A method for facilitating mobile device payments, multimedia capture, calling, and messaging may include providing a payment, multimedia capture, calling, and messaging interface on a display of a mobile and wearable device and sensing a haptic input of the user via the haptic control associated with one touch payment, one tap payment, and one touch service. In response to the haptic input, a cloud-based application associated with the mobile and wearable device may be activated. The haptic input may be analyzed to determine a duration of the haptic input. Based on the duration of the haptic input, an operation may be selected from the list of predetermined operations to be performed by the cloud-based application. The predetermined operations include at least a payment operation, a multimedia capture operation, a calling operation, and a messaging operation. The method may include operably connecting the mobile and wearable device to a cloud storage.

A biometric imaging device is provided with: placement unit that supports a biological object, imaging unit that takes images of the biological object, and determining unit that determines whether or not the biological object is placed on the placement unit, based on whether or not a feature of the biological object has changed at a place where the placement unit and the biological object are in contact, in the image(s).

A smartcard having multiple operating modes. The smartcard may include a processor for controlling operation of the smartcard and an accelerometer for sensing movements of the smartcard, wherein the processor is arranged to switch between different modes of the multiple operating modes in response to the movements sensed by the accelerometer.

A smart card 102 may include a processor for controlling operation of the smartcard, a biometric sensor for identification of an authorised user, and an accelerometer for sensing movements of the smartcard. The processor may be arranged to permit access to one or more secure feature(s) of the smartcard based on the movements sensed by the accelerometer and authentication of the user's identity via the biometric sensor.

Devices, systems, and methods facilitate enrollment of authenticating biometric data for authenticating an authorized user via a biometric sensor. A data input device and a power source are operatively coupled to a smart card including a fingerprint sensor. An activation code input by the user interacting with the data input device is compared with a predefined activation code, and if the detected activation code matches the predefined activation code, a fingerprint template is enrolled from fingerprint data received from the fingerprint sensor, all without transmitting data from either the power source or the data input device to any device other than the smart card.

A fingerprint identification system is provided. The fingerprint identification system includes a sensing panel and a driving circuit. The sensing panel includes a plurality of sensors. Each of the sensors transmits a sensing signal and a reference signal through two signal transmission paths. The driving circuit is coupled to the sensing panel. The driving circuit is configured to drive the sensing panel, and execute a fingerprint identification operation according to the sensing signal and the reference signal. The sensing signal and the reference signal form a differential signal pair. The driving circuit generates a fingerprint identification signal according to the sensing signal and the reference signal. A driving circuit and a fingerprint identification method are also provided.

Method and apparatus for OLED-based displays are provided. Methods may include receiving card identification from a contactless communications chip at an OLED-based foldable display. Methods may include receiving a handwritten signature at a pressure-sensitive portion on the display. Methods may include transmitting the card identification information to a secure entity hub. Methods may include receiving a packet from the secure entity hub. The packet may include the identification number, an acceptance of the handwritten signature and card blank information. Methods may include activating a card blank attached to the display with card blank information. Methods may include transmitting a second packet to the secure entity hub comprising the identification number and a message that the card blank has been activated.

The application provides an enrolment card for a biometric card with a first card body. The enrolment card includes a battery for providing electrical power, a microcontroller unit that is electrically connected to the battery, and a plurality of contact pins that are electrically connected to the battery and to the microcontroller unit. The enrolment card further includes a second card body with a card engagement element. The second card body is sized to correspond to the first card body. The battery and the second microcontroller unit are embedded in the second card body. The enrolment card provides an enrolment mode, wherein the card engagement element engages with the first card body for allowing the contact pins to contact corresponding contact pads of the biometric card and the battery provides the electrical power to the biometric card.

A smart card with improved power stability is provided. The smart card comprises a rectification signal line through which a rectification signal extracted from a radio frequency (RF) signal is provided; a regulator configured to regulate a voltage of the rectification signal line to a first voltage; a power circuit configured to extract a power component from the rectification signal using an output of the regulator; a logic circuit configured to receive the power component and generate a reception enable signal on the basis of the power component; a demodulator which is enabled by the reception enable signal provided from the logic circuit and configured to extract a signal component from the rectification signal; a capacitor controller which is enabled by the reception enable signal provided from the logic circuit and configured to generate a capacitor enable signal; and a capacitor circuit which is connected to the rectification signal line and has capacitance changed according to the capacitor enable signal.

A Usage, Condition and Location System (UCLS) tag is provided, which is an active RFID tag that, in addition to location, is configured to determine the usage state and operating condition of a device. The UCLS tag includes sensors that measure physical activity of the associated equipment (vibration, magnetic activity, temperature, etc.). Algorithms may use the information obtained from the UCLS tags to map the measured sensor data to a contextual usage state and operating condition of the device.