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.

Example embodiments of the systems and methods of card reader protection disclosed herein combine motorization technology with payment card industry (PCI) protection technology. In an example embodiment, access to the card is protected by a mesh grid inside a printed circuit board (PCB). In one embodiment, there are five mesh grid walls in total. A secure signal is used to transmit data. The data is transmitted along traces embedded within the circuit boards. When a signal trace extends from one layer of the PCB to a second layer, the traces on the separate layers are connected with a via hole that extends between the layers and electrically connects traces on different layers. In an example embodiment, one or more of the boards fit together with slot joints. The vias are positioned in the board such that they are hidden due to the slot joint configuration.

In one embodiment, chip-cards are fed from conveyor canisters individually into an array of N heterogeneous encoding assemblies of a heterogeneous chip-card production apparatus. Each chip-card is associated with a user account based on a database. Smart chips and magnetic stripes of the chip-cards are encoded asynchronously, electrically and magnetically by the N assemblies with N independent timing protocols for the N assemblies. Encoded chip-cards are deposited asynchronously in parallel by the N assemblies onto a conveyor belt and transported asynchronously and serially to a chip-card printer. The chip-card printer synchronizes each encoded chip-card with associated user account and prints on a surface of the encoded chip-card based on the associated user account. Parallel verification, serial verification-registration, and/or vision-based verification may be performed to verify and ensure consistency among printed text, patterns, custom labeling, magnetic encoded data, electrical encoded data, and associated user accounts. Faulty cards may be identified/rejected.

A payment card (e.g., credit and/or debit card) or other device (e.g., mobile telephone) is provided with a magnetic emulator operable to communicate data to a magnetic stripe read-head. Gift cards may be inputted by a user into such a payment card or other device such that a user can combine gift cards. Similarly, a user be provided with a global payment account that can be utilized in multiple countries that have different standards for formatting data. A user may be provided with a default country (e.g., United States) but may have a way to select that the user is in a different country (e.g., Japan). Accordingly, a user may select that a Japanese data structure be transmitted through a magnetic stripe reader when the user is in Japan.

Systems and methods of associating data to an item being transported by a conveying system are disclosed. The item and data associated with the item are received at a first zone of the conveying system. The data is stored in a first computer-readable storage medium associated with the first zone. The item is transported to a second zone of the conveying system, and the data stored in the first computer-readable storage medium is transferred to a second computer-readable storage medium associated with the second zone.

An encoded information reading (EIR) terminal can comprise a microprocessor, a memory, an EIR device including a two-dimensional imager, and a micro-projector including a light source and a light manipulation sub-system. The EIR device can be configured to output raw message data containing an encoded message and/or output a decoded message corresponding to an encoded message. The EIR terminal can be configured to acquire an image of a target object in a field of view (FOV) of the two-dimensional imager. The EIR terminal can be further configured, responsive to successfully locating decodable indicia within the image, to produce a decoded message by decoding the decodable indicia. The EIR terminal can be further configured, responsive to successfully decoding the decodable indicia, to generate a projectable image and to project the projectable image onto a surface the target object using the micro-projector.

This patent specification describes operations of a mobile device with barcode-reading capabilities and an application and license server. A mobile device may include a barcode-reading application downloaded from an application server. The barcode-reading application may operate in a base mode or an enhanced mode. In the base mode, the barcode-reading application may establish a network connection to a licensing server to obtain a license code, and determine at least one operating permission authorized by the license code. In the enhanced mode, the barcode-reading application may implement at least one enhanced barcode-reading function which corresponds to the at least one operating permission authorized by the license code. For example, the enhanced barcode-reading function may be a function of decoding a barcode symbology that the decoder is restricted from decoding in the base mode of operation.

A workstation has a metallic housing for supporting an electro-optical reader for reading bar code symbols. A radio frequency (RF) antenna of an RF identification (RFID) reader for reading RFID tags is mounted in a metallic container that is connected to the housing. The RF antenna radiates RF energy at a frequency greater than 900 MHz through RF excitation slots formed between the container and the housing.

In various embodiments, a chip card arrangement for carrying out contactless interaction with an external apparatus is provided. The chip card arrangement may include: a chip card, which has an electronic circuit, and having an optical coding element, which can be used to present an optically capturable code, wherein the electronic circuit is designed such that the interaction requires at least the code.

A multi-media reader (MMR) apparatus, secure transaction system and methods thereof are provided. The MMR apparatus includes a slot to receive a card and a near field communication (NFC) antenna to communicate with other NFC enabled devices and cards. The system is provided for securely sharing information over a network to complete one or more transactions using the MMR apparatus and a mobile device. The shared information may be separated and reassembled using on or more servers to increase security.