Systems, methods, and electronic circuits facilitating embedded sensor chips in polymer-based coatings are provided. In one example, a method comprises fabricating an electronic circuit, the electronic circuit comprising one or more semiconductor devices, one or more sensors, and a communication element; encapsulating the electronic circuit within an insulator, resulting in an encapsulated circuit; and dispersing the encapsulated circuit into a lacquer solution comprising a polymer carrier and a solvent.

Multiple stationary radio frequency (RF) identification (RFID) readers are deployed overhead in a venue and are operated to read RFID tags. A mobile RFID reader is also operated in the venue for reading the RFID tags. The mobile reader is located in the venue, and a host server synchronizes the operation of the stationary readers with the operation of the mobile reader, determines when the mobile reader is in substantially simultaneous, synchronous operation with the stationary readers, and responsively modifies the operation of the stationary and mobile RFID readers to optimize the RFID reading performance.

An encoding method is illustrated. The method includes receiving data to be encoded onto a storage media, wherein the data corresponds to an item and is assigned to a data category. Further, the method includes parsing data into a plurality of data portions, based on one or more first characteristics associated with each of one or more characters in the data. The method further includes encoding, by the processor, the plurality of data portions using a plurality of encoding schemes, to generate a data packet, such that a first data portion of the plurality of data portions is encoded using a first encoding scheme of the plurality of encoding schemes and a second data portion of the plurality of data portions is encoded using a second encoding scheme of the plurality of encoding schemes, wherein the first encoding scheme is different from the second encoding scheme. Furthermore, the method includes transmitting the data packet, wherein the data packet is configured to be stored in the storage media.

Silent radio frequency identifier (RFID) state and restore back is described herein. An RFID tag enters a silent state by receiving a sleep command from an RFID reader. While the RFID tag is in the silent state, only an awake command will restore back normal operation of the RFID tag. Other received commands or interrogations from the RFID reader are ignored and responses are not transmitted to the RFID reader.

This disclosure is generally directed to an RFID system that includes a hybrid RFID tag offering a functionality of a passive RFID tag and an active RFID tag. When operating as a passive RFID tag, an RF signal received from an RFID reader is harvested to produce a DC voltage for powering the hybrid RFID tag. The harvested DC voltage is coupled into a capacitor at a slow-charging rate so as to avoid a capacitor inrush current causing an abrupt power supply voltage drop. A controller chip in the hybrid RFID tag can execute some RFID functions at this time, thereby speeding up a response to the RFID reader. The capacitor is then charged at a fast-charging rate for storing a reserve charge. The hybrid RFID tag can subsequently use the reserve charge to operate as an active RFID tag without waiting for an RF signal from the RFID reader.

A method of programming an RFID tag in an image-forming device is disclosed. The RFID tag is programmed while media is paused in a duplex media path. The RFID tag is programmed using an antenna located between a simplex media path and the duplex media path. Other methods and systems are disclosed.

An identification tag is described in which a first tag member is formed of a polymer and includes a front surface. A second tag member, also formed of a polymer but that visually contrasts with the first tag member, includes slots formed as visual indicia that extend through the second tag member. The second tag member is welded to a front surface of the first tag member to expose the front surface of the first tag member through the slots. An RFID inlay, providing a radio frequency identification function, is affixed to the first tag member on a rear surface thereof. A third tag member, also formed of a polymer, is welded to the rear surface of the first tag member to cover and protect the RFID inlay.

In embodiments of the present invention improved capabilities are described for a wireless computing device, comprising an antenna; an analog block for receiving and transmitting an RF signal through the antenna, wherein the energy from the received RF signal provides power to the wireless computing device; and a data processing and controller block for data management, wherein the data processing and controller block comprises: (i) a first program memory adapted to store a first set of instructions comprising a system call adapted to perform at least one function, and (ii) a second program memory adapted to store a second set of instructions comprising an instruction to call the system call, wherein the data processing and controller block is adapted to execute the first set of instructions and the second set of instructions,

wherein the antenna, analog block, and data processing and controller block are mounted on a single substrate.

Methods and systems are provided for an RFID system that can be tuned dynamically and/or in real-time during a coupling event between a reader and a transponder. The reader can comprise an antenna assembly, a signal driver, and a controller. The antenna assembly may include a tuning circuit and an antenna coupled to the tuning circuit. The tuning circuit can include registers that may be set to adjust one or more characteristics of the reader. A controller is coupled to the antenna assembly to determine characteristics of the received signal and to set hardware or firmware functions that improve the coupling of the reader and transponder and/or improve the reception of the signal(s) from the transponder.

A display may have an active area surrounded by an inactive border area. The display may be a liquid crystal display having a liquid crystal layer sandwiched between a color filter layer and a thin-film transistor layer. An upper polarizer may have a polarized central region that overlaps the active area of the display. The upper polarizer may also have an unpolarized portion in the inactive border area overlapping the border structures. The border structures may include colored material such as a white layer on the inner surface of the thin-film transistor layer. Binary information may be embedded into an array of programmable resonant circuits. The binary information may be a display identifier or other information associated with a display. The programmable resonant circuits may be tank circuits with adjustable capacitors, fuses, or other programmable components.