Infrared detector arrays in the detection, automation and robotics - trends and development perspectives

• Autorzy: Pręgowski P.
• Języki publikacji: EN

Abstrakty

EN

Already in the 1970s, it was predicted that the scale of thermal imaging applications would be limited only by the imagination. It happened thanks to the elaboration of solid-state, Focal Plane Arrays of IR detectors (IR FPA) connected with electronics readouts (ROIC CCD). In the last 20 years, thanks to the appearance of uncooled detectors, and recently also photon detectors in the high operation temperature versions, cameras have become significantly smaller, lower weight, consume lower power and are cheaper. It made them more attractive for civil applications, with optimal adaptation to very different tasks. The aim of this study is to present a brief review of the specifics of non-pure-thermographic markets for these IR detectors. The growing interest of many markets, with more affordable prices of better and better detectors, and the available knowledge base, create good conditions for innovative projects and business programs.

Słowa kluczowe

EN

IR FPAs; cooled & uncooled detectors; applications; markets

• Wydawca: Wydawnictwo PAK
• Czasopismo: Measurement Automation Monitoring
• Rocznik: 2018
• Tom: Vol. 64, No. 4
• Strony: 82--89
• Opis fizyczny: Bibliogr. 47 poz., rys., tab.

Twórcy

autor

Pręgowski P.

• PIRS, Pregowski Infrared Services 36 Zachodzącego Słońca Str., 01-495 Warsaw, Poland

