Abstract: A signal driver may include a plurality of distributed drivers along a differential transmission line. Each of the plurality of the distributed drivers may include: an output tap configured to receive a portion of an incoming signal of the signal driver; and a T-coil connected to an output node of the output tap. The differential transmission line is connected to and intercepted by a first terminal and a second terminal of the T-coil, and a plurality of T-coils of the plurality of the distributed drivers are distributed along and spaced apart on the differential transmission line.

Abstract: A signal driver may include a variable termination resistor and a signal transmission line. The variable termination resistor may include one or more variable termination resistor units. Each of the one or more variable termination resistor units may include a switch connected to a first end node of the variable termination resistor; a T-coil connected to the switch; a first resistor connected to the first end node of the variable termination resistor and to the T-coil; and a second resistor connected to a second end node of the variable termination resistor and to the T-coil. The signal transmission line may be connected to the second end node of the variable termination resistor.

Abstract: A differential signal driver may include a driver circuit and a feedback loop. The driver circuit may include a first output node coupled to a first termination node for receiving a first termination bias voltage, a second output node coupled to a second termination node for receiving a second termination bias voltage, and a bias network connected to the second output node and to the second termination node. The feedback loop may include a first feedback resistor connected to the first output node at a first end of the first feedback resistor, a second feedback resistor connected to the second output node at a first end of the second feedback resistor, and a feedback amplifier configured to provide a feedback correction current from a common mode voltage to a node within the line from the first output node to the first termination node.

Abstract: A signal driver may include a variable termination resistor and a signal transmission line. The variable termination resistor may include one or more variable termination resistor units. Each of the one or more variable termination resistor units may include a switch connected to a first end node of the variable termination resistor; a T-coil connected to the switch; a first resistor connected to the first end node of the variable termination resistor and to the T-coil; and a second resistor connected to a second end node of the variable termination resistor and to the T-coil. The signal transmission line may be connected to the second end node of the variable termination resistor.

Abstract: A signal driver may include a plurality of distributed drivers along a differential transmission line. Each of the plurality of the distributed drivers may include: an output tap configured to receive a portion of an incoming signal of the signal driver; and a T-coil connected to an output node of the output tap. The differential transmission line is connected to and intercepted by a first terminal and a second terminal of the T-coil, and a plurality of T-coils of the plurality of the distributed drivers are distributed along and spaced apart on the differential transmission line.

Abstract: A differential signal driver may include a driver circuit and a feedback loop. The driver circuit may include a first output node coupled to a first termination node for receiving a first termination bias voltage, a second output node coupled to a second termination node for receiving a second termination bias voltage, and a bias network connected to the second output node and to the second termination node. The feedback loop may include a first feedback resistor connected to the first output node at a first end of the first feedback resistor, a second feedback resistor connected to the second output node at a first end of the second feedback resistor, and a feedback amplifier configured to provide a feedback correction current from a common mode voltage to a node within the line from the first output node to the first termination node.

Abstract: A controller includes first and second half bridge sense circuits coupled to a half bridge node. The half bridge node is coupled between a high side switch and a low side switch coupled to an input. A rising slew detection circuit is coupled to the first half bridge sense circuit to output a first slew detection signal in response to a rising slew event at the half bridge node. A falling slew detection circuit is coupled to the second half bridge sense circuit to output a second slew detection signal in response to a falling slew event at the half bridge node. A control circuit coupled to output a high side drive signal to the high side switch and a low side drive signal to the low side switch in response to the first slew detection signal, the second slew detection signal, and a feedback signal.

Abstract: A controller includes first and second half bridge sense circuits coupled to a half bridge node. The half bridge node is coupled between a high side switch and a low side switch coupled to an input. A rising slew detection circuit is coupled to the first half bridge sense circuit to output a first slew detection signal in response to a rising slew event at the half bridge node. A falling slew detection circuit is coupled to the second half bridge sense circuit to output a second slew detection signal in response to a falling slew event at the half bridge node. A control circuit coupled to output a high side drive signal to the high side switch and a low side drive signal to the low side switch in response to the first slew detection signal, the second slew detection signal, and a feedback signal.

