A health and safety compliance system includes processor(s), where the processor(s) are communicatively coupled to a user interface. The user interface includes a display screen, where the display screen is capable of displaying electronic image(s) and is communicatively coupled to the processor(s). The system also includes (i) a sensor unit that is communicatively coupled to the processor(s) and is capable of detecting motion of a user, (ii) a liquid dispensing unit that is communicatively coupled to the processor(s), and (iii) a temperature detection unit that is communicatively coupled to the processor(s).

A health and safety compliance system includes processor(s), where the processor(s) are communicatively coupled to a user interface. The user interface includes a display screen, where the display screen is capable of displaying electronic image(s) and is communicatively coupled to the processor(s). The system also includes (i) a sensor unit that is communicatively coupled to the processor(s) and is capable of detecting motion of a user, (ii) a liquid dispensing unit that is communicatively coupled to the processor(s), and (iii) a temperature detection unit that is communicatively coupled to the processor(s).

Methods are provided for authenticating an initiator of a transaction during processing of the transaction. Methods may include initiating a transaction, including transaction details, at a transaction initiation node. Methods may include transmitting the transaction to a processing entity. Methods may include identifying that the transaction is above a threshold of anomalous transactions based on historic transactions associated with the transaction details. Methods may include transmitting an authorization request from the processing entity to a payment card linked to the transaction details. Methods may include receiving the authorization request at the payment card. Methods may include approving and/or denying the authorization request at the payment card. Approving and/or denying the request may include input of a signature and/or biometric. Methods may include transmitting the approval and/or denial from the payment card to the processing entity. The processing entity may transmit the approval and/or denial to the transaction initiation node.

A wearable device includes a radio-frequency identification (RFID) tag having a memory that stores identification information. The wearable device also has a power harvesting circuit configured to harness power from electromagnetic radiation. Further, the wearable device has a sensor coupled to the power harvesting circuit and configured to utilize the power to monitor a condition of the wearable device. Even further, the wearable device has a microcontroller coupled to the sensor and configured to write data indicative of the condition to the memory of the RFID tag, wherein the RFID tag is configured to transmit the identification information and the data in response to receipt of the electromagnetic radiation from an RFID reader.

There is provided a pick-and-place system for transferring and installing a contoured composite structure onto a mandrel, in a composite manufacturing system. The pick-and-place system includes a tray station having a tray assembly to hold the contoured composite structure, prior to transfer and installation onto the mandrel. The pick-and-place system further includes an installation station having the mandrel and a pick-and-place assembly. The mandrel is designed to receive the contoured composite structure, and designed to move along a moving manufacturing line, via a conveyor assembly. The pick-and-place assembly includes a gantry assembly, a main beam suspended from the gantry assembly, the main beam having a plurality of end effector assemblies and a plurality of indexing assemblies, a vacuum system coupled to the main beam, a load balancer assembly coupling the main beam to the gantry assembly, and a control system coupled to the pick-and-place assembly, to operably control the pick-and-place-assembly.

An identification device is provided having an optical detector (1), a controller (5) and an identification transmitter unit (6), wherein the optical detector (1) has a detection area with an identification pattern partially covering the detection area and the controller (5) is designed to interact with the detector (1) and the identification transmitter unit (6) in such a manner that the identification transmitter unit (6) can be activated to transmit an identification signal depending on an analysis of the temporal sequence of measurement signals from the detector (1). A method is also provided for identifying an object by an identification system.

Systems and methods for providing automated inventory management of medicine and healthcare items stored within bins in care facilities are disclosed. A method includes providing an interactive storage device for attaching to a bin, and outputting, via an audiovisual element, a visual representation of a local inventory of the bin, receiving a user input, determining a change to the local inventory according to the user input, updating the local inventory in a non-volatile data store according to the change, synchronizing the local inventory with one or more nodes via a communication interface, and receiving, from the one or more nodes via the communication interface, periodic updates for a local cache comprising locations and inventories of one or more remote bins.

A multizone equipment tracking solution includes radio frequency identification (RFID) tags affixed to items of inventoried equipment; a plurality of RFID readers deployed in a plurality of different zones, including a transit zone and a storage zone, wherein an RFID reader in a transit zone comprises a mobile reader; and a monitoring node. The RFID readers read the plurality of tags, for example from items that are in the different zones, and report the tag codes to the monitoring node. Examples permit a real-time, end-to-end view of inventoried equipment across different zones, spanning multiple, widely-dispersed storage locations, in-transit routes (for both installation delivery and decommissioning recovery), and at operational sites. Reported data, including locations, times (e.g., durations), may be advantageously mined to provide value for inventory management by locating misplaced or incorrectly-routed items, and identifying excessive transit and storage times and actual loss events.

A light emitting apparatus recognition system includes a light emitting apparatus, an image capturing apparatus, a recognition apparatus, and an electromagnetic wave emitting element. The light emitting apparatus includes a light source that blinks on the basis of identification information unique to the light emitting apparatus and an electromagnetic wave receiving element. The image capturing apparatus captures an image of light emitted by the light source of the light emitting apparatus. The recognition apparatus recognizes the light emitting apparatus on the basis of the light appearing in the image captured by the image capturing apparatus. The electromagnetic wave emitting element emits an electromagnetic wave from the image capturing apparatus or a vicinity of the image capturing apparatus. The electromagnetic wave receiving element receives the electromagnetic wave emitted by the electromagnetic wave emitting element.

A light emitting apparatus includes a light source, and a processor configured to perform control to cause the light source to blink in a blink pattern corresponding to output information including identification information unique to the light emitting apparatus, and configured to, when causing the light source to blink by repeating the blink pattern, change a time interval between the blink patterns.