Abstract: A near field communication controller integrated circuit includes a power management circuit configured to retransmit an external supply voltage from at least one power supply input node to at least one power supply output node in a bypass power supply mode. The power management circuit is hardware configured to automatically enable the bypass power supply mode in response to the external supply voltage being present at the at least one power supply input node.

Abstract: The present disclosure relates to an electronic device comprising: at least one universal integrated circuit card or at least one secure element and at least one power supply circuit for said card or secure element, said power supply circuit being connected to at least a first power supply voltage source of the electronic device and comprising a voltage detector adapted to determine whether said first voltage source provides a first power supply voltage different from a reference voltage; and at least one near field communication module adapted to enter an active mode whenever said voltage detector determines that said first supply voltage is different from the reference voltage.

Abstract: The present disclosure relates to a method for powering an electronic device. The electronic device includes at least one universal integrated circuit card or at least one secure element; at least one power supply circuit for said card or secure element; and at least one near field communication module. When the near field communication module changes from a standby or inactive state to an active state, the following successive operations are performed: —the components and circuits of said electronic device are started; —programs of the electronic device and said secure card or element are started at the same time.

Abstract: Provided is a circuit for managing a first clock signal clocking a timer adapted to being controlled by a processor clocked by a second clock signal. When the processor is off, the first clock signal is equal to a third clock signal having a frequency lower than the frequency of the second clock signal. When the processor is on, the first clock signal is equal to a fourth signal having a rising edge at each rising edge of the second clock signal directly following a rising edge of the third clock signal.

Abstract: An electronic device includes a near-field communication module and a powering circuit for delivering a power supply voltage to the near-field communication module. When the near-field communication module is in a low power mode, the powering circuit is configured for an operational mode where it is periodically started to provide the power supply voltage.

Abstract: A near field communication controller integrated circuit includes a power management circuit configured to retransmit an external supply voltage from at least one power supply input node to at least one power supply output node in a bypass power supply mode. The power management circuit is hardware configured to automatically enable the bypass power supply mode in response to the external supply voltage being present at the at least one power supply input node.

Abstract: In accordance with an embodiment, a circuit for managing a power supply of an electronic module includes: a first state machine configured to receive a first command for disabling the module, and to verify that the first command remains the same for a first minimum time period; and a second state machine configured to cut off a power supply of a first portion of the module when the second state machine receives a second command from the first state machine indicating that the first command has remained the same for the first minimum time period. The first portion of the module is configured to is configured to be powered from a battery via a first power supply voltage.

Abstract: An electronic device includes a near-field communication module and a powering circuit for delivering a power supply voltage to the near-field communication module. When the near-field communication module is in a low power mode, the powering circuit is configured for an operational mode where it is periodically started to provide the power supply voltage.

Abstract: The present disclosure relates to a method for powering an electronic device. The electronic device includes at least one universal integrated circuit card or at least one secure element; at least one power supply circuit for said card or secure element; and at least one near field communication module. When the near field communication module changes from a standby or inactive state to an active state, the following successive operations are performed: —the components and circuits of said electronic device are started; —programs of the electronic device and said secure card or element are started at the same time.

Abstract: The present disclosure relates to an electronic device comprising: at least one universal integrated circuit card or at least one secure element and at least one power supply circuit for said card or secure element, said power supply circuit being connected to at least a first power supply voltage source of the electronic device and comprising a voltage detector adapted to determine whether said first voltage source provides a first power supply voltage different from a reference voltage; and at least one near field communication module adapted to enter an active mode whenever said voltage detector determines that said first supply voltage is different from the reference voltage.

Abstract: A datum is written to a memory, by splitting a binary word, representative of the datum and an error correcting or detecting code, into a first part and a second part. The first part is written at a logical address in a first memory circuit. The second part is written at the logical address in a second memory circuit. The error correcting or detecting code is dependent on both the datum and the logical address.

Abstract: A datum is written to a memory, by splitting a binary word, representative of the datum and an error correcting or detecting code, into a first part and a second part. The first part is written at a logical address in a first memory circuit. The second part is written at the logical address in a second memory circuit. The error correcting or detecting code is dependent on both the datum and the logical address.

Abstract: A datum is written to a memory, by splitting a binary word, representative of the datum and an error correcting or detecting code, into a first part and a second part. The first part is written at a logical address in a first memory circuit. The second part is written at the logical address in a second memory circuit. The error correcting or detecting code is dependent on both the datum and the logical address.

Abstract: A method can be used for addressing a slave integrated circuit connected to a bus. The slave integrated circuit has a default address on the bus. The method includes receiving, at the slave integrated circuit, an addressing message conveyed on the bus. The addressing message contains a replacement address. The method also includes replacing the default address within the slave integrated circuit with the replacement address upon receiving the addressing message, restarting the slave integrated circuit, and upon the restarting, assigning the replacement address as a new default address.

Abstract: A datum is written to a memory, by splitting a binary word, representative of the datum and an error correcting or detecting code, into a first part and a second part. The first part is written at a logical address in a first memory circuit. The second part is written at the logical address in a second memory circuit. The error correcting or detecting code is dependent on both the datum and the logical address.

Abstract: A method can be used for addressing a slave integrated circuit connected to a bus. The slave integrated circuit has a default address on the bus. The method includes receiving, at the slave integrated circuit, an addressing message conveyed on the bus. The addressing message contains a replacement address. The method also includes replacing the default address within the slave integrated circuit with the replacement address upon receiving the addressing message, restarting the slave integrated circuit, and upon the restarting, assigning the replacement address as a new default address.

Abstract: A method of operating on a net-list describing an integrated circuit design for use with an automated test pattern generator for testing an integrated circuit built using the design is described. The method includes replacing a defective portion of the design in test mode with a substitute circuit to reduce testing impact of the defective portion. The method includes identifying a first defective portion of the integrated circuit design in the net-list, determining conditions under which the first defective portion is likely to malfunction and replacing the first defective portion in the net-list with another first portion that provides unknown output signals representing an unknown state in response to conditions under which the first defective portion is likely to malfunction.

Abstract: Communication systems, circuits, circuit systems and methods of operating a circuit are provided. According to one aspect of the invention, a circuit configured to operate in a functional mode and a test mode includes a flip-flop including a control input; logic circuitry configured to generate a control signal to control an operation of the flip-flop; and control circuitry configured to selectively provide the control signal to the control input of the flip-flop during testing of the circuit in the test mode. A method of operating a circuit according to another aspect of the invention includes providing a circuit having a flip-flop; operating the circuit in a functional mode; testing the circuit; generating a control signal to control an operation of the flip-flop; and selectively providing the control signal to a control input of the flip-flop during the testing of the circuit.

Abstract: The present invention includes a circuit assembly and method of synchronizing plural circuits. According to one aspect of the present invention, a circuit includes: an oscillator configured to generate a reference clock signal; a first circuit including: a first divider configured to generate a first internal clock signal responsive to the reference clock signal; and reset generation circuitry configured to receive an external reset signal and generate a reset second circuit signal synchronized with a predefined position of the first divider, with the reference clock signal and with the external reset signal; and a second circuit including: reset detection circuitry configured to generate a reset detection signal synchronized with the reset second circuit signal and the reference clock signal; and a second divider configured to set to a predefined position responsive to the reception of the reset detection signal and generate a second internal clock signal synchronized with the first internal clock signal.