Abstract: Disclosed herein include a system and a method of synchronizing a slave device to a signal from a master device based on pulse width analysis. The pulse width analysis is a process to sample the signal at a sampling frequency of the slave device, determine varying pulse widths of the sampled signal, and determine frequency of an embedded master clock signal of the signal based on statistical analysis of the varying pulse widths. Advantageously, performing pulse width analysis allows synchronization of a slave device with the embedded master clock signal in a time and cost efficient manner. In one aspect, determining a frequency of the embedded master clock signal and adjusting an internal clock of the slave device according to the determined frequency is faster and more cost efficient than iteratively adjusting the internal clock based on feedback loop based circuitries.

Abstract: Disclosed herein include a system and a method of synchronizing a slave device to a signal from a master device based on pulse width analysis. The pulse width analysis is a process to sample the signal at a sampling frequency of the slave device, determine varying pulse widths of the sampled signal, and determine frequency of an embedded master clock signal of the signal based on statistical analysis of the varying pulse widths. Advantageously, performing pulse width analysis allows synchronization of a slave device with the embedded master clock signal in a time and cost efficient manner. In one aspect, determining a frequency of the embedded master clock signal and adjusting an internal clock of the slave device according to the determined frequency is faster and more cost efficient than iteratively adjusting the internal clock based on feedback loop based circuitries.

Abstract: A differential input driver circuit (10, 50) includes first and second transistors (Q0, Q3) as input transistors and third and fourth transistors (Q1, Q2) as diode-connected, cross-coupled transistors. In one embodiment, first, second, third and fourth transistors are NPN bipolar transistors. The base terminals of the first and third transistors are connected while the base terminals of the second and fourth transistors are connected. The input transistors receive a pair of differential input signals (In+/?) at the emitter terminals (24, 26) and provides a pair of differential output signals (Vo+/?) at the collector terminals (16, 18). The emitter terminals of the diode-connected transistors (Q1, Q2) couple the input signal at the emitter terminal of the first transistor to the collector terminal of the second transistor and vice versa. The cross-coupling of the third and fourth transistors enables the input driver to operate effectively in single-ended to differential conversion mode.

Abstract: A differential input driver circuit (10, 50) includes first and second transistors (Q0, Q3) as input transistors and third and fourth transistors (Q1, Q2) as diode-connected, cross-coupled transistors. In one embodiment, first, second, third and fourth transistors are NPN bipolar transistors. The base terminals of the first and third transistors are connected while the base terminals of the second and fourth transistors are connected. The input transistors receive a pair of differential input signals (In+/?) at the emitter terminals (24, 26) and provides a pair of differential output signals (Vo+/?) at the collector terminals (16, 18). The emitter terminals of the diode-connected transistors (Q1, Q2) couple the input signal at the emitter terminal of the first transistor to the collector terminal of the second transistor and vice versa. The cross-coupling of the third and fourth transistors enables the input driver to operate effectively in single-ended to differential conversion mode.