Location: Soil and Water Management ResearchTitle: Performance of a wireless sensor network for crop monitoring and irrigation control) Author
Submitted to: ASABE Annual International Meeting
Publication Type: Proceedings
Publication Acceptance Date: 7/25/2012
Publication Date: 7/29/2012
Citation: O'shaughnessy, S.A., Evett, S.R., Colaizzi, P.D., Howell, T.A. 2012. Performance of a wireless sensor network for crop monitoring and irrigation control. In:ASABE Annual International Meeting, July 29-August 1, 2012, Dallas,TX. Paper No.12-1338246. Interpretive Summary: In previous research studies involving automatic irrigation scheduling and control of center pivot systems, wired sensors, multiplexers, and data loggers were used to accomplish the remote monitoring of crop water stress and control of crop water use efficiency. While the reliability of data collection with wired systems is relatively high, often times, wired systems are not practical for agricultural applications. Their limitations include a restricted area of coverage, inflexibility in changing the network layout, and the cost and maintenance of the cabling and intermediate data logging units. In this study, a wireless sensor network comprised of infrared thermometers, multiband radiometers, and a global positioning sensor (GPS) unit were used to monitor crop water stress, schedule irrigations, and control a six-span center pivot system. While there were intermittent issues with data dropout from the wireless sensors, treatment plots that were irrigated with automatic methods produced grain yields and water use efficiency that was similar to those produced from manual methods of irrigation scheduling using direct soil water measurements. These results indicate that it is possible to control automatic irrigation scheduling with a wireless sensor network system on a large-sized pivot field.
Technical Abstract: Robust automatic irrigation scheduling has been demonstrated using wired sensors and sensor network systems with subsurface drip and moving irrigation systems. However, there are limited studies that report on crop yield and water use efficiency resulting from the use of wireless networks to automatically schedule and control irrigations. In this study, a multinode wireless sensor network (WSN) system was mounted onto a six-span center pivot outfitted with a commercial variable rate irrigation (VRI) system. Data from the WSN was used for automatic irrigation scheduling and irrigation control to produce an early hybrid variety of grain sorghum in 2011. An integrated crop water stress index (CWSI) was used as a threshold to schedule irrigations. Half of the center pivot field was divided into six sectors, three were irrigated using automatic control, and three were irrigated based on weekly direct soil water measurements. Wireless sensor nodes, i.e. infrared thermometers, GPS unit, and multiband radiometers were integrated onto the center pivot system and field below. The WSN system was scaled to 40 different nodes and was operational throughout 98% of the growing season. An assessment of the reliability of the nodes, demonstrated that delivery rates for data packets from the different nodes ranged between 90% to 98%. Automatic irrigation scheduling succeeded in producing mean dry grain yields and controlling crop water use efficiency (WUE) at levels that were similar to those from soil water based irrigation scheduling. Average seasonal integrated crop water stress indices were negatively correlated to irrigation treatment amounts in both the manual and automatic plots and correlated well to crop water use. These results demonstrate that it is feasible to use WSN systems for irrigation management on a field scale level.