An equipment management method based on radio frequency identification comprises binding a first electronic tag and second electronic tags, reading the first electronic tag in a search mode, obtaining an abnormality list of one or more abnormal tags in the second electronic tags according to the first electronic tag, reading one of the second electronic tags in the search mode, and outputting an error signal when the read second electronic tag matches up to the abnormality list. The first electronic tag is set on a test machine, the second electronic tag are respectively set on test elements, and the test elements are disposed in the test machine.

Consistent with disclosed embodiments, systems, methods, and computer readable media for electronic security systems for preventing theft of returned goods may be provided. Embodiments may include an electronic article surveillance (EAS) gate in an establishment and at least one receiver configured to receive transmissions from wirelessly transmitting tags. Embodiments may also include at least one processor configured to receive, from a mobile communications device associated with a previous purchaser, a notification of intent to return a previously purchased product to the establishment; identify a unique tag ID of a specific wirelessly transmitting tag associated with the previously purchased product; update a data structure to indicate that the previously purchased product was returned to the establishment; and enable an ability to initiate an alarm when the at least one receiver receives a transmission from the specific tag associated with the previously purchased product in proximity to the EAS gate.

Embodiments of the disclosure relate generally to imaging devices and indicia reading devices. An imaging apparatus comprises an image sensor, an optical window positioned in front of the image sensor and a light source enclosing a perimeter of the optical window such that an illumination cone of the light source overlaps a portion of a near field of view cone of the imaging apparatus. The portion of the near field of view cone extends from a surface of the optical window to a threshold distance from the optical window. The light source is configured to produce a first illumination along a first direction extending towards a scene to be imaged.

A portable item reporting device (200) is configured to be attached to and in substantial collocation with a portable item (100), or to be integrated into a portable item (100). The device (200) includes environmental sensors (210) to monitor item location, movement, ambient light, sounds, temperature, etc. The device (200) is configured to store usage expectation data (600) indicative of historical and/or expected item usage and environments when the item (100) is in normal use/storage associated with an authorized user (AU). The device (200) monitors current environmental conditions (104) surrounding and pertaining to the item. If the current environment (104) is inconsistent with expected conditions (600), the device (200) assesses that the item (100) is displaced (503.0), meaning either that the item (100) is in abnormal use or abnormal storage, or is under the control of an unauthorized user (UU) who is other than the authorized user (AU). Based on the assessment the device initiates a signal (372) or message (374) to an authorized user (AU) of the item (100), indicating that the item (100) usage/storage is displaced (503.0) or otherwise anomalous (503.2).

The present invention is a wireless HVIL system and method using RFID-enabled Electrical Connector with connector position assurance (“CPA”) features. Each RFID-enabled Electrical Connector has an RFID tag that is only readable after the CPA features of the RFID-enabled Electrical Connector have been fully deployed. If a CPA feature has not been fully deployed, electrically conductive material will obscure the RFID tag so that it cannot be read. At least one RFID reader is distributed so that all of the RFID tags are within its effective range. When system power is cycled on, the at least one RFID reader emits a digital pulse and reads all of the non-obscured RFID tags. If the at least one RFID reader detects all of the expected RFID tags, an HVIL processor will shut an HVIL switch, and power will be supplied to all HV devices.

An agent activated non-metal antenna for an ultra-high frequency (UHF) wireless sensor having a radio frequency identification (RFID) tag in electronic communication with the non-metal antenna, and a wireless data communication integrated circuit (IC), includes a conductive stimuli-responsive hydrogel material configured to be inactive prior to an interaction with an activating agent and active upon the interaction with the activating agent. The antenna is further configured to transmit power to turn on the wireless data communication IC only when the non-metal antenna is active upon interaction with the activating agent.

An indicia reading terminal has a three-dimensional depth sensor, a two dimensional image sensor, an autofocus lens assembly, and a processor. The three dimensional depth sensor captures a depth image of a field of view and create a depth map from the depth image, the depth map having one or more surface distances. The two dimensional image sensor receives incident light and capture an image therefrom. The autofocusing lens assembly is positioned proximate to the two dimensional image sensor such that the incident light passes through the autofocusing lens before reaching the two dimensional image sensor. The processor is communicatively coupled to the two dimensional image sensor, the three dimensional depth sensor, and the autofocusing lens assembly.

A mobile device includes a code capturing entity adapted to capture a data code associated with an item, an entity adapted to determine whether a captured data code is authentic and to generate authentication information as a result, and to decode the captured data code to obtain decoded information, and an output entity. The mobile device is adapted such that the authentication information and the decoded information are sent to a processing entity which receives the authentication information and the decoded information and generates, based on the authentication information and the decoded information by using a stored prediction model, an indication for a next code to be captured; and the output entity is arranged to output information relating to an item and location associated with said next code to be captured based on said indication.

Disclosed is a set for assisting in the shooting of images of an object including a mobile removable support (120) configured to receive the object, a unit (135) for modifying the pose of a member, including a unit for rigid fastening by suspension of the support, making it possible to modify the pose of the support, image shooting unit (110) enabling images to be obtained representing the support and the object placed on the support as well as computing unit (115) for receiving images from the image shooting unit, analyzing the images received and, in response to an analysis of those images and predetermined position information, controlling the unit for modifying the pose of a member.

A radio-frequency identification (“RFID”) system for tracking items stored in a safe. The RFID safe system may include at least a safe and an RFID system. An RFID antenna may be fixed inside the safe. For example, the RFID antenna may fixed on an inner surface of a door to the safe such that the RFID antenna sends and receives signals across multiple angles as the safe door opens and closes.