An electrostatic discharge (ESD) protection structure that provides snapback protections to one or more high voltage circuit components. The ESD protection structure can be integrated along a peripheral region of a high voltage circuit, such as a high side gate driver of a driver circuit. The ESD protection structure includes a p-channel device and an n-channel device. The p-channel device includes an n-type barrier region circumscribing a p-type drain region with an n-type body region. The p-channel device may be positioned adjacent to the n-channel device and a high voltage junction diode.

A method is provided for controlling communication in wireless charging. The method comprises: controlling wireless power transfer with a device; receiving a communication signal from the device; generating a jamming signal based on the communication signal from the device; and applying the jamming signal to the communication signal to obtain a jammed communication signal. A device is also provided for controlling communication in wireless charging. The device is configured to control wireless power transfer and receive a communication signal. The device comprises: a jamming circuit configured to generate a jamming signal based on the received communication signal, wherein the device is further configured to apply the jamming signal to the received communication signal to obtain a jammed communication signal.

A receiver circuit includes a clock lane propagating a clock signal. A self-sampled clock applies a delayed version of the clock signal to the clock signal and compensation logic controls an amount of delay of the delayed version of the clock, based on a reference voltage offset (difference) between the receiver and a transmitter. The delayed version of the clock is centered on one unit interval of the clock. An offset correction based on a clock duty cycle error is applied to data receiver front ends.

Circuits and methods for switching between an internal clock and an external clock without causing an interruption or an artifact in the switched clock signal are disclosed. To achieve this, the internal clock signal is synchronized with the external clock signal prior to switching. The synchronization may be accomplished using two possible clock-synchronization methods: a first method that passively waits for the clocks to synchronize over time and a second that adjusts a period of the internal clock signal to actively synchronize the clocks. The method selected for use requires the fewest clock cycles to reach synchronization, which is determined by a frequency difference between the two clock frequencies. After clock-synchronization, the output clock signal spectrum will be substantially the same before and after switching between the clock signals, and therefore is suitable for use with spread spectrum clocks.

A debounce circuit and a method for masking or filtering a glitch from an input signal are provided. The debounce circuit includes a reset synchronizer circuit and a logic circuit. The reset synchronizer circuit receives the input signal, detects a glitch in the input signal and outputs one or more reset synchronizer output signals having a first reset synchronizer state indicating detection of the glitch. The logic circuit receives the one or more reset synchronizer output signals, determines that the one or more reset synchronizer output signals are in the first reset synchronizer state indicating detection of the glitch and in response to determining that the one or more reset synchronizer output signals are in the first reset synchronizer state, keeps an output signal of the debounce circuit in a present state of the output signal of the debounce circuit.

A method and system for reducing power supply noise comprising receiving a primary data stream at a data rate. The primary data stream comprises a stream of bits having logical values of either zero or one. Then, splitting the primary data stream to create a first group of lower rate data streams and a second group of lower rate data streams. Processing the second group of lower rate data streams to invert the logic values of the bits of the lower rate data streams to create processed lower rate data streams. The first group of lower rate data streams are combined with the processed lower rate data streams to create a complementary data stream. Then, processing the primary data stream and the complementary data stream concurrently with a data processing system, the concurrent processing reducing noise on the power supply.

An electrostatic discharge (ESD) protection structure that provides snapback protections to one or more high voltage circuit components. The ESD protection structure can be integrated along a peripheral region of a high voltage circuit, such as a high side gate driver of a driver circuit. The ESD protection structure includes a p-channel device and an n-channel device. The p-channel device includes an n-type barrier region circumscribing a p-type drain region with an n-type body region. The p-channel device may be positioned adjacent to the n-channel device and a high voltage junction diode.

The present disclosure provides a PUF circuit including a first array including at least one physically unclonable function (PUF) cell, a second array including at least one PUF cell, and a controller which selects a first PUF cell from the first array and selects a second PUF cell from the second array and generates unique information represented by the first PUF cell and the second PUF cell based on a first output voltage output by the first PUF cell and a second output voltage output by the second PUF cell.

A synchronizer circuit includes a first synchronizer having a first input for receiving a signal associated with a first clock signal, a second input for receiving a second clock signal, and an output for providing a synchronizer circuit output signal; a second synchronizer having a first input for receiving the signal associated with the first clock signal, a second input for receiving the second clock signal, and an output; a detection stage having a first input coupled to the output of the first synchronizer and to the output of the second synchronizer, a second input for receiving the second clock signal, and an output; and a fault output stage having a first input coupled to the detection stage, a second input for receiving the second clock signal, and an output for providing a fault output signal.

A receiver circuit includes a clock lane propagating a clock signal. A self-sampled clock applies a delayed version of the clock signal to the clock signal and compensation logic controls an amount of delay of the delayed version of the clock, based on a reference voltage offset (difference) between the receiver and a transmitter. The delayed version of the clock is centered on one unit interval of the clock. An offset correction based on a clock duty cycle error is applied to data receiver front ends.