A zero current detection system for a switching regulator is provided. The switching includes an inductor. In the zero current detection system, a comparator has a positive input coupled to a terminal of the inductor and an output terminal for outputting a comparison result signal; a first signal latch circuit has a clock terminal for receiving the comparison result signal and outputting a latched output signal; a delay line module starts counting upon receipt of the latched output signal, and then outputs a zero current detection signal after counting a delay time; in response to the zero current detection signal, a voltage sampling module samples a node voltage at two different time points, to generate two sampling voltages; a delay control module adjusts the delay time of the delay line module according to the two sampling voltages.

A disclosed pre-driver includes multiple signal generation stages and a switching bias circuit with a first switch and a second switch. The first switch and primary inverters in each of the stages all receive the same input signal. When the input signal transitions, the first switch turns on the bias circuit to supply a bias voltage to each of the stages. However, the primary inverters do not concurrently turn on. Instead, due to the bias voltage and some additional circuitry within each stage, the primary inverters turn on in sequence and slowly, thereby ensuring that pre-driver signals generated and output by the different stages, respectively, transition in sequence and at a relatively slow rate. Once the last pre-driver signal transitions, the second switch turns off the switching bias circuit. Optionally, a selected one of multiple bias voltages could be used in order to tune delay and transition times.

The present disclosure generally relates to semiconductor structures and, more particularly, to measurement circuits for logic paths and methods of manufacture. The circuit includes: a flip flop device outputting an output signal comprising an intrinsic delay; a logic path looping the output signal back to the flip flop device such that the intrinsic delay is to be received by the flip flop device; and an oscillator which feeds an input signal into the logic path and sweeps the input signal to alter the looped output signal thereby providing a maximum frequency of the logic path.

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.

A high-speed signal driving device includes an assist driver, a delay adjuster, and a plurality of drivers. The assist driver receives a control signal and is coupled to a first output node and a second output node to output a first current to the first output node or the second output node. The delay adjuster receives the control signal to generate a plurality of delay signals. Each of the delay signals has a different delay time corresponding to the control signal. One of the drivers receives the control signal, and other drivers correspondingly receive the plurality of delay signals. The plurality of drivers are coupled to the first output node and the second output node via a first output end and a second output end.

A data-processing-circuit comprising: a clock-input-terminal configured to receive a clock-signal; a data-output-terminal configured to provide a data-output-signal; an adjustable-driver-buffer configured to: receive a data-signal; and apply a driver-strength-value to the data-signal in order to provide a data-output-signal, wherein the current level of the data-output-signal is based on the driver-strength-value; and a driver-control-module comprising: a time-alignment-module configured to: process the clock-signal and the data-output-signal in order to determine a timing-delay-signal that is representative of a time delay between: a transition in the clock-signal; and a transition in the data-output-signal; provide the driver-strength-value for the adjustable-driver-buffer based on the timing-delay-signal and a target-delay-signal, wherein the driver-strength-value is for reducing a difference between: the timing-delay-signal; and the target-delay-signal.

A high-speed signal driving device includes an assist driver, a delay adjuster, and a plurality of drivers. The assist driver receives a control signal and is coupled to a first output node and a second output node to output a first current to the first output node or the second output node. The delay adjuster receives the control signal to generate a plurality of delay signals. Each of the delay signals has a different delay time corresponding to the control signal. One of the drivers receives the control signal, and other drivers correspondingly receive the plurality of delay signals. The plurality of drivers are coupled to the first output node and the second output node via a first output end and a second output end.

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.

A circuit includes a random oscillation number generator (RONG) configured to generate first and second pulse signals at first and second RONG outputs. A first counter is coupled to the first RONG output and generates a first count at a first counter output. A second counter is coupled to the second RONG output and generates a second count at a second counter output. A selection circuit is coupled to the first and second counter outputs and to the first and second RONG outputs. A first pulse shaper is connected between the first RONG output and the first counter, and a second pulse shaper is connected between the second RONG output and the second counter.

Disclosed aspects relate to a clock distribution network of a synchronous logic device. The synchronous logic device has sub-circuits having different clock domains. The clock domains form a hierarchical structure. The clock distribution network has a clock source to provide a global clock signal. A programmable delay line associated with a sub-circuit generates a local clock signal for the sub-circuit by delaying the signal. A global skew control circuit can manage clock skew between the local clock signals. The global skew control circuit may adjust a delay, determine initial operations for the delay lines, verify whether it is possible to perform the initial operations, and perform a correction operation. The correction operation can include correcting the control commands such that the corrected commands lead to the same change of skew adjustment between the local clocks.