A system and method for encoding and personalizing smart cards from a remote location. The method includes connecting to a website or remote server and allowing the user to use remote software to encode a smart card connected to a specified client computer or RFID enabled mobile device. The server manages specialized virtual device drivers to allow users only authorized devices that are connected to the server and block access to other unauthorized devices not belonging to the locally connected user's account. The server can also control how many cards are able to be encoded for each user.

The present invention provides a method for providing a random combination status code for a commodity, comprising parts A and B provided on a commodity and corresponding circuit components. The parts A and B have particular joint surfaces, and their respective joint surfaces have conductive geometric patterns made of a conductive material; the combination of these patterns reflects the on/off of a circuit, thereby generating potential signals which record and transmit information by means of other circuit components. In this coding method, different storage statuses of a commodity can be distinguished according to status bit information sent by the commodity. The method can be widely used in commodity packaging, and can achieve good effects in managing commodity circulation, quality and safety.

A method is provided for generating a public/private key pair and certificate. The method includes providing an integrated circuit (IC) with an IC specific initial public and private key pair and a public key certificate signed by a manufacturer of the IC. A smartcard having stored thereon customer unique configuration data related to the IC is provided to a customer of the IC manufacturer. The smartcard enables the customer to generate a customization value and a customized public key using the customer unique configuration data. In response to the customer receiving the public key certificate signed by the IC manufacturer from the IC, the customer is enabled to provide the customization value, the customized public key, and a public key certificate signed by the customer to the IC. The IC is thus enabled to generate a customized private key, thus providing an IoT device with a public/private key pair and a certificate signed by the device manufacturer without the use of a trusted party.

Cards embodying the invention include a core subassembly whose elements define the functionality of the card and a hard coat subassembly attached to the top and/or bottom sides of the core subassembly to protect the core subassembly from wear and tear and being scratched. The core subassembly may be formed solely of plastic layers or of different combinations of plastic and metal layers and may include all the elements of a smart card enabling contactless RF communication and/or direct contact communication. The hard coat subassembly includes a hard coat layer, which typically includes nanoparticles, and a buffer or primer layer formed so as to be attached between the hard coat layer and the core subassembly for enabling the lasering of the core subassembly without negatively impacting the hard coat layer and/or for imparting color to the card.

A tracking system comprising a tag reader comprising an interrogating antenna. One or more tags comprising an electrical energy generator configured to convert environmental energy to electrical energy. A radio frequency, RF, communication circuit. A controller configured to use the electrical energy generated by the electrical energy generator to transmit a data signal to the tag reader using the RF communication circuit.

An RFID system for selectively communicating with a targeted transponder from among a group of multiple adjacent transponders is provided. The RFID system may include a transponder conveyance system adapted to transport at least one targeted transponder from a group of multiple adjacent transponders through a transponder encoding area along a feeding direction and an antenna having a resonant inductor and a ferrite material, wherein the ferrite material at least partially covers the resonant inductor and defines an exposed portion of the resonant inductor. In one antenna-transponder alignment, the exposed portion extends substantially parallel to the feeding direction.

A method for automatically electronically associating vessel identity information of a vessel with an unassociated telemetric device, the unassociated telemetric device comprising a processor and being configured to detect and transmit quantity or usage data and being configured with a location sensing device, wherein the unassociated telemetric device is configured to communicate with a remote server, the method comprising the steps of: the remote server receiving the vessel identity information comprising a deployment location for the unassociated telemetric device; the unassociated telemetric device operating in accordance with an automatic action rule; in response to the unassociated telemetric device operating in accordance with the automatic action rule, the processor receiving location information of the unassociated telemetric device from the location sensing device; the unassociated telemetric device transmitting the location information; the remote server receiving the location information; the remote server correlating the location information with the vessel identity information when resolving that the location information represents that the unassociated telemetric device is within a proximity to the deployment location, and the remote server automatically electronically associating the unassociated telemetric device with the vessel identity information, resulting in the unassociated telemetric device becoming an associated telemetric device, so that when the associated telemetric device generates quantity or usage information, the quantity or usage information transmitted by the associated telemetric device is applied to a data store of the remote server related to the vessel identity information.

A system for processing barcode information provided by the user, which may be used to print and encode RFID-enabled product labels. The system may include a bar code scanner or may include a manual bar code entry interface such as a keyboard and mouse, and may be configured to output a label corresponding to a barcode once the barcode has been scanned, optionally with user customization by an operator and optionally including variable data provided through a variable data module. This system may allow for the calculation of EPC values, the tracking of serial values used in the printing process, exporting of the printing history, and printing and encoding of tag.

An integrated circuit is described. The integrated circuit comprises a one-time programmable non-volatile memory and a memory controller for the one-time programmable non-volatile memory. The memory controller is configured to send a first random number which has been generated in the integrated circuit to a device initialization server. The memory controller is configured, in response to receiving a signed device initialization message from the device initialization server, the signed device initialization message comprising a device initialization message and a corresponding signature, and the device initialization message comprising a second random number and a device identity, to determine whether the first and second random numbers are equal and whether the signature is valid. The memory controller is configured, in response to determining that the first and second random numbers are equal and that the signature is valid to program the device identity into a first part of the one-time programmable non-volatile memory.

A method is provided for generating a public/private key pair and certificate. The method includes providing an integrated circuit (IC) with an IC specific initial public and private key pair and a public key certificate signed by a manufacturer of the IC. A smartcard having stored thereon customer unique configuration data related to the IC is provided to a customer of the IC manufacturer. The smartcard enables the customer to generate a customization value and a customized public key using the customer unique configuration data. In response to the customer receiving the public key certificate signed by the IC manufacturer from the IC, the customer is enabled to provide the customization value, the customized public key, and a public key certificate signed by the customer to the IC. The IC is thus enabled to generate a customized private key, thus providing an IoT device with a public/private key pair and a certificate signed by the device manufacturer without the use of a trusted party.