A device and a method for implementing a physically unclonable function is disclosed. In one aspect, the device includes at least one electronic structure including a dielectric. A conductive path is formed at a random position through the dielectric due to an electrical breakdown of the dielectric, or the electronic structure is adapted for generating an electrical breakdown of the dielectric such that the conductive path is formed through the dielectric at a random position. The at least one electronic structure is adapted for determining a distinct value of a set comprising at least two predetermined values. The distinct value is determined by the position of the conductive path through the dielectric.

An integrated circuit includes first and second bus terminals, a pass-gate transistor, first and rising time accelerator (RTA) control circuits, and first and second falling time accelerator (FTA) control circuits. The pass-gate transistor couples between the first and second bus terminals. The first RTA control circuit couples to the first bus terminal, detects a rising edge on the first bus terminal, and accelerates the rising edge on the first bus terminal. The first FTA control circuit couples to the first bus terminal, detects a falling edge on the first bus terminal having a slope below a threshold, and accelerates the falling edge on the first bus terminal. The second RTA and FTA control circuits function similar to the first RTA and FTA control circuits but with respect to the second bus terminal.

A circuit includes a first transistor having first and second current terminals and a first control input, and a second transistor having third and fourth current terminals and a second control input. The third current terminal is connected to the second current terminal at an intermediate node and the fourth current terminal connected to a ground or supply node. In some cases, a third transistor is connected to the intermediate node to bias the intermediate rather than letting the intermediate node float. In other cases, a capacitor is connected to the intermediate node to reduce a negative voltage that might otherwise be present on the intermediate node.

A high-voltage tolerant circuit includes a first level shifter responsive to an input signal having a first logic high voltage and a first logic low voltage for providing a first intermediate signal having the first logic high voltage and a second logic low voltage referenced to a second reference voltage higher than the first logic low voltage, a second level shifter responsive to the input signal for providing a second intermediate signal having a second logic high voltage referenced to a first reference voltage lower than the first logic high voltage, and the first logic low voltage, an output stage responsive to the first and second intermediate signals for providing an output signal having the first logic high voltage and the first logic low voltage, and a reference voltage generation circuit providing the second logic high and second logic low voltages without drawing current from the reference voltage generation circuit.

An output driver includes a first pre-driver circuit, a first driver circuit, a second pre-driver circuit, a second driver circuit, and a feedback network. The first pre-driver circuit pre-drives a first data input signal to generate a first pre-driving output signal. The first driver circuit drives the first pre-driving output signal to generate a first data output signal. The second pre-driver circuit pre-drives a second data input signal to generate a second pre-driving output signal, wherein the first data input signal and the second data input signal are a differential input of the output driver. The second driver circuit drives the second pre-driving output signal to generate a second data output signal. The feedback network performs a latching operation upon the first pre-driving output signal and the second pre-driving output signal according to the first data output signal and the second data output signal.

Embodiments of the disclosure provide a level shift circuit, a chip and a display device. By setting first and second voltage clamping modules, and by adjusting first clamping voltage by controlling bias voltage input to the first voltage clamping module and adjusting second clamping voltage by controlling bias voltage and second bias voltage input to the second voltage clamping module, respective operating and output voltages of the first and the second voltage clamping modules and the shift module are within small range. Therefore, even the level shift circuit is designed by using devices with breakdown voltage lower than the difference between the first and second power supply voltages, the devices in the level shift circuit may be avoid being breakdown. Accordingly, some process platforms that cannot produce high-breakdown voltage devices may produce chips including the level shift circuit in the embodiment, and the restrictions on the process platform are reduced.

A level shifter may include: a discharge circuit configured to receive an input signal on the basis of a first power supply voltage, and discharge an internal node on the basis of the input signal; a charge supply circuit configured to supply charge to an output node from which an output signal is outputted, on the basis of a second power supply voltage; and a voltage adjustment circuit including a first MOS transistor coupled between the internal node and the output node, and configured to adjust the voltage of the output node on the basis of a bias voltage applied to the first MOS transistor, and stop the operation of adjusting the voltage of the output node on the basis of the bias voltage, when the levels of the first and second power supply voltages are equal to each other.

Provided is a phase self-correction circuit, including a trigger signal operation module and a signal phase correction module. The trigger signal operation module and the signal phase correction module are both composed of a plurality of discrete components. The trigger signal operation module is configured to perform a logical operation on an input phase standard reference signal and actual transmission signal, to obtain a target trigger signal for triggering the signal phase correction module; and the signal phase correction module is configured to output, based on trigger modes of the target trigger signal and the actual transmission signal, a self-correction transmission signal with the same waveform as that of the phase standard reference signal, to realize phase self-correction on the actual transmission signal.

The embodiments herein describe technologies for back-gate biasing of clock trees using a reference generator. A circuit includes a set of clock buffers and a programmable voltage reference generator to apply a voltage to a back gate of a transistor of the set of clock buffers.

Apparatus and method for actively mitigating coherent errors by modifying an original quantum circuit, inserting Clifford gate operations at intermediate stages. Embodiments of the apparatus and method may perform CGI statically, at the compiling stage, and/or dynamically, at the control processing stage. The insertion of Clifford gates takes advantage of the symmetries in a quantum circuit and actively cancels coherent errors, maintaining the quantum processor in a state as close as possible to the original tune-up environment.