A robotic fruit picking system includes an autonomous robot that includes a positioning subsystem that enables autonomous positioning of the robot using a computer vision guidance system. The robot also includes at least one picking arm and at least one picking head, or other type of end effector, mounted on each picking arm to either cut a stem or branch for a specific fruit or bunch of fruits or pluck that fruit or bunch. A computer vision subsystem analyses images of the fruit to be picked or stored and a control subsystem is programmed with or learns picking strategies using machine learning techniques. A quality control (QC) subsystem monitors the quality of fruit and grades that fruit according to size and/or quality. The robot has a storage subsystem for storing fruit in containers for storage or transportation, or in punnets for retail.

The present invention relates to automatic and high throughput smart, robotic, autonomous or driver operated, self-propelled field crops harvester (SPFCH) device of row crops, characterized by the need of selecting harvesting ripen crop, during relative long period of time. Harvesting is done by one or more modular robotic harvesting arms hanged on modular booms. When harvesting orchards fruits the SPFCH comprise at least one hybrid robotic arms equipped with a grabbing hand aimed to grab one or more fruit of a an adjacent fruits and also cut its connecting stem, and arm transporting mechanism that gently collects the fruits and transport them to the SPFCH main accumulation area. When harvesting cotton, the SPFCH of the invention may further comprise vacuum sucking hoses and at least one ginning unit that gin the seed-cotton during harvesting and accumulate the seeds in a self-container, and the lint by bales processed, on board by self-press.

A plant harvesting system for use with a vertical hydroponic tower, the hydroponic tower containing a plurality of vertically aligned plants. The harvesting system includes a payload transport system and a harvester. The payload transport system, which is configured to be positioned at a location adjacent to the hydroponic tower, includes a base and a lift tower, the lift tower including a motorized lift system configured to move the harvester upward and downward. In addition to cutting plant stalks while moving upwards along the face of the hydroponic tower, the harvester also groups and collects the plant leafs.

A plant harvesting system for use with a vertical hydroponic tower, the hydroponic tower containing a plurality of vertically aligned plants. The harvesting system includes a payload transport system and a harvester. The payload transport system, which is configured to be positioned at a location adjacent to the hydroponic tower, includes a base and a lift tower, the lift tower including a motorized lift system configured to move the harvester upward and downward. In addition to cutting plant stalks while moving upwards along the face of the hydroponic tower, the harvester also groups and collects the plant leafs.

A robotic fruit picking system includes an autonomous robot that includes a positioning subsystem that enables autonomous positioning of the robot using a computer vision guidance system. The robot also includes at least one picking arm and at least one picking head, or other type of end effector, mounted on each picking arm to either cut a stem or branch for a specific fruit or bunch of fruits or pluck that fruit or bunch. A computer vision subsystem analyses images of the fruit to be picked or stored and a control subsystem is programmed with or learns picking strategies using machine learning techniques. A quality control (QC) subsystem monitors the quality of fruit and grades that fruit according to size and/or quality. The robot has a storage subsystem for storing fruit in containers for storage or transportation, or in punnets for retail.

A fruit picker includes first and second curved sections, a handle and a bag. The first and second curved sections are outwardly curved to form a leaf-shaped space therebetween. The first curved section and a second curved section are attached at a first end at a cutter angle. The handle is attached to the first and second curved sections at a second end. The bag is attached to the first and second curved sections with fixing elements. The leaf-shaped frame provides maneuverability of this tool within a cluster of fruit or tree branches, where an angled shape helps catching and holding fruit. The scissors-like tip offers efficiency in releasing fruit from its stem. Finally, this fruit picker boasts applicability to multiple kinds of fruit.

A system including a first carrier configured to carry at least one first robotic system. The system also can include a second carrier configured to be coupled to a vehicle that is movable across a surface. The first carrier can be movably coupled to and carried by the second carrier. The system can be configured to automatically hold the first carrier in a first position and stationary in a first direction with respect to the surface during a first time period while the vehicle moves the second carrier in the first direction with respect to the surface during the first time period, such that at least a portion the at least one first robotic system carried by the first carrier is stationary in the first direction with respect to the surface during the first time period. Other embodiments are provided.

A harvesting system includes a vertical frame, a plurality of linear robots, a plurality of cameras and a processor. The vertical frame is configured to be positioned opposite a sector to be harvested. The robots are arranged in pairs stacked vertically in the frame, each pair including first and second robots that are configured to move together along a vertical axis, to move independently of one another along a horizontal axis, and have respective first and second robot arms that are configured to approach the sector and harvest fruit. The plurality of cameras is configured to acquire images of the sector. The processor is configured to identify the fruit in the images and control the robots to harvest the fruit.

This disclosure includes a method for pruning a fruit plant. An exemplary method step includes obtaining an image of the fruit plant that has branches. Next, creating exclusion zones surrounding the branches. Then pruning the fruit plant based upon the exclusion zones.

This disclosure includes a method for pruning a fruit plant. An exemplary method step includes obtaining an image of the fruit plant that has branches. Next, creating exclusion zones surrounding the branches. Then pruning the fruit plant based upon the exclusion zones.