Nature in engineering for monitoring the oceans: comparison of the energetic costs of marine animals and AUVs

Phillips, Alexander B.; Haroutunian, Maryam; Man, Shushuang; Murphy, Alan J.; Boyd, Stephen; Blake, J.I.R.; Griffiths, Gwyn

doi:10.1049/pbce077e_ch17

Cited by 18 publications

(45 citation statements)

References 90 publications

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“…Therefore to achieve equivalent performance using Python compared to C++ requires a more powerful computer that will, in general, use more electrical power. The hotel load of Delphin2 at 50W is high for a vehicle of it's size [20]. As this vehicle is designed as a research platform, electrical power consumption is not of primary concern and instead the rate of software development takes precedent.…”

Section: Vehicle Characteristicsmentioning

confidence: 99%

Model predictive control of a hybrid autonomous underwater vehicle with experimental verification

Steenson

Turnock

Phillips

et al. 2014

Proceedings of the Institution of Mechanical Engineers, Part M:

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In this work model predictive control is used to provide transit and hover capabilities for an autonomous underwater vehicle where the description of the system dynamics used include terms measured experimentally. The resulting controller manoeuvres the vehicle in the presence of constraints on the actuators and results obtained from the deployment of the vehicle in an inland lake for the study of the Zebra mussel, an invasive species, are also given.

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Section: Vehicle Characteristicsmentioning

confidence: 99%

Model predictive control of a hybrid autonomous underwater vehicle with experimental verification

Steenson

Turnock

Phillips

et al. 2014

Proceedings of the Institution of Mechanical Engineers, Part M:

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“…Consequently, significant research effort has been applied to mimicking biological propulsion systems, for example see DLVCUUV robotic tuna [37], robotic dolphin [38], Finnegan robotic turtle [39], and soft-bodied robot fish [40]. However, current actuator efficiencies mean that the electric motor and propeller combination still provides a comparable level of total propulsion system efficiency, with comparatively easy control and design [41]. As such, a conventional propeller and brushless DC motor combination will be used to propel the NEMOdeep vehicle.…”

Section: F Propulsor and Actuationmentioning

confidence: 99%

Nature in Engineering for Monitoring the Oceans (NEMO): An isopycnal soft bodied approach for deep diving autonomous underwater vehicles

Phillips

Blake

Boyd

et al. 2012

2012 IEEE/OES Autonomous Underwater Vehicles (AUV)

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Taking inspiration from nature the NEMOdeep vehicle described in this paper is being developed as a laboratory demonstrator to showcase potential technologies to achieve small deep diving autonomous underwater vehicles. The design of the vehicle is a hybrid of conventional AUV components with engineered analogues of marine animal organs. The internal structure is comprised of a spine, ribs and sternum, which support a hydrodynamic fairing or 'skin'. The 'brain' and actuators are developed using pressure tolerant electronics, negating the need for pressure vessels. The pressure tolerant electronics are surrounded by light mineral oil which transmits the hydrostatic pressure uniformly to the components while also providing buoyancy. The internal fluid is more compressible than seawater and the batteries and internal structure are less compressible than seawater: a 'Buoyancy/Compressibility' organ is being developed to passively maintain neutral buoyancy over the 0 to 6000m depth range.

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“…However for BMSs with limited available data, the calculation is rather complicated. Therefore, a formulation of the physical factors associated with biological & engineered systems energy usage was presented for energetic cost comparison [1]. Since BMSs from many and various biological classes of species are investigated in this research, there were a number of principal challenges to be overcome.…”

Section: A Investigating Bio-inspiration: the Contrast Between Bms Amentioning

confidence: 99%

“…As explained by Phillips et al [1], the energetic cost of transport for biological and engineered vehicles is calculated as: It is evident from literature that the definition of total efficiency is inconsistent when applied to BMSs and in some cases unclear; therefore to elaborate further on the definition of , this is given special treatment in Section V.…”

Section: A Calculation Of the Energetic Costmentioning

confidence: 99%

Mission based Optimum System Selector for Bio-inspired Unmanned Untethered Underwater Vehicles

Haroutunian

Murphy

2012

2012 IEEE/OES Autonomous Underwater Vehicles (AUV)

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This paper is a part of the Nature in Engineering for Monitoring the Oceans (NEMO) project, investigating bio-inspiration to improve the performance of Unmanned Untethered Underwater Vehicles (UUUVs). Since biological systems (i.e. marine animals) are natives to the oceans, successfully surviving through time, they have been the source of this approach.NEMO's earlier investigations highlighted biological capabilities desirable for UUUV operations, including speed, speed range and manoeuvrability. These are significantly superior compared to current engineered systems. However, not all desirable characteristics are evident in the same species. Considering the mismatch between the "missions" of biological and engineered systems, no single specific biological system is able to fulfil all the desired UUUV mission requirements. Therefore, means are required to obtain the myriad of information from the biological world and adjust them to engineering needs. This paper describes the algorithm of an Optimum System Selector (OSS) demonstrating its methodology and explaining modules such as estimating the drag of biological systems and indication of their propulsive efficiency. The OSS is implemented to output the appropriate combination for a bio-inspired UUUV design, based on its mission.The OSS comprises missions as inputs, the decision maker, and the outputs. Mission profiles also account for capabilities unique to biological systems such as high manoeuvrability. The decision maker takes into account three main modules; speed and propulsion, manoeuvrability and upright stability. The fitnessfor-purpose function of the selector consists of the energetic cost of the proposed combination, as well as the trade-off between the three modules due to the multi-functionality of the biological systems. The output consists of body and control surfaces design, propulsion and manoeuvring systems.Through this method, OSS is an excellent guide to transform complex biological data for the future design and development of UUUVs.

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Nature in engineering for monitoring the oceans: comparison of the energetic costs of marine animals and AUVs

Cited by 18 publications

References 90 publications

Model predictive control of a hybrid autonomous underwater vehicle with experimental verification

Model predictive control of a hybrid autonomous underwater vehicle with experimental verification

Nature in Engineering for Monitoring the Oceans (NEMO): An isopycnal soft bodied approach for deep diving autonomous underwater vehicles

Mission based Optimum System Selector for Bio-inspired Unmanned Untethered Underwater Vehicles

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