Typically, online payments require entering sensitive transaction information into a third-party web browser or application. This may expose sensitive transaction information to an increased risk of inadvertent disclosure. Apparatus and methods are provided for a smart card which enables users to securely complete online payments without entering any sensitive transaction information into a third-party system. The smart card may include a touch-sensitive screen configured to display selectable payment options. The smart card may include a microprocessor and wireless interface. The wireless interface may provide wireless communication capabilities and the ability to initiate online payments based on information captured by the touch-sensitive screen.

A method for performing a card-to-card direct contactless transaction between a first active stored-value smart card (“SVSC”) and a second active SVSC, each comprising an active near-field communication (“NFC”) reader. The method may include activating the first active SVSC by receiving input of a personal identification number (“PIN”) on a keypad located on the first active SVSC, verifying the PIN and further receiving input of a transaction amount on the keypad. The method may further include initiating a wireless NFC communication to perform the transaction by positioning the first active SVSC within a pre-determined distance to the second active SVSC and confirming accuracy of each of the first and second active SVSC using the active NFC reader to retrieve card ID data and confirm accuracy. Following confirming, the method may include directly completing the transaction between the first active SVSC and the second active SVSC.

Wait times at ATMs may undermine the utility of these self-service machines. ATMs are configured to provide faster self-service kiosks that allow users to quickly perform common financial transactions. However, it has been increasing common for users to have to wait on a line to access an ATM. Apparatus and methods are provided for a smart card that stages transactions by capturing the amount, pin and other necessary information on the smart card itself, before the user begins interacting with the ATM. Information captured by the smart card may be transferred to ATM when the smart card is inserted into ATM. The user does not provide the ATM with any additional information after inserted the smart card into the ATM, thereby improving the transaction processing efficiency of the ATM and enhancing user satisfaction.

A method for performing a card-to-card direct contactless transaction between a first active stored-value smart card (“SVSC”) and a second active SVSC, each comprising an active near-field communication (“NFC”) reader. The method may include activating the first active SVSC by receiving input of a personal identification number (“PIN”) on a keypad located on the first active SVSC, verifying the PIN and further receiving input of a transaction amount on the keypad. The method may further include initiating a wireless NFC communication to perform the transaction by positioning the first active SVSC within a pre-determined distance to the second active SVSC and confirming accuracy of each of the first and second active SVSC using the active NFC reader to retrieve card ID data and confirm accuracy. Following confirming, the method may include directly completing the transaction between the first active SVSC and the second active SVSC.

Systems and methods for autonomous payment routing are provided. A method may include storing in a smart card a database of contacts accessed from a digital contact directory. The method may include receiving a request to reroute a payment via an alternate payment channel, the payment including a recipient and an amount, and the alternate payment channel originating from an account associated with one of the contacts in the database. The method may also include resolving, via a wireless communication element that is embedded in the smart card, routing information for the account. The method may also include transmitting, to an administrator of the account, a request for authorization to reroute the payment, and, when authorization is received, executing the payment via the alternate payment channel.

Disclosed are an IC card asymmetric labelling system, an IC card built-in password input system and an IC card built-in password input method. The IC card asymmetric labelling system includes: an IC card, a payment terminal and a cloud end sever. The IC card includes a crypto-key unit and a communication module. The crypto-key unit stores a first private key which is used to sign a message transmitted from the IC card. The communication module establishes a communication connection with a cloud end through the payment terminal, or directly establishes a communication connection with the cloud end. The cloud end stores an open ID of the IC card and associated user information. The open ID is a hash value of a first public key of the IC card and is open to the public.

A self-authenticating credit card includes an input device for entering a PIN. The PIN is accepted by a micro-controller that uses the entered PIN as an encryption key for decrypting stored account information. A portion of the account information includes data, that when decrypted, contains an image that is rendered on an integral display, with account information sent to a transaction terminal. A timer is used to limit access to account data while in the unlocked state.

Digital transaction apparatus including a Data Assistance Device (DAD), including a user interface that is operable to at least select data, and a DAD transmitter, a Digital Transaction Card (DTC), including a Digital Transaction Processing Unit (DTPU), and a DTC receiver, wherein the DAD and DTC are operable to transfer data from the DAD to the DTC and when subsequently using the DTC to effect a digital transaction, the DTC operates in accordance with data selected and transferred from the DAD to the DTC, wherein the DTPU is configured to enable data communication with a digital transaction device during a digital transaction, the DTPU operable to receive and execute one or more commands that emulate commands received from the digital transaction device.

Advanced loyalty applications are provided to improve the functionality of cards and devices. For example, a user interface may be placed on a card (e.g., a physical button) or a telephonic device (e.g., a virtual button on a capacitive touch screen). Manual input provided to this user interface may, for example, cause a non-merchant product (e.g., insurance) to be purchased with a merchant purchase. The product can be paid for with debit, credit, gift card balance, or points. A code indicative of a user's desire to purchase the product may be communicated to a payment card reader (e.g., to a magnetic stripe reader via a magnetic stripe communications device). A display may be provided next to a button to allow a user to scroll, or toggle by pressing the button repeatedly, through different products (which may be merchant or non-merchant products).

Disclosed herein is a small form factor device for selectively communicating an authorisation signal. The small form factor device comprises a processor configured to process force signals received from a force sensor to determine the occurrence of an authorisation gesture. If an authorisation gesture is determined to have occurred and light is detected by a light sensor of the device, the processor further causes a wireless communications module of the device to transmit an authorisation signal.