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Abstract

We describe a waterproof, lightweight (1.3 kg), low-power (∼1.1 W average power) fluorometer operating on 5 V direct current deployed on a small uncrewed aircraft system (sUAS) to measure chlorophyll and used for triggering environmental water sampling by the sUAS. The fluorometer uses a 450 nm laser modulated at 10 Hz for excitation and a standard photodiode and transimpedance amplifier for the detection of fluorescence. Additional detectors are available for measuring laser intensity and light scattering. Control of the fluorometer and communication between the fluorometer and the Raspberry Pi 4B computer controlling the sampler were provided by an Arduino microcontroller using the robot operating system (ROS). Calibrations were based on standards of dissolved chlorophyll extracted from Chlorella powder (a widely available dietary supplement). The detection limit for chlorophyll from these calibrations was found to be 0.2 μg per liter of water for a single 0.1 s differential measurement. The detection limit decreases with the square root of the integration time as expected. Detection limits increase by a factor of two to three when mounted in the sUAS due to electrical noise; sUAS acoustic noise and vibration do not appear to contribute significantly.

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Keywords

Fluorescence chlorophyll small uncrewed aircraft system sUAS aerial drone fluorometer automatic water sampling

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References

Behrenfeld

M.J.

O’Malley

R.T.

Siegel

D.A.

McClain

C.R.

, et al. “Climate-Driven Trends in Contemporary Ocean Productivity”. Nature. 2006. 444(7120): 752–755. 10.1038/nature05317

Richardson

T.L.

Jackson

G.A.

. “Small Phytoplankton and Carbon Export from the Surface Ocean”. Science. 2007. 315(5813): 838–840. 10.1126/science.1133471

Boyd

P.W.

Doney

S.C.

Strzepek

Dusenberry

, et al. “Climate-Mediated Changes to Mixed-Layer Properties in the Southern Ocean: Assessing the Phytoplankton Response”. Biogeosciences. 2008. 5(3): 847–864. 10.5194/bg-5-847-2008

Hallegraeff

G.M.

. “Ocean Climate Change, Phytoplankton Community Responses, and Harmful Algal Blooms: A Formidable Predictive Challenge”. J. Phycol. 2010. 46(2): 220–235. 10.1111/j.1529-8817.2010.00815.x

Tett

Barton

E.D.

. “Why Are There About 5000 Species of Phytoplankton in the Sea?” J. Plankton Res. 1995. 17(8): 1693–1704. 10.1093/plankt/17.8.1693

Jeffrey

S.W.

Vesk

J.M.

. “Introduction to Marine Phytoplankton and Their Pigment Signatures” In: Jeffrey

S.W.

Mantoura

R.F.C.

Wright

S.W.

, editors. Phytoplankton Pigments in Oceanography: Guidelines to Modern Methods. Paris: UNESCO Publishing, 1997. Pp. 37–84.

Bruckman

L.S.

Richardson

T.L.

Swanstrom

J.A.

Donaldson

K.A.

, et al. “Linear Discriminant Analysis of Single-Cell Fluorescence Excitation Spectra of Five Phytoplankton Species”. Appl. Spectrosc. 2012. 66(1): 60–65. 10.1366/11-06294

Rekully

C.M.

Faulkner

S.T.

Lachenmyer

E.M.

Cunningham

B.R.

, et al. “Fluorescence Excitation Spectroscopy for Phytoplankton Species Classification Using and All-Pairs Method: Characterization of a System with Unexpectedly Low Rank”. Appl. Spectrosc. 2018. 72(3): 442–462. 10.1177/0003702817741278

Yentsch

C.S.

Menzel

D.W.

. “A Method for the Determination of Phytoplankton Chlorophyll and Phaeophytin by Fluorescence”. Deep-Sea Res. 1963. 10(3): 221–231. 10.1016/0011-7471(63)90358-9

10.

Lawrenz

Richardson

T.L.

. “How Does the Species Used for Calibration Affect Chlorophyll a Measurements by In Situ Fluorometry?” Estuaries Coasts. 2011. 34(4): 872–883. 10.1007/s12237-010-9346-6

11.

Faulkner

S.T.

Rekully

C.M.

Lachenmyer

E.M.

Kara

, et al. “Single-Cell and Bulk Fluorescence Excitation Signatures of Seven Phytoplankton Species During Nitrogen Depletion and Resupply”. Appl. Spectrosc. 2019. 73(3): 304–312. 10.1177/0003702818812090

12.

Schwarzbach

Laiacker

Mulero-Pazmany

Kondak

. “Remote Water Sampling Using Flying Robots”. Paper presented at: 2014 International Conference on Unmanned Aircraft Systems (ICUAS). Orlando, Florida, 27‐30 May 2014. Pp. 72–76. 10.1109/ICUAS.2014.6842240

13.

Ore

J.-P.

