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Enabling better global research outcomes in soil, plant & environmental monitoring.


DroughtSpotter is a fully automated gravimetric platform, made to assess the transpiration dynamics of plants with a precision of up to 1 g.

The integrated irrigation units allow precise and reproducible water application for drought stress or related experiments requiring accurate control of water volume to 1 ml. DroughtSpotter can easily be adjusted to accommodate various pot sizes and pot designs. Watering protocols or drought scenarios can quickly and easily be customised via the DroughtSpotter software web interface. The designed irrigation events maintain the target weight of each individual plant pot according to the researchers’ experimental protocol and provide plant transpiration rates at high temporal resolution calculated by the loss of weight. Combined with PlantEye’s growth measurements, the weight increase due to plant biomass accumulation can also be considered.

DroughtSpotter was designed to the IP65 standard to work in controlled environments and in greenhouses. The system is built with separate tables, so-called units, that can accommodate up to 24 plants per unit. Central valves enable the user to shut down water supplies for maintenance or whenever experiments are not running. DroughtSpotter units have an integrated drainage system for preventing damage if and when the soil is over watered. As a solid-state system without any moving parts, DroughtSpotter needs very little maintenance and is not susceptible to hardware failures.

Dimensions: 1,000 mm x 700 mm x 650 mm
Irrigation Precision: 1 ml
Weighing Accuracy: 0.02%
Scale Range: 1 – 50 kg


The beauty of using gravimetric measurements to assess transpiration rates for drought research lies in the simplicity of the method and its ability to provide you with incorruptible and resilient data. Although simple, it is nonetheless a very labour intensive protocol! Spurred into action by this challenge, we decided to engineer a solution that was simple but professional and specially made for high-throughput phenotyping. Why professional? Homemade solutions have provided good results and have been proven to be useful for drought research and breeding, but for those who want to focus less on technical development and more on research, DroughtSpotter is a better tool. Design your drought scenarios with our software, position your plants on the system, and all of your measurements and irrigations will be performed fully automated.

What is drought? More than one definition

Research on drought stress has strongly increased over the last decade, as water shortage is one of the key limiting factors in global crop production. Many breeding and scientific projects aim to deliver knowledge, traits and chemical agents that will help to provide better resistance to drought stress. However, the term “drought stress” is broadly defined and covers many different ways that plants might be affected. For instance, drought stress differs depending upon the site of the action, its strength and its dynamics, which may be integrated by plants and might also trigger different coping mechanisms in plants for dealing with the stress. This fact has to be considered in experimental designs and breeding programs, and the mode of stress has to be controlled and reproducible.

Assess transpiration dynamics over the day

Plants adjust their transpiration rates dynamically within minutes towards environmental parameters like vapour pressure deficit (VPD), soil moisture, light, CO2 and others. Despite the fact that transpiration is dynamically controlled by soil moisture, vapour pressure deficit and other environmental parameters, transpiration rates are typically only measured on a daily basis. To better understand the dynamics of these processes, DroughtSpotter tracks transpiration in intervals of 10 minutes or less. Typically, such accuracy would require investment in either a lot of labour force or expensive conveyor belts, and researchers still would not be able to achieve the same precision (down to 1ml in high temporal resolution) as they could with DroughtSpotter.

Flexible Experimental Protocols and weighing ranges

Depending on what you want to test, the pot size, or the number of plants per pot, the way you want to irrigate may vary strongly. DroughtSpotter offers different watering modes that allow the user to apply specific behaviour to each pot. Besides holding a predefined target weight, plants can be given fixed dosages of water, or the conditions of a specific pot can be replicated for all plants as in the field. For all events, you can define whether watering is performed at defined times, or even dynamically, whenever a certain minimum threshold is reached. With tool-free adjustable irrigation tubes, pots sizes from 10 to 50 cm can easily be handled. DroughtSpotter can be built to accommodate pots from 1 kg to 50 kg large-scale containers that can be placed either on tables or directly on the ground. The system can also be used outdoors in combination with Phenospex FieldScan in order to measure the drought performance of various genotypes in field conditions.

Control edge effects on each individual plant

Everybody knows how difficult it is to control and reproduce a drydown, since even in climate chambers, environmental conditions are not homogeneous. Border effects, different growth rates and many other factors influence the soil water content to which the plants react. DroughtSpotter takes care of this by tracking and controlling the water status of plants using its precision irrigation system, which can deliver water in 1 ml increments for each individual plant, and by monitoring environmental conditions, such as temperature and light intensity, that affect transpiration. Hence, even the transpiration rates of small plants can be controlled and tracked, thereby keeping variability low. DroughtSpotter is easily combined with data loggers from various suppliers to monitor climate conditions (T, RH, PAR, CO2) and manage data in one central place.