Monitoring spray drift in aerial spray application based on infrared thermal imaging technology

•A first study to measure pesticide drift distribution using thermal imaging.•Tiny thermal differences during spray application had been measured.•The drift distribution and spray range could be detected.•The testing results had well agreement with the water-sensitive paper method. The pesticide dri...

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Vydané v:	Computers and electronics in agriculture Ročník 121; s. 135 - 140
Hlavní autori:	Jiao, Leizi, Dong, Daming, Feng, Haikuan, Zhao, Xiande, Chen, Liping
Médium:	Journal Article
Jazyk:	English
Vydavateľské údaje:	Elsevier B.V 01.02.2016
Predmet:	Aerial spray application Aerials algorithms Drift Droplets humans image analysis Infrared Infrared thermal imaging monitoring Pesticides Spray drift Sprayers spraying Sprays Thermal imaging Water-sensitive paper Spray drift Water-sensitive paper Aerial spray application Infrared thermal imaging
ISSN:	0168-1699, 1872-7107
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Abstract	•A first study to measure pesticide drift distribution using thermal imaging.•Tiny thermal differences during spray application had been measured.•The drift distribution and spray range could be detected.•The testing results had well agreement with the water-sensitive paper method. The pesticide drift in aerial spray applications is harmful both to environment and human beings but hard to be measured. We demonstrated a new method for real-time evaluation of pesticide drift which used infrared thermal imaging technology to detect the thermal differences before and after spraying process and then measured the range and concentration distribution of droplets. The drift distribution and spray range are detected using infrared thermal imaging system combined with image processing algorithms. The experiments were carried out in both ground spray and aerial spray applications. The results showed that this method had the ability to detect the tiny thermal differences during spray application and thus to monitor the aerial drifts. Furthermore, the testing results using this method had well agreement with the water-sensitive paper method. Therefore, it is verified that infrared thermal imaging method combined with infrared image processing algorithms can be used to monitor the pesticide drift in aerial spray application with advantages of fast, non-contact and able to realize real-time measurement.
AbstractList	The pesticide drift in aerial spray applications is harmful both to environment and human beings but hard to be measured. We demonstrated a new method for real-time evaluation of pesticide drift which used infrared thermal imaging technology to detect the thermal differences before and after spraying process and then measured the range and concentration distribution of droplets. The drift distribution and spray range are detected using infrared thermal imaging system combined with image processing algorithms. The experiments were carried out in both ground spray and aerial spray applications. The results showed that this method had the ability to detect the tiny thermal differences during spray application and thus to monitor the aerial drifts. Furthermore, the testing results using this method had well agreement with the water-sensitive paper method. Therefore, it is verified that infrared thermal imaging method combined with infrared image processing algorithms can be used to monitor the pesticide drift in aerial spray application with advantages of fast, non-contact and able to realize real-time measurement. •A first study to measure pesticide drift distribution using thermal imaging.•Tiny thermal differences during spray application had been measured.•The drift distribution and spray range could be detected.•The testing results had well agreement with the water-sensitive paper method. The pesticide drift in aerial spray applications is harmful both to environment and human beings but hard to be measured. We demonstrated a new method for real-time evaluation of pesticide drift which used infrared thermal imaging technology to detect the thermal differences before and after spraying process and then measured the range and concentration distribution of droplets. The drift distribution and spray range are detected using infrared thermal imaging system combined with image processing algorithms. The experiments were carried out in both ground spray and aerial spray applications. The results showed that this method had the ability to detect the tiny thermal differences during spray application and thus to monitor the aerial drifts. Furthermore, the testing results using this method had well agreement with the water-sensitive paper method. Therefore, it is verified that infrared thermal imaging method combined with infrared image processing algorithms can be used to monitor the pesticide drift in aerial spray application with advantages of fast, non-contact and able to realize real-time measurement.
Author	Zhao, Xiande Jiao, Leizi Dong, Daming Chen, Liping Feng, Haikuan
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Snippet	•A first study to measure pesticide drift distribution using thermal imaging.•Tiny thermal differences during spray application had been measured.•The drift... The pesticide drift in aerial spray applications is harmful both to environment and human beings but hard to be measured. We demonstrated a new method for...
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SubjectTerms	Aerial spray application Aerials algorithms Drift Droplets humans image analysis Infrared Infrared thermal imaging monitoring Pesticides Spray drift Sprayers spraying Sprays Thermal imaging Water-sensitive paper
Title	Monitoring spray drift in aerial spray application based on infrared thermal imaging technology
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