Elbaum

Burgin

Detweiler

. “Autonomous Aerial Water Sampling”. J. Field Robotics. 2015. 32: 1095–1113. 10.1002/rob.21591

14.

Castendyk

D.N.

Straight

B.J.

Boorhis

J.C.

Somogyi

M.K.

, et al. “Using Aerial Drones to Select Sample Depths in Pit Lakes”. In: Fourie

A.B.

Tibbett

, editors. Mine Closure 2019: Proceedings of the 13th International Conference on Mine Closure, Australian Centre for Geomechanics, Perth. Pp. 113–1126. 10.36487/ACG_rep/1915_89_Castendyk

15.

Raimondi

Palombi

Lognoli

Masini

Simeone

. “Experimental Tests and Radiometric Calculations for the Feasibility of Fluorescence LIDAR-Based Discrimination of Oil Spills from UAV”. Int. J. Appl. Earth Obs. Geoinf. 2017. 61: 46–54. 10.1016/j.jag.2017.04.012

16.

Duan

Wang

Zhao

Svanberg

. “Aquatic Environment Monitoring Using a Drone-Based Fluorosensor”. Appl. Phys. B. 2019. 125(6): Art. no. 108. 10.1007/200340-019-7215-y

17.

Kalaitzakis

Cain

Carroll

Ambrosi

, et al. “Fiducial Markers for Pose Estimation: Overview, Applications and Experimental Comparison of the ARTag, AprilTag, ArUco, and STag Markers”. J. Intell. Robot. Syst. 2021. 101(4): Art. no. 71. 10.1007/s10846-020-01307-9

18.

Carroll

Satme

Alkharusi

Vitzilaios

, et al. “Drone-Based Vibration Monitoring and Assessment of Structures”. Appl. Sci. 2021. 11(18): Art. no. 8560. 10.3390/app11188560

19.

Kalaitzakis

Vitzilaios

Rizos

D.C.

Sutton

M.A.

Drone-Based StereoDIC System Development , Experimental Validation, and Infrastructure Application”. Exp. Mech. 2021. 61(6): 981–996.

20.

Sanim

KR.I.

Kalaitzakis

Kosaraju

Kitzhaber

, et al. “Development of an Aerial Drone System for Water Analysis and Sampling”. Paper presented at: International Conference on Unmanned Aircraft Systems (ICUAS). Dubrovnik, Croatia, 21–24 June 2022. 10.1109/ICUAS54217.2022.9836122

21.

Price

N.M.

Harrison

P.J.

Landry

M.R.

Azam

, et al. “Toxic Effects of Latex and Tygon Tubing on Marine-Phytoplankton, Zooplankton and Bacteria”. Mar. Ecol.: Prog. Ser. 1986. 34(1‐2): 41–49. 10.3354/meps034041

22.

Kitzhaber

Z.B.

English

C.M.

Sanim

K.R.I.

Kalaitzakis

Kosaraju

Hodgson

M.E.

Vitzilaios

N.I.

Richardson

T.L.

Myrick

M.L.

. “Fluorometer Control and Readout with an Arduino Nano 33 BLE Sense” Applied Spectroscopy (accepted, 2022)

23.

Strickland

J.D.H.

Parsons

T.R.

. A Practice Handbook of Seawater Analysis. Ottawa: Fisheries Research Board of Canada, 1972. Pp. 185–192.

24.

Long

G.L.

Winefordner

J.D.

. “Limit of Detection. A Closer Look at the IUPAC Definition”. Anal. Chem. 1983. 55(7): 712A–724A. 10.1021/ac00258a001

25.

Pinckney

J.L.

Millie

D.F.

Howe

K.E.

Paerl

H.W.

, et al. “Flow Scintillation Counting of C-14-Labeled Microalgal Photosynthetic Pigments”. J. Plankton Res. 1996. 18(10): 1867–1880. 10.1093/plankt/18.10.1867

26.

Carberry

Roesler

Drapeau

. “Correcting In Situ Chlorophyll Fluorescence Time-Series Observations for Nonphotochemical Quenching and Tidal Variability Reveals Conservative Phytoplankton Variability in Coastal Waters”. Limnol. Oceanogr.: Methods. 2019. 17(8): 462–473. 10.1002/lom3.10325

27.

Cullen

J.J.

. “The Deep Chlorophyll Maximum: Comparing Vertical Profiles of Chlorophyll-A”. Can. J. Fish. Aquat. Sci. 1982. 39(5): 791–803. 10.1139/f82-108

28.

Roesler

Uitz

Claustre

Boss

, et al. “Recommendations for Obtaining Unbiased Chlorophyll Estimates from In Situ Chlorophyll Fluorometers: A Global Analysis of WET Labs ECO Sensors”. Limnol. Oceanogr.: Methods. 2017. 15(6): 572–585. 10.1002/lom3.10185

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Chlorophyll Fluorometer for Intelligent Water Sampling by a Small Uncrewed Aircraft System (sUAS)

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