The Basking Shark ( Cetorhinus maximus) is an elusive creature that possesses a highly-specialised filter-feeding system capable of filtering around two million litres of water every hour. Learning from such filters could be instrumental in making new filtration systems for microplastics or pollutants in the future. However, the specific filtration mechanism, as well as many other aspects of their morphology and behaviour, is not well understood. There are numerous difficulties involved with the study of basking sharks, particularly finding the sharks in their ocean habitat and observing them without disturbing them. Here, we propose a robotic platform, the System for underWater Imaging and Monitoring for Marine Environment Research (SWIMMER, SWIM for short), for the non-invasive imaging of basking sharks. The robot was designed to produce high-resolution stereo images at both surface level and underwater. The imaging payload is carried by a surface robot to make it easy to monitor, control, and retrieve. The robot is built low-cost and entirely from off-the-shelf components and 3D printing to enable us to scale up the robot to a swarm in the future for imaging from multiple points of view and for other marine applications. In a single trial, we were able to collect video data from 6 different basking shark encounters with 9 different individuals, as well as gathering data about manoeuvrability. This work has the potential to provide new insights into basking shark feeding behaviour, as well as potentially making marine swarm robotics more accessible to researchers everywhere due to the low cost and ease of construction of the SWIMMERs.

Engineering microscopic collectives of cells or microrobots is challenging due to the often-limited capabilities of the individual agents, our inability to reliably program their motion and local interactions, and difficulties visualising their behaviours. Here, we present a low-cost, modular and open-source Dynamic Optical MicroEnvironment (DOME) and demonstrate its ability to augment microagent capabilities and control collective behaviours using light. The DOME offers an accessible means to study complex multicellular phenomena and implement de-novo microswarms with desired functionalities. Corresponding author(s) Email:    [email protected] [email protected]

Single-use jumping robots that are mass-producible and biodegradable could be quickly released for environmental sensing applications. Such robots would be pre-loaded to perform a set number of jumps, in random directions and with random distances, removing the need for onboard energy and computation. Stochastic jumpers build on embodied randomness and large-scale deployments to perform useful work. This paper introduces simulation results showing how to construct a large group of stochastic jumpers to perform environmental sensing, and the first demonstration of robot prototypes that can perform a set number of sequential jumps, have full-body sensing, and are well suited to be made biodegradable. Corresponding author(s) Email: [email protected] [email protected]