A multi-channel digital isolator includes a digital isolator and an interlock circuit. The isolator includes a transmitter having a transmitter output, a receiver having a receiver input and a receiver output, an isolation barrier coupled between the transmitter output and the receiver input, and an output buffer having a buffer input and configured to output an isolated signal. The transmitter is configured to transmit an input signal across the isolation barrier. The interlock circuit has an interlock input coupled to the receiver output and an interlock output coupled to the buffer input. The interlock module is configured to prevent overlapping active states between the first isolated signal and a complementary isolated signal. In some implementations, the digital isolator also includes a dead-time insertion circuit.

A skew compensation circuit includes a skew detection circuit configured to generate skew detection signals by detecting a skew characteristic of a basic logic element constituting a semiconductor apparatus, a skew compensation signal generation circuit configured to generate a skew compensation signal by comparing the skew detection signals and a plurality of reference voltages, a variable delay circuit configured to generate a compensation signal by delaying an input signal by a delay time varied according to the skew compensation signal, and a reference voltage generation circuit configured to generate the plurality of reference voltages of which offset components are compensated for according to variations of a temperature and an external voltage.

In an embodiment, a class-D amplifier includes an input terminal configured to receive an input signal; a comparator having an input coupled to the input terminal; a deglitching circuit having an input coupled to an output of the comparator; and a driving circuit having an input coupled to an output of the deglitching circuit. The deglitching circuit includes a logic circuit coupled between the input of the deglitching circuit and the output of the deglitching circuit. The logic circuit is configured to receive a clock signal having the same frequency as the switching frequency of the class-D amplifier.

A positive feedback XOR/XNOR gate and a low-delay hybrid logic adder are provided. The low-delay hybrid logic adder comprises the positive feedback XOR/XNOR gate and an output circuit. The positive feedback XOR/XNOR gate comprises a first PMOS transistor and a second PMOS transistor used as pass transistors, a first NMOS transistor and a second NMOS transistor constituting a pull-down network, and a third PMOS transistor, a third NMOS transistor and a fourth NMOS transistor constituting a positive feedback loop. When an XOR logic output terminal of the positive feedback XOR/XNOR gate is pulled down below a switching threshold of an inverter formed by the third PMOS transistor and the fourth NMOS transistor, the positive feedback loop starts to operate to enable the XOR logic output terminal of the positive feedback XOR/XNOR gate to enter a pull-down phase to be pulled down to a low level to avoid threshold voltage losses.

A Hardware-Embedded Delay PUF (HELP) leverages entropy by monitoring path stability and measuring path delays from core logic macros. HELP incorporates techniques to deal with bias. A unique feature of HELP is that it may compare data measured from different test structures. HELP may be implemented in existing FPGA platforms. HELP may leverage both path stability and within-die variations as sources of entropy.

Aspects of the invention include a circuit including a power circuit having an amplifier, a resistor, a current source, and a first node, one end of the resistor being configured to couple to a power supply, the first node being coupled to an opposite end of the resistor, a first input terminal of the amplifier, and the current source. A voltage sensitive circuit includes a logic gate coupled to both a second input terminal of the amplifier and an output terminal of the amplifier at a second node.

A buffer circuit includes an input terminal, an output terminal, a buffer, and an RC circuit coupled in series with the buffer between the input terminal and the output terminal. The RC circuit is configured to increase a transition time between logical voltage levels of an output signal generated at the output terminal relative to a transition time between logical voltage levels of an input signal received at the input terminal, and the transition time of the output signal is based on a duration of a logic inversion of the input signal.

Apparatus and methods are provided for improving yield and frequency performance of integrated circuit processors, such as multiple-core processors. In an example, an apparatus can include a plurality of clock buffers, each clock buffer of the plurality of clock buffers configured to receive a first clock signal and distribute a plurality of second clock signals, a one-time programmable locate critical path mechanism configured provide a plurality of indications to enable or disable a delay of each clock buffer of the plurality of clock buffers, and a power management control circuit configured to over-ride one or more of the plurality of indications in a first non-test mode of operation of the apparatus and to not over-ride the one or more indications in a second non-test mode of operation of the apparatus.

A minimum delay error apparatus such as a minimum delay error detection, prediction, correction, repair, prevention, and/or avoidance apparatus includes a minimum delay path replica circuit. The minimum delay path replica circuit can detect or predict, and subsequently can correct or avoid, minimum delay errors in data paths of digital circuits using pulsed latches.

In an embodiment, a class-D amplifier includes an input terminal configured to receive an input signal; a comparator having an input coupled to the input terminal; a deglitching circuit having an input coupled to an output of the comparator; and a driving circuit having an input coupled to an output of the deglitching circuit. The deglitching circuit includes a logic circuit coupled between the input of the deglitching circuit and the output of the deglitching circuit. The logic circuit is configured to receive a clock signal having the same frequency as the switching frequency of the class-D amplifier.