REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZE

REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZE

Wildfires cause large scale devastation to human settlements and forests every year and their frequency and severity is on the rise. A major reason for this devastation is the significant delay in their detection due to their remote locations in forests. To mitigate this, a constellation of nanosate...

Full description

Bibliographic Details
Main Authors: S. B. Shah, T. Grübler, L. Krempel, S. Ernst, F. Mauracher, S. Contractor
Format: Article
Language:English
Published: Copernicus Publications 2019-09-01
Series:The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences
Online Access:https://www.int-arch-photogramm-remote-sens-spatial-inf-sci.net/XLII-2-W16/209/2019/isprs-archives-XLII-2-W16-209-2019.pdf
id doaj-840707577c1c498a90aa270b81948402
record_format Article
spelling doaj-840707577c1c498a90aa270b819484022020-11-25T02:01:05ZengCopernicus PublicationsThe International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences1682-17502194-90342019-09-01XLII-2-W1620921310.5194/isprs-archives-XLII-2-W16-209-2019REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZES. B. Shah0T. Grübler1L. Krempel2S. Ernst3F. Mauracher4S. Contractor5OroraTech, Orbital Oracle Technologies GmbH, 82205 Gilching n. Munich, GermanyOroraTech, Orbital Oracle Technologies GmbH, 82205 Gilching n. Munich, GermanyOroraTech, Orbital Oracle Technologies GmbH, 82205 Gilching n. Munich, GermanyOroraTech, Orbital Oracle Technologies GmbH, 82205 Gilching n. Munich, GermanyOroraTech, Orbital Oracle Technologies GmbH, 82205 Gilching n. Munich, GermanyOroraTech, Orbital Oracle Technologies GmbH, 82205 Gilching n. Munich, GermanyWildfires cause large scale devastation to human settlements and forests every year and their frequency and severity is on the rise. A major reason for this devastation is the significant delay in their detection due to their remote locations in forests. To mitigate this, a constellation of nanosatellites in Low Earth Orbit (LEO) equipped with multi-spectral visible to Infrared (IR) cameras is proposed leveraging the modular and affordable architecture of CubeSats. Coupled with the payload design, meticulously planned constellation and a ground support system, all surface points on the planet will be revisited at least once in an hour. Capturing a surface location with a high resolution in MidWavelength Infrared (MWIR) and LongWavelength Infrared (LWIR) allows a precise estimation of thermal output of the surface. Simulations indicate that a fire of about four hundred square meters can be easily detected from this satellite payload. Through onboard data processing, wildfires can be already detected in space, minimizing bandwidth requirements for real-time alerts. This enables an early wildfire warning within 30 min by utilizing existing satellite internet networks. Additionally, compressed raw images will be transmitted on fixed ground station passes to provide a global thermal data updated every 90 min. The near real-time multi-spectral data provides opportunity for several other applications like weather forecasting besides wildfire detection.https://www.int-arch-photogramm-remote-sens-spatial-inf-sci.net/XLII-2-W16/209/2019/isprs-archives-XLII-2-W16-209-2019.pdf
collection DOAJ
language English
format Article
sources DOAJ
author S. B. Shah
T. Grübler
L. Krempel
S. Ernst
F. Mauracher
S. Contractor
spellingShingle S. B. Shah
T. Grübler
L. Krempel
S. Ernst
F. Mauracher
S. Contractor
REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZE
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences
author_facet S. B. Shah
T. Grübler
L. Krempel
S. Ernst
F. Mauracher
S. Contractor
author_sort S. B. Shah
title REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZE
title_short REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZE
title_full REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZE
title_fullStr REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZE
title_full_unstemmed REAL-TIME WILDFIRE DETECTION FROM SPACE – A TRADE-OFF BETWEEN SENSOR QUALITY, PHYSICAL LIMITATIONS AND PAYLOAD SIZE
title_sort real-time wildfire detection from space – a trade-off between sensor quality, physical limitations and payload size
publisher Copernicus Publications
series The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences
issn 1682-1750
2194-9034
publishDate 2019-09-01
description Wildfires cause large scale devastation to human settlements and forests every year and their frequency and severity is on the rise. A major reason for this devastation is the significant delay in their detection due to their remote locations in forests. To mitigate this, a constellation of nanosatellites in Low Earth Orbit (LEO) equipped with multi-spectral visible to Infrared (IR) cameras is proposed leveraging the modular and affordable architecture of CubeSats. Coupled with the payload design, meticulously planned constellation and a ground support system, all surface points on the planet will be revisited at least once in an hour. Capturing a surface location with a high resolution in MidWavelength Infrared (MWIR) and LongWavelength Infrared (LWIR) allows a precise estimation of thermal output of the surface. Simulations indicate that a fire of about four hundred square meters can be easily detected from this satellite payload. Through onboard data processing, wildfires can be already detected in space, minimizing bandwidth requirements for real-time alerts. This enables an early wildfire warning within 30 min by utilizing existing satellite internet networks. Additionally, compressed raw images will be transmitted on fixed ground station passes to provide a global thermal data updated every 90 min. The near real-time multi-spectral data provides opportunity for several other applications like weather forecasting besides wildfire detection.
url https://www.int-arch-photogramm-remote-sens-spatial-inf-sci.net/XLII-2-W16/209/2019/isprs-archives-XLII-2-W16-209-2019.pdf
work_keys_str_mv AT sbshah realtimewildfiredetectionfromspaceatradeoffbetweensensorqualityphysicallimitationsandpayloadsize
AT tgrubler realtimewildfiredetectionfromspaceatradeoffbetweensensorqualityphysicallimitationsandpayloadsize
AT lkrempel realtimewildfiredetectionfromspaceatradeoffbetweensensorqualityphysicallimitationsandpayloadsize
AT sernst realtimewildfiredetectionfromspaceatradeoffbetweensensorqualityphysicallimitationsandpayloadsize
AT fmauracher realtimewildfiredetectionfromspaceatradeoffbetweensensorqualityphysicallimitationsandpayloadsize
AT scontractor realtimewildfiredetectionfromspaceatradeoffbetweensensorqualityphysicallimitationsandpayloadsize
_version_ 1724958961848811520

Similar Items