Ricardo Martins scite author profile

Abstract-Obtaining synoptic observations of dynamic ocean phenomena such as fronts, eddies, oxygen minimum zones and blooms has been challenging primarily due to the large spatial scales involved. Traditional methods of observation with manned ships are expensive and, unless the vessel can survey at high-speed, unrealistic. Autonomous underwater vehicles (AUVs) are robotic platforms that have been making steady gains in sampling capabilities and impacting oceanographic observations especially in coastal areas. However, their reach is still limited by operating constraints related to their energy sources. Unmanned aerial vehicles (UAVs) recently introduced in coastal and polar oceanographic experiments have added to the mix in observation strategy and methods. They offer a tantalizing opportunity to bridge such scales in operational oceanography by coordinating with AUVs in the water-column to get in-situ measurements. In this paper, we articulate the principal challenges in operating UAVs with AUVs making synoptic observations for such targeted watercolumn sampling. We do so in the context of autonomous control and operation for networked robotics and describe novel experiments while articulating the key challenges and lessons learned.

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SWORDFISH: an Autonomous Surface Vehicle for Network Centric Operations

Ferreira¹,

Martins²,

Marques³

et al. 2007

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The design and development of the Swordfish Autonomous Surface Vehicle (ASV) system is discussed. Swordfish is an ocean capable 4.5m long catamaran designed for network centric operations (with ocean and air going vehicles and human operators). In the basic configuration, Swordfish is both a survey vehicle and a communications node with gateways for broadband, Wi-Fi and GSM transports and underwater acoustic modems. In another configuration, Swordfish mounts a docking station for the autonomous underwater vehicle Isurus from Porto University. Swordfish has an advanced control architecture for multi-vehicle operations with mixed initiative interactions (human operators are allowed to interact with the control loops).

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Implementation of a Control Architecture for Networked Vehicle Systems

Pinto

Calado

Braga

et al. 2012

IFAC Proceedings Volumes

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The light autonomous underwater vehicle: Evolutions and networking

Madureira¹,

Sousa²,

Braga

et al. 2013

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Integrated Monitoring of Mola mola Behaviour in Space and Time

et al. 2016

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Over the last decade, ocean sunfish movements have been monitored worldwide using various satellite tracking methods. This study reports the near-real time monitoring of fine-scale (< 10 m) behaviour of sunfish. The study was conducted in southern Portugal in May 2014 and involved satellite tags and underwater and surface robotic vehicles to measure both the movements and the contextual environment of the fish. A total of four individuals were tracked using custom-made GPS satellite tags providing geolocation estimates of fine-scale resolution. These accurate positions further informed sunfish areas of restricted search (ARS), which were directly correlated to steep thermal frontal zones. Simultaneously, and for two different occasions, an Autonomous Underwater Vehicle (AUV) video-recorded the path of the tracked fish and detected buoyant particles in the water column. Importantly, the densities of these particles were also directly correlated to steep thermal gradients. Thus, both sunfish foraging behaviour (ARS) and possibly prey densities, were found to be influenced by analogous environmental conditions. In addition, the dynamic structure of the water transited by the tracked individuals was described by a Lagrangian modelling approach. The model informed the distribution of zooplankton in the region, both horizontally and in the water column, and the resultant simulated densities positively correlated with sunfish ARS behaviour estimator (rs = 0.184, p<0.001). The model also revealed that tracked fish opportunistically displace with respect to subsurface current flow. Thus, we show how physical forcing and current structure provide a rationale for a predator’s fine-scale behaviour observed over a two weeks in May 2014.

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IMC: A communication protocol for networked vehicles and sensors

Martins

Dias

Marques

et al. 2009

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REP10 AUV: Shallow water operations with heterogeneous autonomous vehicles

Martins

Sousa

Afonso

et al. 2011

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Ricardo Martins

The LSTS toolchain for networked vehicle systems

Coordinating UAVs and AUVs for oceanographic field experiments: Challenges and lessons learned

SWORDFISH: an Autonomous Surface Vehicle for Network Centric Operations

Implementation of a Control Architecture for Networked Vehicle Systems

The light autonomous underwater vehicle: Evolutions and networking

Integrated Monitoring of Mola mola Behaviour in Space and Time

IMC: A communication protocol for networked vehicles and sensors

REP10 AUV: Shallow water operations with heterogeneous autonomous vehicles

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