In one embodiment, systems and methods include using an inspection and projection system to measure the thickness of a coating and provide visual guidance for secondary operations. The inspection and projection system comprises a robotic arm operable to rotate about a plurality of axes, wherein an end effector is disposed at a distal end of the robotic arm. The inspection and projection system further comprises a linear rail system, wherein the robotic arm is coupled to the linear rail system, and wherein the robotic arm is operable to translate along the linear rail system. The inspection and projection system further comprises a frame, wherein the linear rail system is disposed on top of the frame, and an information handling system coupled to the frame, wherein the information handling system is operable to actuate the robotic arm and the linear rail system.

A networked spray application management arrangement is described herein. The spray application management arrangement includes a spray scan data server and a spray application. The spray scan application, in turn, includes: a spray nozzle monitoring apparatus that renders a process variable data indicative of a current status of a spray nozzle system; and a first network interface that sends a message comprising a data payload comprising information corresponding to the process variable data to the spray scan data server. The spray scan data server includes: a second network interface for receiving the message; a spray scan database for storing the information corresponding to the process variable data; and a spray scan data analysis engine.

A measurement sensor is integrated with a control object so that a position separated from a processing object by the control object along a target trajectory is a measurement point. A control device includes: a first generator that generates a first command position of the control object on a plane; a first control part that generates a first operation amount using a model predictive control; a second generator that generates a second command position of the control object on an orthogonal axis that is orthogonal to the plane; and a second control part that generates a second operation amount using the model predictive control. The second generator generates the second command position so that the distance between the control object and the surface of an object is constant, based on the measurement result of the measurement sensor and the first command position.

An apparatus for growing plants comprises two towers located adjacent to each other and forming an outside perimeter surface, a tray located in the bottom of the outside perimeter surface; and a cable system configured to pull a plurality of pods along the outside perimeter, each pod having containers, the cable system configured to bring at least one pod in a contact with a liquid located in the tray. A plant growth monitoring system comprises a plurality of sensors, a plurality of distributors configured to distribute fertilizers in response to received commands, and a controller configured to receive a sensor data from the plurality of sensors, determine commands for a stage of growth of plants based on a sensor data received and transmit the commands to the distributors. A method of initiating a plant in preparation of its introduction into a vertical farm unit is also disclosed.

A multi-spectral optical plant treatment device (10) employs a vegetation scanner (20), an electromagnetic radiator (30) and a plant treatment controller (40) for multi-spectral plant treatment applications. In operation, the plant treatment controller (40) executes a discriminating recognition between unwanted plants and wanted plants, and further executes a systematic herbicide EM radiation emission for damaging a recognized unwanted plant in accordance with a photosynthesis termination and/or a photomorphogenesis termination and/or a systematic fertilizer EM radiation emission enhancing a recognized wanted plant in accordance with a plant protection enhancement and/or a plant flavor enhancement.

Apparatus, systems and methods for the application of water, fertilizers and herbicides to municipal plants, crop plants, indoor plants, nursery plants and the like. A self-powered mobile apparatus delivers a liquid agent. The apparatus has a reservoir for the agent and a dispenser, electronic plant identifier or geographic locator, and an electronic controller to control delivery of the agent based on an output of the electronic plant identifier or geographic locator, or an output of a remote electronic plant identifier or geographic locator.

Systems and a method predict a generation of a robotic program for industrial coating. Inputs are received including a virtual representation of a robot, a coating gun, elements of the object surface to be coated and a set of desired coating thickness ranges. Inputs on a coating dispersion object are also received. Training data of a plurality of robotic programs for industrial coating and of their corresponding coating thickness coverage on a plurality of surfaces are received. The training data are processed in x, y tuples so as to learn a mapping function to generate a coating prediction module. Starting with a given selected valid thickness coverage as input parameters, it is proceeded in an iterative manner to predict a robotic program via the coating prediction module. A coating robotic program is generated for each surface element based on the resulting predicted coating programs.

An automated construction robot system includes: a mobile base assembly configured to be displaceable within the work area; a head assembly configured to process a work surface; an arm assembly configured to moveably-couple the head assembly and the mobile base assembly and controllably-displace the head assembly with respect to the work surface; a machine vision system configured to scan a target area and generate target area information; and a computational system configured to: process the target area information to identify a surface defect, generate one or more remedial instructions based, at least in part, upon the surface defect identified, and manipulate one or more of the mobile base assembly, the head assembly and the arm assembly based, at least in part, upon the one or more remedial instructions.

Disclosed is a coating apparatus. A first imaging unit captures an image of the substrate disposed on the stage. A second imaging unit captures an image of the substrate disposed on the stage with a narrower viewing angle and higher resolution than the first imaging unit. The control unit performs a pre-alignment processing of capturing an image of a circular pre-alignment mark formed on the substrate using the first imaging unit and performing positioning of the substrate by controlling the moving mechanism and the rotating mechanism based on the captured image and, after the pre-alignment processing, performs a fine-alignment processing of capturing an image of a circular fine-alignment mark formed on the substrate using the second imaging unit and performing positioning of the substrate by controlling the moving mechanism and the rotating mechanism based on the captured image.

This solution is for painting the external walls of a building, and adopts a lightweight six axis robotic arm mounted on a mini-gondola hoisted by a pulley system with the controlling motor located within the mini-gondola, while another set of motor located on the pulley system at the roof-top end drives the mini-gondola to traverse laterally on a set of twin-rails on the roof-top of the building. Four vacuum suction cups mounted on the mini-gondola through linear actuator are used to secure the mini-gondola to the wall. Each linear actuator has three ultrasonic distance sensors that measure and manage the distance between the mini-gondola and the wall to be painted. Once the gondola is in position, the robotic arm will be activated to start the painting process.