naeem

et al. 2023

Preprint

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Mechanical search is a robotic problem where a robot needs to retrieve a target item that is partially or fully-occluded from its camera. State-of-the-art approaches for mechanical search either require an expensive search process to find the target item, or they require the item to be tagged with a radio frequency identification tag (eg, RFID), making their approach beneficial only to tagged items in the environment. We present FuseBot, the first robotic system for RF-Visual mechanical search that enables efficient retrieval of both RF-tagged and untagged items in a pile. Rather than requiring all target items in a pile to be RF-tagged, FuseBot leverages the mere existence of an RF-tagged item in the pile to benefit both tagged and untagged items. Our design introduces two key innovations. The first is RF-Visual Mapping, a technique that identifies and locates RF-tagged items in a pile and uses this information to construct an RF-Visual occupancy distribution map. The second is RF-Visual Extraction, a policy formulated as an optimization problem that minimizes the number of actions required to extract the target object by accounting for the probabilistic occupancy distribution, the expected grasp quality, and the expected information gain from future actions. We built a real-time end-to-end prototype of our system on a UR5e robotic arm with in-hand vision and RF perception modules. We conducted over 180 real-world experimental trials to evaluate FuseBot and compare its performance to a state-of-the-art vision-based system named X-Ray. Our experimental results demonstrate that FuseBot outperforms X-Ray’s efficiency by more than 40% in terms of the number of actions required for successful mechanical search. Furthermore, in comparison to X-Ray’s success rate of 84%, FuseBot achieves a success rate of 95% in retrieving untagged items, demonstrating for the first time that the benefits of RF perception extend beyond tagged objects in the mechanical search problem.

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Demo: Enabling Battery-Free Wireless Underwater Imaging

Rademacher

Akbar

Afzal

et al. 2022

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This demo presents a system for real-time wireless imaging of underwater environments using a fully-submerged battery-free camera. The camera powers up from harvested acoustic energy, captures images using an ultra-low-power image sensor, and communicates wirelessly using piezo-acoustic backscatter. A demo video of the battery-free camera can be found here: https://www.youtube.com/watch?v=kyVZ1ll6_qY

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Nazish Naeem

Software-Controlled Polarization for Longer-Range RFID Reading and Localization

FuseBot: RF-Visual Mechanical Search

FuseBot: Mechanical Search of Rigid and Deformable Objects via Multi-Modal Perception

Demo: Enabling Battery-Free Wireless Underwater Imaging

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