Pre-harvest weed mapping of Cirsium arvense in wheat and barley with off-the-shelf UAVs

Research output: Contribution to journalJournal articleResearchpeer-review

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Pre-harvest weed mapping of Cirsium arvense in wheat and barley with off-the-shelf UAVs. / Rasmussen, J.; Nielsen, J.; Streibig, J. C.; Jensen, J. E.; Pedersen, K. S.; Olsen, S. I.

In: Precision Agriculture, Vol. 20, No. 5, 2019, p. 983–999.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Rasmussen, J, Nielsen, J, Streibig, JC, Jensen, JE, Pedersen, KS & Olsen, SI 2019, 'Pre-harvest weed mapping of Cirsium arvense in wheat and barley with off-the-shelf UAVs', Precision Agriculture, vol. 20, no. 5, pp. 983–999. https://doi.org/10.1007/s11119-018-09625-7

APA

Rasmussen, J., Nielsen, J., Streibig, J. C., Jensen, J. E., Pedersen, K. S., & Olsen, S. I. (2019). Pre-harvest weed mapping of Cirsium arvense in wheat and barley with off-the-shelf UAVs. Precision Agriculture, 20(5), 983–999. https://doi.org/10.1007/s11119-018-09625-7

Vancouver

Rasmussen J, Nielsen J, Streibig JC, Jensen JE, Pedersen KS, Olsen SI. Pre-harvest weed mapping of Cirsium arvense in wheat and barley with off-the-shelf UAVs. Precision Agriculture. 2019;20(5):983–999. https://doi.org/10.1007/s11119-018-09625-7

Author

Rasmussen, J. ; Nielsen, J. ; Streibig, J. C. ; Jensen, J. E. ; Pedersen, K. S. ; Olsen, S. I. / Pre-harvest weed mapping of Cirsium arvense in wheat and barley with off-the-shelf UAVs. In: Precision Agriculture. 2019 ; Vol. 20, No. 5. pp. 983–999.

Bibtex

@article{3a91de19e8144cedb2f1e74b6b0f688c,
title = "Pre-harvest weed mapping of Cirsium arvense in wheat and barley with off-the-shelf UAVs",
abstract = "The paper describes a procedure to detect green weeds in pre-harvest cereals using images from off-the-shelf UAVs with RGB cameras. All images used to develop and test the detection procedure were from fields infested with Cirsium arvense and in consequence, the procedure is called Thistle Tool. Thistle tool, however, may also detect other green weeds and may also be useful in post-harvest stubble. C. arvense maps may be used for pre-harvest glyphosate spraying in countries allowing this practice or used post-harvest or in the following year because C. arvense patches are relatively stable from one year to the next. The detection procedure exclusively used colour analysis and discriminated green and senescent vegetation without the ability to discriminate between green plant species. Thistle Tool divides images into patches of 1 m2 irrespective of the flight altitude, and calculates a classifier called TopMaxExG used for visual threshold editing. Patches are classified into two categories: with or without green vegetation. When C. arvense was the main contributor to green vegetation in pre-harvest cereals, 92–97% patches were classified correctly under varying environmental conditions with different consumer-grade RGB cameras. With small consumer UAVs, such as Phantom 3 or 4, it is possible to map 10 ha in 20 min at 40 m flight altitude, which corresponds to the duration of one battery. This study has demonstrated that UAV imagery is practically manageable for C. arvense mapping. Barriers to reach the end user and pros-and-cons of using more advance weed detection algorithms are discussed.",
keywords = "Cereals, Image analysis, Perennial weeds, Site-specific weed management, Weed detection",
author = "J. Rasmussen and J. Nielsen and Streibig, {J. C.} and Jensen, {J. E.} and Pedersen, {K. S.} and Olsen, {S. I.}",
year = "2019",
doi = "10.1007/s11119-018-09625-7",
language = "English",
volume = "20",
pages = "983–999",
journal = "Precision Agriculture",
issn = "1385-2256",
publisher = "Springer",
number = "5",

}

RIS

TY - JOUR

T1 - Pre-harvest weed mapping of Cirsium arvense in wheat and barley with off-the-shelf UAVs

AU - Rasmussen, J.

AU - Nielsen, J.

AU - Streibig, J. C.

AU - Jensen, J. E.

AU - Pedersen, K. S.

AU - Olsen, S. I.

PY - 2019

Y1 - 2019

N2 - The paper describes a procedure to detect green weeds in pre-harvest cereals using images from off-the-shelf UAVs with RGB cameras. All images used to develop and test the detection procedure were from fields infested with Cirsium arvense and in consequence, the procedure is called Thistle Tool. Thistle tool, however, may also detect other green weeds and may also be useful in post-harvest stubble. C. arvense maps may be used for pre-harvest glyphosate spraying in countries allowing this practice or used post-harvest or in the following year because C. arvense patches are relatively stable from one year to the next. The detection procedure exclusively used colour analysis and discriminated green and senescent vegetation without the ability to discriminate between green plant species. Thistle Tool divides images into patches of 1 m2 irrespective of the flight altitude, and calculates a classifier called TopMaxExG used for visual threshold editing. Patches are classified into two categories: with or without green vegetation. When C. arvense was the main contributor to green vegetation in pre-harvest cereals, 92–97% patches were classified correctly under varying environmental conditions with different consumer-grade RGB cameras. With small consumer UAVs, such as Phantom 3 or 4, it is possible to map 10 ha in 20 min at 40 m flight altitude, which corresponds to the duration of one battery. This study has demonstrated that UAV imagery is practically manageable for C. arvense mapping. Barriers to reach the end user and pros-and-cons of using more advance weed detection algorithms are discussed.

AB - The paper describes a procedure to detect green weeds in pre-harvest cereals using images from off-the-shelf UAVs with RGB cameras. All images used to develop and test the detection procedure were from fields infested with Cirsium arvense and in consequence, the procedure is called Thistle Tool. Thistle tool, however, may also detect other green weeds and may also be useful in post-harvest stubble. C. arvense maps may be used for pre-harvest glyphosate spraying in countries allowing this practice or used post-harvest or in the following year because C. arvense patches are relatively stable from one year to the next. The detection procedure exclusively used colour analysis and discriminated green and senescent vegetation without the ability to discriminate between green plant species. Thistle Tool divides images into patches of 1 m2 irrespective of the flight altitude, and calculates a classifier called TopMaxExG used for visual threshold editing. Patches are classified into two categories: with or without green vegetation. When C. arvense was the main contributor to green vegetation in pre-harvest cereals, 92–97% patches were classified correctly under varying environmental conditions with different consumer-grade RGB cameras. With small consumer UAVs, such as Phantom 3 or 4, it is possible to map 10 ha in 20 min at 40 m flight altitude, which corresponds to the duration of one battery. This study has demonstrated that UAV imagery is practically manageable for C. arvense mapping. Barriers to reach the end user and pros-and-cons of using more advance weed detection algorithms are discussed.

KW - Cereals

KW - Image analysis

KW - Perennial weeds

KW - Site-specific weed management

KW - Weed detection

UR - http://www.scopus.com/inward/record.url?scp=85058479584&partnerID=8YFLogxK

U2 - 10.1007/s11119-018-09625-7

DO - 10.1007/s11119-018-09625-7

M3 - Journal article

AN - SCOPUS:85058479584

VL - 20

SP - 983

EP - 999

JO - Precision Agriculture

JF - Precision Agriculture

SN - 1385-2256

IS - 5

ER -

ID: 213856806