TY - JOUR
T1 - Data-driven agriculture and sustainable farming
T2 - friends or foes?
AU - Rozenstein, Offer
AU - Cohen, Yafit
AU - Alchanatis, Victor
AU - Behrendt, Karl
AU - Bonfil, David J.
AU - Eshel, Gil
AU - Harari, Ally
AU - Harris, W. Edwin
AU - Klapp, Iftach
AU - Laor, Yael
AU - Linker, Raphael
AU - Paz-Kagan, Tarin
AU - Peets, Sven
AU - Rutter, S. Mark
AU - Salzer, Yael
AU - Lowenberg-DeBoer, James
N1 - Publisher Copyright:
© 2023, The Author(s).
PY - 2024/2/1
Y1 - 2024/2/1
N2 - Sustainability in our food and fiber agriculture systems is inherently knowledge intensive. It is more likely to be achieved by using all the knowledge, technology, and resources available, including data-driven agricultural technology and precision agriculture methods, than by relying entirely on human powers of observation, analysis, and memory following practical experience. Data collected by sensors and digested by artificial intelligence (AI) can help farmers learn about synergies between the domains of natural systems that are key to simultaneously achieve sustainability and food security. In the quest for agricultural sustainability, some high-payoff research areas are suggested to resolve critical legal and technical barriers as well as economic and social constraints. These include: the development of holistic decision-making systems, automated animal intake measurement, low-cost environmental sensors, robot obstacle avoidance, integrating remote sensing with crop and pasture models, extension methods for data-driven agriculture, methods for exploiting naturally occurring Genotype x Environment x Management experiments, innovation in business models for data sharing and data regulation reinforcing trust. Public funding for research is needed in several critical areas identified in this paper to enable sustainable agriculture and innovation.
AB - Sustainability in our food and fiber agriculture systems is inherently knowledge intensive. It is more likely to be achieved by using all the knowledge, technology, and resources available, including data-driven agricultural technology and precision agriculture methods, than by relying entirely on human powers of observation, analysis, and memory following practical experience. Data collected by sensors and digested by artificial intelligence (AI) can help farmers learn about synergies between the domains of natural systems that are key to simultaneously achieve sustainability and food security. In the quest for agricultural sustainability, some high-payoff research areas are suggested to resolve critical legal and technical barriers as well as economic and social constraints. These include: the development of holistic decision-making systems, automated animal intake measurement, low-cost environmental sensors, robot obstacle avoidance, integrating remote sensing with crop and pasture models, extension methods for data-driven agriculture, methods for exploiting naturally occurring Genotype x Environment x Management experiments, innovation in business models for data sharing and data regulation reinforcing trust. Public funding for research is needed in several critical areas identified in this paper to enable sustainable agriculture and innovation.
KW - Data integration
KW - Data ownership
KW - Decision support systems
KW - Privacy
KW - Regenerative agriculture
KW - Research funding
KW - Research needs
UR - http://www.scopus.com/inward/record.url?scp=85167918430&partnerID=8YFLogxK
U2 - 10.1007/s11119-023-10061-5
DO - 10.1007/s11119-023-10061-5
M3 - Article
AN - SCOPUS:85167918430
SN - 1385-2256
VL - 25
SP - 520
EP - 531
JO - Precision Agriculture
JF - Precision Agriculture
IS - 1
ER -