Abstract: One variation of a method for automating transfer of plants within an agricultural facility includes: dispatching a loader to autonomously deliver a first module—defining a first array of plant slots at a first density and loaded with a first set of plants at a first growth stage—from a first grow location within an agricultural facility to a transfer station within the agricultural facility; dispatching the loader to autonomously deliver a second module—defining a second array of plant slots at a second density less than the first density and empty of plants—to the transfer station; recording a module-level optical scan of the first module; extracting a viability parameter of the first set of plants from features detected in the module-level optical scan; and if the viability parameter falls outside of a target viability range, rejecting transfer of the first set of plants from the first module.

Abstract: One variation of a method for automating transfer of plants within an agricultural facility includes: dispatching a loader to autonomously deliver a first module—defining a first array of plant slots at a first density and loaded with a first set of plants at a first growth stage—from a first grow location within an agricultural facility to a transfer station within the agricultural facility; dispatching the loader to autonomously deliver a second module—defining a second array of plant slots at a second density less than the first density and empty of plants—to the transfer station; recording a module-level optical scan of the first module; extracting a viability parameter of the first set of plants from features detected in the module-level optical scan; and if the viability parameter falls outside of a target viability range, rejecting transfer of the first set of plants from the first module.

Abstract: One variation of a method for automatically redistributing plants throughout an agricultural facility includes, at a mobile robotic system: delivering a first module—defining a first array of plant slots at a first density and loaded with a first set of plants in approximately a second growth stage—from a grow area within a facility to a transfer station within the facility; delivering a second module—located within the facility and defining a second array of plant slots at a second density less than the first density—to the transfer station; and following transfer of a first subset of plants from the first array of plant slots in the first module into the second array of plant slots in the second module at the transfer station, delivering the second module to the grow area in the facility.

Abstract: One variation of a method for automating transfer of plants within an agricultural facility includes: dispatching a loader to autonomously deliver a first module—defining a first array of plant slots at a first density and loaded with a first set of plants at a first growth stage—from a first grow location within an agricultural facility to a transfer station within the agricultural facility; dispatching the loader to autonomously deliver a second module—defining a second array of plant slots at a second density less than the first density and empty of plants—to the transfer station; recording a module-level optical scan of the first module; extracting a viability parameter of the first set of plants from features detected in the module-level optical scan; and if the viability parameter falls outside of a target viability range, rejecting transfer of the first set of plants from the first module.

Abstract: One variation of method for monitoring growth of plants within a facility includes: aggregating global ambient data recorded by a suite of fixed sensors, arranged proximal a grow area within the facility, at a first frequency during a grow period; extracting interim outcomes of a set of plants, occupying a module in the grow area, from module-level images recorded by a mover at a second frequency less than the first frequency while interfacing with the module during the period of time; dispatching the mover to autonomously deliver the module to a transfer station; extracting interim outcomes of the set of plants from plant-level images recorded by the transfer station while sequentially transferring plants out of the module at the conclusion of the grow period; and deriving relationships between ambient conditions, interim outcomes, and final outcomes from a corpus of plant records associated with plants grown in the facility.

Abstract: A mobile robot can include an elongated body no more than two meters high and no more than one meter wide; at least one securable container; at least one depth sensor mounted near or at the top of the body to have a downward field of view (FOV), the at least one depth sensor comprising a video camera in combination with another distance sensor; and a drive mechanism configured to provide linear and rotational movement for the robot.

Abstract: A mobile robot can include an elongated body disposed in a vertical direction and having an approximately cylindrical shape; a user interface within an upper 20 centimeters of the body and inclined to be accessible from above and in front of the robot; at least one depth sensor that is mounted at or near a top of the body and having at least one field of view; at least one container formed within the body; and a drive mechanism disposed within the body.

Abstract: A system can include at least one robot configured to autonomously navigate from a first location to a destination zone, the at least one robot having a generally cylindrical shape and including a storage container for storing at least one item for delivery, a plurality of image based depth sensor mounted proximate a top end of the robot, and a controller configured to navigate to the destination zone and to authenticate a delivery target for the item.

Abstract: A mobile robot can include an elongated body no more than two meters high and no more than one meter wide; at least one securable container; at least one depth sensor mounted near or at the top of the body to have a downward field of view (FOV), the at least one depth sensor comprising a video camera in combination with another distance senor; and a drive mechanism configured to provide linear and rotational movement for the robot.

Abstract: A system can include at least one robot configured to autonomously navigate from a first location to a destination zone, the at least one robot having a generally cylindrical shape and including a storage container for storing at least one item for delivery, a plurality of image based depth sensor mounted proximate a top end of the robot, and a controller configured to navigate to the destination zone and to authenticate a delivery target for the item.