A method of manufacturing an electrical system for reducing differential-to-differential far end crosstalk (DDFEXT) includes converting a first S parameter representative of a design of a first electrical system into a differential-only S parameter, generating a second differential-only S parameter configured to add even-mode propagation delay and odd-mode propagation delay of the differential-only S parameter of the electrical system such that a total even-mode propagation delay and odd-mode propagation delay of the differential-only S parameter are substantially equivalent, and reconfiguring a second electrical system from the differential-only S parameter and the second differential-only S parameter.

A method includes detecting a signal on a switching node connected to a power switch, detecting a gate drive voltage of the power switch, during a gate drive process of the power switch, reducing a gate drive current based on a first comparison result obtained from comparing the signal with a first threshold, and during the gate drive process of the power switch, increasing the gate drive current based on a second comparison result obtained from comparing the gate drive voltage with a second threshold.

A method includes detecting a signal on a switching node connected to a power switch, detecting a gate drive voltage of the power switch, during a gate drive process of the power switch, reducing a gate drive current based on a first comparison result obtained from comparing the signal with a first threshold, and during the gate drive process of the power switch, increasing the gate drive current based on a second comparison result obtained from comparing the gate drive voltage with a second threshold.

In a method of operating a circuit, at a beginning of a first edge of a driving signal, a first transistor is turned ON to pull, at a first changing rate, a voltage of the driving signal on the first edge from a first voltage toward a second voltage. Then, in response to the voltage of the driving signal on the first edge reaching a threshold voltage between the first voltage and the second voltage, the first transistor is turned OFF and an output circuit is caused to start a second edge of an output signal in response to the first edge of the driving signal. The second edge has a slew rate corresponding to a second changing rate of the voltage of the driving signal on the first edge from the threshold voltage toward the second voltage. The second changing rate is smaller than the first changing rate.

In a method of operating a circuit, at a beginning of a first edge of a driving signal, a first transistor is turned ON to pull, at a first changing rate, a voltage of the driving signal on the first edge from a first voltage toward a second voltage. Then, in response to the voltage of the driving signal on the first edge reaching a threshold voltage between the first voltage and the second voltage, the first transistor is turned OFF and an output circuit is caused to start a second edge of an output signal in response to the first edge of the driving signal. The second edge has a slew rate corresponding to a second changing rate of the voltage of the driving signal on the first edge from the threshold voltage toward the second voltage. The second changing rate is smaller than the first changing rate.

A serial bus re-driver circuit includes an edge detector circuit and a booster circuit. The edge detector circuit is configured to detect a transition of serial bus signal. The booster circuit is coupled to the edge detector circuit, and is configured to switch current to the serial bus signal. The booster circuit includes a leading edge boost pulse generation circuit and a trailing edge boost pulse generation circuit. The leading edge boost pulse generation circuit is configured to switch a first current pulse to the serial bus signal at the transition of the serial bus signal. The trailing edge boost pulse generation circuit is configured to switch a second current pulse to the serial bus signal. The second current pulse is shorter than the first current pulse.

A staggering signal generation circuit includes a pulse generation circuit, a counting circuit and a signal generation circuit. The pulse generation circuit generates a first periodic pulse signal and a second periodic pulse signal; the counting circuit counts the first periodic pulse signal and the second periodic pulse signal to generate rising edge triggering signals and falling edge triggering signals; and the signal generation circuit generate a staggering pulse signal according to the input rising edge triggering signals and the input falling edge triggering signals.

A staggering signal generation circuit includes a pulse generation circuit, a counting circuit and a signal generation circuit. The pulse generation circuit generates a first periodic pulse signal and a second periodic pulse signal; the counting circuit counts the first periodic pulse signal and the second periodic pulse signal to generate rising edge triggering signals and falling edge triggering signals; and the signal generation circuit generate a staggering pulse signal according to the input rising edge triggering signals and the input falling edge triggering signals.

A method includes detecting a signal on a switching node connected to a power switch, detecting a gate drive voltage of the power switch, during a gate drive process of the power switch, reducing a gate drive current based on a first comparison result obtained from comparing the signal with a first threshold, and during the gate drive process of the power switch, increasing the gate drive current based on a second comparison result obtained from comparing the gate drive voltage with a second threshold.

A method includes detecting a signal on a switching node connected to a power switch, detecting a gate drive voltage of the power switch, during a gate drive process of the power switch, reducing a gate drive current based on a first comparison result obtained from comparing the signal with a first threshold, and during the gate drive process of the power switch, increasing the gate drive current based on a second comparison result obtained from comparing the gate drive voltage with a second threshold.