Abstract: Methods and systems are disclosed for predictive feedback compensation (PFC) circuitry for suppressing distortions caused by supply voltage variations and output amplitude switching non-idealities in pulse width modulated (PWM) switching amplifiers by pre-compensating the PWM input based upon the supply voltage or output pulse amplitude. Output amplitude errors associated with previous PWM output signals are used to predict output amplitude errors expected for future PWM output signals. These predicted output amplitude errors are then used to adjust the pulse widths for the future PWM output signals. Traditional feedback techniques can also be used in conjunction with the predictive feedback compensation (PFC) circuitry.

Abstract: Methods and systems are disclosed for closed loop feedback for pulse width modulated (PWM) switching amplifiers using predictive feedback compensation (PFC) for suppressing distortions caused by supply voltage variations and output amplitude switching non-idealities in pulse width modulated (PWM) switching amplifiers by pre-compensating the PWM input based upon the supply voltage or output pulse amplitude and using closed loop timing feedback. Output amplitude errors associated with previous PWM output signals are used to predict output amplitude errors expected for future PWM output signals. These predicted output amplitude errors are then used to adjust the pulse widths for the future PWM output signals. Timing differences between pulse widths for the uncompensated PWM input signal and the pre-compensated PWM signal are used as feedback to provide closed loop width adjustment.

Abstract: Methods and systems are disclosed for closed loop feedback for pulse width modulated (PWM) switching amplifiers using predictive feedback compensation (PFC) for suppressing distortions caused by supply voltage variations and output amplitude switching non-idealities in pulse width modulated (PWM) switching amplifiers by pre-compensating the PWM input based upon the supply voltage or output pulse amplitude and using closed loop timing feedback. Output amplitude errors associated with previous PWM output signals are used to predict output amplitude errors expected for future PWM output signals. These predicted output amplitude errors are then used to adjust the pulse widths for the future PWM output signals. Timing differences between pulse widths for the uncompensated PWM input signal and the pre-compensated PWM signal are used as feedback to provide closed loop width adjustment.

Abstract: Methods and systems are disclosed for predictive feedback compensation (PFC) circuitry for suppressing distortions caused by supply voltage variations and output amplitude switching non-idealities in pulse width modulated (PWM) switching amplifiers by pre-compensating the PWM input based upon the supply voltage or output pulse amplitude. Output amplitude errors associated with previous PWM output signals are used to predict output amplitude errors expected for future PWM output signals. These predicted output amplitude errors are then used to adjust the pulse widths for the future PWM output signals. Traditional feedback techniques can also be used in conjunction with the predictive feedback compensation (PFC) circuitry.

Abstract: A Schmitt trigger circuit 10 includes a pair of transmission gates 20, 22 connected, respectively, between a pair of threshold voltages V.sub.tH, V.sub.tL and the threshold input port 16 of a comparator 12. The control lead of one transmission gate 20 is connected to the output 18 of the comparator 12 through an inverter 24. The control lead of the other transmission gate 22 is connected directly to the output 18 of the comparator 12. The other input port 14 of the comparator 12 receives the signal input. Also disclosed is a circuit 26 for generating the reference voltages V.sub.tH, V.sub.tL. The circuit 26 includes an operational amplifier 28 driving a complementary pair of current mirrors (M1, M3, M5; M4, M6) which force current through a pair of resistors (R.sub.H, R.sub.L) to ground potential. The resistors (R.sub.H, R.sub.L) provide stable reference potentials.

Abstract: The input (16) and output (20) MOS transistors of a current mirror (10) have their sources connected to a supply voltage node (12). The gate of the input transistor (16) is connected to its drain and is also connected to the gate of the output transistor (20) through an isolation switch (24). The gate of the output transistor (20) is connected to the supply voltage node (12) through a disable switch (26). Closing of the disable switch (26) and opening of the isolation switch (24) turns off current in the output transistor (20). Opening the disable switch (26) and closing the isolation switch (24) turns the output current on again.Also disclosed is a mirror (28) having switches (30), (32) configured for various logic functions. A voltage-controlled oscillator (34) and a phase detector circuit 72 having a switched current input provided by switched current mirrors (40, 42, 80, 82) is described.