A method for controlling one or more scent delivery units includes maintaining one or more scheduled events, maintaining one or more scheduled anti-events, and generating, based on the one or more scheduled events and the one or more scheduled anti-events, command data to be communicated to the one or more scent delivery units to control their activation and deactivation. Generating the command data includes identifying a conflicting period of time during which control specified by the one or more scheduled events differs from control specified by the one or more scheduled anti-events and also includes generating command data that gives priority to control specified by the one or more scheduled anti-events. Control for the one or more scent delivery units during the conflicting period of time is in accordance with control logic of the one or more scheduled anti-events and not the one or more scheduled events.

Some aspects include a schedule development method for a robotic floor-cleaning device that recognizes patterns in user input to automatically devise a work schedule.

A scalable industrial asset management system dynamically negotiates allocation of mobile industrial assets to industrial operation sites. The asset management system tracks and models the capabilities and availabilities of a pool of mobile industrial assets (e.g., truck-mounted assets or other such assets). Based on a defined demand of a scheduled industrial operation requiring mobile industrial assets (e.g., a fracking operation, a mining operation, etc.) the system selects a subset of the mobile industrial assets that are both available during the scheduled operation and are collectively capable of satisfying the demands of the industrial operation. Moreover, based on the asset models for the subset of mobile industrial assets, the system configures an on-premise cloud agent device to collect telemetry data from the mobile assets during the operation and to migrate the collected data to a cloud-based collection and analytics system.

An automated manufacturing system and method is provided. The system includes a software system and a production system. The software system includes a design module, an engineering module, and a manufacturing module for the design, engineering, and subsequent production of a prefabricated building product. The production system includes a matrix of cells and a plurality of robotic production units configurable with a plurality of production tools. The matrix includes a number of columns and a number of rows, each column representing a product to be worked on and each row representing a type of work to be performed on each product. The system processes a building model and configures each cell to perform specific work with one or more robotic production units and one or more production tools. A prefabricated building product is built in stages as it moves from cell to cell.

A controller includes a processor and a communication circuit. The controller controls an object of control by sequentially repeating, on a predetermined control cycle, the transmission of the output data, the reception of the input data, and execution of a control program for generating the output data using the input data. In the transmission of the output data, the processor executes: storing of the output data in a frame, the output data having been generated by the execution of the control program in a previous control cycle; and control of the communication circuit such that the frame, in which the output data is stored, is transmitted to the object of control. The processor executes, in a current control cycle, at least a part of the storing of the output data in a frame that is to be executed in a next control cycle.

To obtain a plant-monitoring autonomous control system which performs autonomous distributed control without using an advanced calculation processing unit such as a CPU. A plant-monitoring autonomous control system is provided with a control network which mutually connects: input nodes for receiving an input signal from a control target apparatus and transmitting the input signal to the control network; a calculation node having calculation circuits, and for transmitting, to the control network, a result obtained by performing calculation processing on data received from the input node; and an output node for outputting, to the control target apparatus, data received from the calculation node.

A substrate production control system includes production start timing obtaining section configured to obtain information of production start timing on substrate production lines, setup time estimation section configured to estimate setup times required for a setup work of setting up the substrate production line, setup start timing determination section configured to determine setup start timing of starting the setup work based on the production start timing and the setup time, delivery time estimation section configured to estimate delivery time required for a delivery work of receiving a member necessary for production of the substrate from member warehouse and conveying the member to at least one of an execution location (external setup area) of the setup work and the substrate production line, and delivery start timing determination section configured to determine delivery start timing of starting the delivery work based on the setup start timing and the delivery time.

A programmable, refillable medication dispenser with scheduled metered medication unit dispensing, includes a main housing, a powered CPU with countdown timer, a multi-unit medication removable refillable cartridge with a (first) lock, a medication release control gate positioned at a medication outlet and connected to a (second) lock being a gate control mechanism, and an in-chamber medication unit sensor. A pharmacist will insert a medicine cartridge into the main housing, locking it in, and will program the CPU to permit a patient to activate dispensing according to a predetermined schedule, and then only when a medication unit is sensed in the chamber. A patient may receive the dispenser and activate medication dispensing according to the programmed schedule and dispense by the timer schedule, only when a medication unit is sensed in the chamber.

Apparatus and methods regarding a processing system operable to implement an arbiter. The arbiter receives commands from non-prioritized and prioritized actors, and repeatedly issues an earliest received, non-issued command received from the non-prioritized actor. Execution of an immediately preceding issued command is completed or terminated by a sending actor of the immediately preceding issued command before a subsequent earliest received, non-issued command is issued. The arbiter also issues a command received from the prioritized actor upon receipt of the command received from the prioritized actor. Issuance of the command received from the prioritized actor interrupts issuance and execution of a command received from the non-prioritized actor. The commands from the non-prioritized and prioritized actors are issued to equipment controllers operable to control equipment of a well construction system.

A method for controlling one or more scent delivery units includes maintaining one or more scheduled events, maintaining one or more scheduled anti-events, and generating, based on the one or more scheduled events and the one or more scheduled anti-events, command data to be communicated to the one or more scent delivery units to control their activation and deactivation. Generating the command data includes identifying a conflicting period of time during which control specified by the one or more scheduled events differs from control specified by the one or more scheduled anti-events and also includes generating command data that gives priority to control specified by the one or more scheduled anti-events. Control for the one or more scent delivery units during the conflicting period of time is in accordance with control logic of the one or more scheduled anti-events and not the one or more scheduled events.