Bibliografia

• [1] Collins N.: Scientists create 'sixth sense' brain implant to detect infrared light, The Telegraph, 17 February 2019. www.telegraph.co.uk/news/science/science-news/9875931
• [2] Rogalski A.: Infrared and Terahertz Detectors - III edition, CRC Press, Boca Raton, FL, 2019.
• [3] Bisotto S., Abergel J., Dupont B., Ferron A., Mailliart O., Nicolas J. A., Renet S., Rochette F., Santailler J. L.: 110K displays nonlinearity under 0.1%, a full-well of 3.1 Me- with a 3.8V dynamic range, and NETD of 24mK. Published in Proceedings Volume 11002: Infrared Technology and Applications XLV, May 2019.
• [4] Tinnes S., Boudou N., Durand A.: Ulis bolometer improvements for fast imaging applications. OECD Con. Paris, February 6-8, 2018, www.lynred-usa.com/media/wp-ulis-bolometer-improvements-2-6-2018.pdf - state by June 10, 2019.
• [5] FLIR® Systems, www.flir.com – state by April 20, 2019.
• [6] Rogerson St.: Ulis sensor counts people in buildings. November 8, 2018, IMC, www.iotm2mcouncil.org/uliscoun, state May 6, 2019.
• [7] Infrared Detection Workshop, July 3-5, 2018, www.comet-cnes.fr/resource-access/20180703-05%20Abstract%20List.pdf
• [8] Pregowski P., Goleniewski G., Komosa W., Korytkowski W., Zwolenik S.: Dynamic, Multispectral-band IR Thermography Applications in the Petrochemical Furnaces. Proc. SPIE 5405, Thermosense XXVI, (April12, 2004); doi: 10.1117/12.546806 .
• [9] Barber R., Miguel A., Conejo R., Melendez J., Garrido S.: Design of an Infrared Imaging System for Robotic Inspection of Gas Leaks in Industrial Environments, International Journal of Advanced Robotic Systems, December 15, 2014, doi: 10.5772/60058
• [10] Wiecek P.: A method for automatic gas detection using wide-band 3-14 µm bolometer camera, 14th Quantitative InfraRed Thermography Conference, Berlin 2018, http:// qirt.org/archives/qirt2018/papers.p.32.pdf
• [11] Olbrycht R., Kałuża M., Wittchen W., Borecki M., Więcek B., De Mey G., Kopeć M.: Gas identification and estimation of its concentration in a tube using thermographic camera with diffraction grating. QIRT Journal, Vol. 15, 2018 - Issue 1.
• [12] ROBOTS: Your Guide to the World of Robotics - IEEE, 2019 https://robots.ieee.org/
• [13] Shawnn H.: What’s the drone difference between a drone, UAV and UAS. November 14, 2017, BOTLINK, https://botlink.com/blog
• [14] US Security Against Drone Warfare, April 26, 2019, https://iq.govwin.com/neo/marketAnalysis/view/US-Security-Against-Drone-Warfare/3442?researchTypeId=1 (WB Group, Poland).
• [15] Westoby M. Rutter N., Tobias J.: Three-dimensional thermal characterization of forest canopies using UAV photogrammetry, ELSEVIER, Remote Sensing of Environment, Volume 209, May 2018, Pages 835-847; https:doi.org/10.1016/j.rse.2017.09.033
• [16] Clarkson G., Luo S., Fuentes R.: Thermal 3D Modelling, 34th International Symposium on Automation and Robotics in Construction (ISARC 2017), White Rose Research Online, http://eprints.whiterose.ac.uk/120381/
• [17] Grzegorz Bieszczad G., Gogler S, Krupiński K, Ligienza A., Krzysztof Sawicki K.: The concept of thermovision inertial sensor supporting the navigation of unmanned aerial platforms, TTP 2019, (To be published in MAM 2019 /TTP)
• [18] SBA & READY2SERVICES (R2S), www.eg-4u.org/wp-content/uploads/2018/10/Session-6¬-Smart-Homes-2018.pdf
• [19] www.smartbuildingsalliance.org/association/membres/
• [20] Shortwave Infrared (SWIR) Industry Overview, Alexa Reports, Report Id: GRS-9267, February 2019 www.alexareports.com/ report/shortwave-infrared-swir-industry/9267
• [21] Blog - The global thermal imaging market in 2018, ULIS IR, http://www.ulis-ir.com/blog/the global-thermal-imaging-market- 2018.html – state for May 6, 2019
• [22] Uncooled Infrared Imagers and Detectors https://yole-i-micronews-com.osu.eu-west-2.outscale.com/uploads/2019/02/YD19002- Uncooled_IR_2019_sample.pdf
• [23] Sofradir, ULIS Merge to Become Lynred, PHOTONICS, photonics.com/Newsletter.aspx?NSID=73,347
• [24] http://ala.com/ulis-releases-att0640-worlds-smallest-60-hz-vga-12-micron-thermal-image-sensor/ - state for May 6, 2019
• [25] Roberts Ch.: Global Security Robot Market Share | CAGR Status | Market Growth | Trends | Analysis and Forecast (2018–2023), June, 2019, http;// californiaoralce.com/global-security-robot-market-cagr-status-market-growth-trends-analysis-and-forecast-2018-2023/20486
• [26] Blog - Thermal vision technology a major benefit to the hunting market, http;//www.ulis-ir.com/blog/thermal vision technology a major benefit to the hunting market.html - state for May 6, 2019
• [27] ULIS releases ATT0640™, world’s smallest 60 Hz VGA/12micron thermal image sensor, June 4, 2019, Andrew Loyd & Associates, http://ala.com/ulis-releases-att0640-worlds-smallest-60-hz-vga-12-micron-thermal-image-sensor/ - state for June 6, 2019
• General Thermography
• 1. Madura H. (red.): Pomiary termowizyjne w praktyce, Wydawnictwo PAK, Warszawa, 2004. 176 str., ISBN 83-87982-26-1
• 2. Minkina W.: Pomiary termowizyjne – przyrządy i metody. Wydawnictwo Politechniki Częstochowskiej, Częstochowa 2004, 243 str., ISBN 83-7193-237-5.
• 3. Minkina W., Dudzik S.: Infrared thermography – errors and uncertainties. John Wiley & Sons Ltd, Chichester 2009 r., 192 pp, ISBN 978-0-470-74718-6.
• 4. Wiecek B., G. De Mey G.: Termowizja w podczerwieni, podstawy i zastosowania. Wydawnictwo PAK, 2011.
• 5. Więcek B., Pacholski K., Olbrycht R., Strąkowski R., Kałuża M., Borecki M., Wittchen: Termografia i spektrometria w podczerwieni. Zastosowanie przemysłowe, Wyd. Naukowe PWN, Warszawa, 2017.
• NDT, applications
• 1. Dudzik S.: Wyznaczanie głębokości defektów materiałowych z zastosowaniem aktywnej termografii dynamicznej i sztucznych sieci neuronowych, Wydawnictwo Politechniki Częstochowskiej, Częstochowa, 2013, ISBN 978-83-7194-572, ISSN 0860-5017
• 2. Fidali M.: Metodyka termograficznej diagnostyki obiektów technicznych, Wyd. Naukowe Instytutu Technologii i Eksploatacji – PIB, Radom, 2013 _
• 3. Minkina W. (e_d.): Wybrane problemy współczesnej termografii i termometrii w podczerwieni, Wyd. Politechniki Częstochowskiej, Częstochowa 2011, ISBN 978-83-7193-512-1, ISSN 0860-5017
• 4. Suszyński Z.: Termofalowe metody badania materiałów i przyrządów elektronicznych, Politechnika Koszalińska, 2013.
• Buildings
• 1. Wróbel A. (ed.): Ilościowe określanie cieplnych właściwości przegród budowlanych z wykorzystaniem techniki termograficznej, Wydawnictwa Naukowe/Akademia Górniczo-Hutnicza, 2011, ISBN: 978-83-7464-393-1.
• 2. Nowak H.: Zastosowanie badań termowizyjnych w budownictwie. Oficyna Wydawnicza Politechniki Wrocławskiej, Wrocław, 201.
• Medical thermography
• 1. Jung A., Żuber J.: Thermographic Methods in Medical Diagnostics, Medpress, Warszawa, 1998.
• 2. Nowakowski A. (ed.): Postępy termografii – aplikacje medyczne 235 stron, Wyd. Gdańskie, 2001.
• 3. Nowakowski A.(red.): Rozwój diagnostyki termicznej metodami detekcji podczerwieni (ilościowa diagnostyka ran oparzeniowych i inne aplikacje. Akademicka Oficyna wydawnicza EXIT, Warszawa, 2009.
• 4. Ring F., Jung A., Żuber J.: Infrared Imaging: A Casebook in Clinical Medicine, IOP Publishing Ltd., Bristol, 2015.
• IR detectors
• 1. Rogalski A.: Infrared Detectors, Second Edition, by CRC Press 2010, (898 pages).
• 2. Rogalski A. (editor, contribution 50%), Infrared Photon Detectors, SPIE Optical Engineering Press, Bellingham, Washington USA,1995 (644p.).
• 3. Rogalski A.: Infrared Detectors: Developments, SPIE Milestone Series, SPIE Optical Engineering Press, Bellingham, 2004 (830 pages).
• 4. Piotrowski J., Rogalski A.: High-Operating Temperature Infrared Photodetectors, SPIE Press, Bellingham, 2007 (242 pages).
• 5. Rogalski A.: Infrared and Terahertz Detectors, Third Edition, by CRC Press 2019, (1044 pages) ISBN 9781138198005

Uwagi

PL

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).