A rover includes a base having wheels and a propulsion system coupled to the wheels to propel the rover around a field. A tower is coupled to the base and extends over the base. Sensors are set on the tower and the base and are configured to sense environmental conditions around the rover at different elevations. A computing system includes a processor and memory. The memory is configured to receive measured data from the sensors and determine an amount and manner of water to be dispensed on plant life in the field.

A container for fluid, including a container housing, a button atop the container housing, an overcap at least partially enclosing the button, the overcap having an orifice to allow flow of the fluid and an aperture for facilitating actuation of the button, the overcap further having a projecting member, and a fitting member disposed at least partially circumferentially about the container.

According to one aspect, a fluid dispensing device comprises a housing and a fluid moving device associated with the housing. The housing includes an interior surface defining a passage extending at least between an emission end and at least one aperture configured to facilitate entry of a fluid into the passage. The housing further includes a mounting apparatus adjacent the aperture and adapted to receive a fluid source. The fluid moving device is operable to develop air flow in the passage, wherein the aperture is disposed downstream of the fluid moving device and upstream of the emission end.

A rover includes a base having wheels and a propulsion system coupled to the wheels to propel the rover around a field. A tower is coupled to the base and extends over the base. Sensors are set on the tower and the base and are configured to sense environmental conditions around the rover at different elevations. A computing system includes a processor and memory. The memory is configured to receive measured data from the sensors and determine an amount and manner of water to be dispensed on plant life in the field.

A method of treating a tree, the method includes positioning a temperature transmitter proximate to the tree; and lowering a treatment unit over the tree and the temperature transmitter, the treatment unit configured to move independently from a supply unit, the treatment unit in fluid communication with the supply unit.

A rover includes a base having wheels and a propulsion system coupled to the wheels to propel the rover around a field. A tower is coupled to the base and extends over the base. Sensors are set on the tower and the base and are configured to sense environmental conditions around the rover at different elevations. A computing system includes a processor and memory. The memory is configured to receive measured data from the sensors and determine an amount and manner of water to be dispensed on plant life in the field.

A rover includes a base having wheels and a propulsion system coupled to the wheels to propel the rover around a field. A tower is coupled to the base and extends over the base. Sensors are set on the tower and the base and are configured to sense environmental conditions around the rover at different elevations. A computing system includes a processor and memory. The memory is configured to receive measured data from the sensors and determine an amount and manner of water to be dispensed on plant life in the field.

A tree canopy treatment system includes: a supply unit configured to heat a fluid; and a treatment unit in fluid communication with the supply unit, the treatment unit configured to move independently from the supply unit. A method of treating a tree includes positioning a temperature transmitter proximate to the tree; and lowering a treatment unit over the tree and the temperature transmitter, the treatment unit configured to move independently from a supply unit, the treatment unit in fluid communication with the supply unit.

A method includes receiving a treatment temperature from a user device; positioning a tree within a treatment region of a canopy; flowing a fluid from a hot fluid generating system to the canopy; spraying the fluid from the hot fluid generating system into the treatment region of the canopy; and selectively enabling and disabling a fluid flow from the hot fluid generating system to the canopy to maintain the treatment temperature within the treatment region of the canopy.

A control system for a canopy to treat plants is disclosed. In one implementation according to examples of the present disclosure, a method comprises receiving a treatment temperature from a user device. The method further comprises flowing a fluid from a hot fluid generating system to a canopy. The method further comprises selectively enabling and disabling a fluid flow from the hot fluid generating system to the canopy to maintain the treatment temperature within the canopy.