A system and method are described that enables mobile devices (e.g. including but not limited to a mobile phone or the like), to intercept and respond to contactless card authentication requests, allowing mobile devices to be used in place of contactless cards. Enabling mobile phone devices to emulate contactless cards decreases issues related to lost or damaged cards, enabling a single device to be used to provide tokens related to multiple different contactless cards, and leverages functionality of the mobile device to provide dual-factor authentication.

A preprocessing method for configuring a near field communication (NFC) smart card, includes: determining a card set belonging to a user; generating identifier information corresponding to the card set according to a non-contact parameter corresponding to a card included in the card set, the identifier information identifying at least one of a state of conflict or a state of compatibility between two cards included in the card set; and sending the identifier information to electronic equipment used by the user, such that the electronic equipment adds, to an NFC smart card according to the identifier information, at least two cards compatible with each other in the card set.

A millimeter-wave (mmW) imaging device comprises a mmW radar sensor, an auxiliary sensor arrangement, and at least one processor. The mmW radar sensor comprises a transmitter coupled to an antenna arrangement configured to transmit mmW radiation at a target, and a receiver coupled to the antenna arrangement or a separate antenna arrangement configured to receive backscatter radiation from the target. The auxiliary sensor arrangement is configured to detect one or both of relative motion and relative position between the imaging device and the target. A processor of the mmW imaging device is configured to receive data respectively produced by the mmW radar sensor and the auxiliary sensor arrangement during relative movement between the imaging device and the target. The processor or a remote processor is configured to reconstruct a mmW radar image of the target using the received data.

Systems and methods for force-supplying cached API call data are disclosed. A system may comprise a memory storing instructions and at least one processor configured to execute instructions to perform operations including: receiving initial order data from a user device, the initial order data comprising a product identifier, a user identifier, and a promotion identifier; determining an initial reduction amount based on the received product identifier and promotion identifier; mapping the initial reduction amount to a cache identifier; caching the initial order data and the cache identifier; receiving an order request from a device associated with the user identifier, the order request being associated with the promotion identifier; calling an API to complete the order request; detecting a failure of the API attempting to complete the order request; retrieving the cache identifier; determining a final reduction amount; and completing the order request using the final reduction amount.

A computer system and method for identifying and monitoring animals in a confined space. A tracking apparatus is provided having a plurality of antenna arrays in proximity to a confined space. One or more animals to be disposed in the confined space are associated with a detection component operable to identify and detect a core body temperature of an animal it is associated with when detected by the tracking apparatus. Data is received in a computer monitor system from a detection component when detected by the tracking apparatus in the confined space. The received data identifies an animal in correlation with its motion and temperature data. Real-time position and core body temperature of a detected animal is determined while the animal is disposed in the confined space by analysis of the received data in the computer monitor system.

Secure medication storage is described herein. A smart latch includes an actuator, a communication interface, a display, and a processor. The actuator is configured to open and close a latch to secure a door of the enclosure. The processor can be configured to receive a user credential for accessing the enclosure, validate the user credential for accessing the enclosure, trigger the actuator to open the latch, thereby allowing the door to be opened, and trigger the actuator to close the latch after detecting that the door is closed, thereby securing the door.

An electronic processor is operatively connected with at least one video camera, or additionally or alternatively a non-camera-based sensor, and at least one annunciator to process real time video acquired by the at least one video camera in real time to perform a hand hygiene compliance enforcement method for encouraging use of a hand sanitation station. The real time video is analyzed to determine an occupancy time interval over which a sanitation zone imaged by the real time video is occupied. Whether a hand sanitation event occurs is determined based on images of a wash station zone extracted from the real time video acquired during the occupancy time interval. The at least one annunciator is controlled to annunciate a hand hygiene compliance status based on the determination of whether a hand sanitation event occurs.

Exemplary embodiments of the present invention utilize passive near-field communication (NFC) devices placed in various office spaces (e.g., offices, workstations, meeting rooms, etc.) to provide access to various scheduling and monitoring services.

Activity monitoring systems and methods are disclosed. Systems include a continuous glucose monitoring device for a user including a glucose sensor for monitoring blood glucose levels of the user during an activity. An activity monitoring device is associated with the user and includes an activity sensor for tracking movement of the user during the activity. A display device is associable with the user during the activity. At least one processor is configured to execute program instructions configurable to cause the at least one processor to: receive activity data from the activity monitoring device; cause to be displayed at least some of the activity data on the display device; receive blood glucose data from the continuous glucose monitoring device; determine a product consumption recommendation based on the blood glucose data and the activity data, wherein the product consumption recommendation includes a recommendation of when the user should consume carbohydrates in order to maintain blood glucose levels within a specified target range during the activity; cause to be displayed the product consumption recommendation on the display device; and record an activity log including the activity data and the blood glucose data with respect to time.

Provided is a dynamic label for a product. Data that is generated at different nodes in the supply chain can be linked to a unique identifier associated with the product. At a particular node, the dynamic label may be added to the product, container, or package. The dynamic label may include a Near Field Communication (“NFC”) tag with a value that can be read using a user device. The dynamic label may be connected to the unique identifier. When the product reaches a consumer, the consumer may use a device to read the dynamic label, and pass the value from the dynamic label to a host. The host may identify the connection between the dynamic label and the unique identifier, and may provide the data, that is generated by different nodes in the supply chain and that is associated with the unique identifier, to the user device.