A device for transmitting real-time identification of a fashion item for receipt by a portable wireless computing device operated by a consumer located in a non-store location observing the fashion item, the device comprising: a Bluetooth fashion-item identification chip including: a fashion-item-use sensor; a processor operably connected to the fashion-item-use-sensor; a Bluetooth low energy transmitter operably linked to the processor; a battery operably connected to the fashion-item-use sensor, Bluetooth low energy transmitter, and the processor for providing power to operate the device; and a machine washable coating deposited around the periphery of the device for protecting the interior of the device from repeated exposure to water, heat, and chemicals utilized to maintain the fashion item. The device is utilized in the methods and systems of the invention for real-time identification of a fashion-item observed by a consumer in a non-store location and for real-time time purchase of the identified fashion-item via the consumer's portable electronic device.

A train positioning method includes acquiring first device identification information at an antenna; acquiring train positioning information; after determining the first device identification information is trustworthy, storing the first device identification information and the positioning information in a non-volatile memory; after awakening the train from dormancy mode, receiving second device identification information using the antenna; according to the received second device identification information and the first device identification information from the memory, determining whether, after being awakened, the train is at the same position as before entering dormancy mode; upon determining that, after awakening, the train is at the same position as before entering dormancy mode, determining the current position and direction of the train match positioning information in the memory, and completing positioning of the train. This ensures the usage experience of users of a train. An apparatus, a system, and a computer-readable medium are also provided.

A method performed by a wireless device for wirelessly transmitting a wake-up signal. The method includes wirelessly transmitting a legacy physical layer protocol data unit (PPDU) to protect a wake-up receiver PPDU, wherein the legacy PPDU includes a preamble and a legacy frame, wherein the legacy frame includes a power management field that indicates that the wireless device is transitioning to a doze state to cause other wireless devices to refrain from transmitting to the wireless device and wirelessly transmitting a wake-up receiver PPDU after transmitting the legacy PPDU.

A method, an apparatus, and a computer program product for wireless communication are provided. The apparatus may transmit a plurality of repetitions of a cell-common wakeup signal (WUS) on a different transmit beam in each monitoring occasion of one or more monitoring occasions. Another apparatus may beam sweep receive beams in each monitoring occasion to receive the cell-common WUS and to identify a transmit beam/receive beam pair for receiving a paging communication in a paging occasion associated with the transmit beam.

Apparatuses, systems, and methods for performing multi-TRP transmissions using techniques for reducing wireless device power consumption. A wireless device may select a downlink signal buffering method for a communication slot. The downlink signal buffering method may be selected from a single antenna panel signal buffering method or a multi-antenna panel signal buffering method. One or more beams for which to perform downlink signal buffering for the communication slot may be selected based at least in part on the downlink signal buffering method selected. Downlink signals may be received from one or more cellular base stations during the communication slot using the selected one or more beams. The downlink signals received using the selected one or more beams may be buffered by the wireless device.

According to one example embodiment, a wireless communication device having an associated first serial code. The wireless communication device includes a receiver, a processor, and a transmitter. The wireless communication device starts up intermittently. The receiver receives a second serial code different from the first serial code from a second the wireless communication device different from the wireless communication device. The processor stores the second serial code received by the receiver in a memory, and acquires the first serial code and the second serial code from the memory. The transmitter transmits the first serial code and the second serial code.

A method for controlling a terminal to receive signaling from a wireless network during discontinuous reception, DRX, the method being carried out in the terminal and comprising determining (604) a time offset (ΔTO) between a first window (41) for monitoring a wake-up signal, WUS, occasion and a subsequent second window (42) for monitoring signal reception responsive to receiving a WUS in the first window, wherein said time offset is dependent on a characteristic (62) associated with a downlink signal from the wireless network in accordance with a predetermined rule.

A terminal according to one aspect of the present disclosure includes a control section that determines whether to power on or off each panel of a plurality of panels and switches power of the panel to ON or OFF, a receiving section that receives a signal by using the panel being powered on, and a transmitting section that transmits a signal by using the panel being powered on. According to one aspect of the present disclosure, it is possible to suppress power consumption of a panel.

Systems, methods, and computer readable media for performing task assignment, completion, and management within a crowdsourced surveillance platform. A remote server may identify targets for image capture and may assign capture tasks to users based on travel plans of the user. Users may be assigned task to capture image of target locations lying along a travel path. The remote server may aggregate data related to the captured images and use it to update a map and log changes to the target location over time.

Techniques for operating cellular internet of things (IoT) devices under a public cellular carrier are disclosed. During an active connection, the cellular IoT device's radio-controlling application can collect radio metrics by tapping into the diagnostics interface of IoT device's cellular modem to collect data regarding accumulative signal strength, block/bit error rate, and/or round-trip latency for the session, etc. During the active connection, battery and environmental information as well as application-based information can be collected and sent to a remote computing device. In an example, the cellular IoT device can be given revised or refined values for use in timers, which may be used by the device to more efficiently use idle and/or power-save modes to reduce battery power consumption. Moreover, the use of the timers may be extended to devices distinct from the cellular modem, thereby increasing the utility of the timers and the functionality of the IoT device.