Abstract: A method to control a high side switch of a motor drive includes sinking a current of an ON signal to communicate a turn ON of the high side switch. A first current signal, a second current signal, a third current signal, a fourth current signal and a common mode rejection signal are generated in response to the ON signal. The ON signal in a presence of common mode noise is determined by comparing the first current signal and the second current signal. A first output signal is generated in response to determining the ON signal. A drive signal is generated responsive to the first output signal to control the high side switch in response to the ON signal in presence of common mode noise that is caused by a slewing at a half-bridge node.

Abstract: A method to control a high side switch of a motor drive includes sinking a current of an ON signal to communicate a turn ON of the high side switch. A first current signal, a second current signal, a third current signal, a fourth current signal and a common mode rejection signal are generated in response to the ON signal. The ON signal in a presence of common mode noise is determined by comparing the first current signal and the second current signal. A first output signal is generated in response to determining the ON signal. A drive signal is generated responsive to the first output signal to control the high side switch in response to the ON signal in presence of common mode noise that is caused by a slewing at a half-bridge node.

Abstract: A controller for use in a power converter of a motor drive includes a control circuit configured to turn ON a high side switch by sinking a current of an ON signal. A high side signal interface circuit is coupled to receive the ON signal to generate a drive signal to control switching of the high side switch in a presence of a common mode signal caused by slewing at a half bridge node. The high side signal interface circuit includes a common mode cancellation circuit coupled to provide a common rejection signal to provide a cancellation or rejection of the common mode signal. A first current hysteresis comparator is coupled to receive a common mode rejection signal, a first current signal, and a fourth current signal, and generate a first output signal in a presence of a common mode voltage.

Abstract: A controller for use in a power converter of a motor drive includes a control circuit configured to turn ON a high side switch by sinking a current of an ON signal. A high side signal interface circuit is coupled to receive the ON signal to generate a drive signal to control switching of the high side switch in a presence of a common mode signal caused by slewing at a half bridge node. The high side signal interface circuit includes a common mode cancellation circuit coupled to provide a common rejection signal to provide a cancellation or rejection of the common mode signal. A first current hysteresis comparator is coupled to receive a common mode rejection signal, a first current signal, and a fourth current signal, and generate a first output signal in a presence of a common mode voltage.

Abstract: A power converter controller includes a high side signal interface circuit that includes a common mode cancellation circuit that is coupled to generate a fourth current signal representative of an OFF signal referenced to a bypass voltage during an initial state, and a first current signal in response to an ON signal being pulled to a lower value relative to the OFF signal to turn ON a high side switch. The common mode cancellation circuit generates a common mode rejection signal in response to the first and fourth current signals. A first current hysteresis comparator receives the first and fourth current signals, the common mode rejection signal, and a drive signal to generate a first output signal. A drive signal generated in response to the first output signal in a presence of a common mode voltage caused by slewing at a half bridge node.

Abstract: A power converter controller includes a high side signal interface circuit that includes a common mode cancellation circuit that is coupled to generate a fourth current signal representative of an OFF signal referenced to a bypass voltage during an initial state, and a first current signal in response to an ON signal being pulled to a lower value relative to the OFF signal to turn ON a high side switch. The common mode cancellation circuit generates a common mode rejection signal in response to the first and fourth current signals. A first current hysteresis comparator receives the first and fourth current signals, the common mode rejection signal, and a drive signal to generate a first output signal. A drive signal generated in response to the first output signal in a presence of a common mode voltage caused by slewing at a half bridge node.

Abstract: A controller for use in a power converter includes a control circuit coupled to generate a low side drive signal to control switching of a low side switch, and generate an ON signal and an OFF signal in response to a feedback signal representative of an output of the power converter. A high side signal interface circuit is coupled to generate a high side drive signal in response to the ON signal and the OFF signal to control switching of a high side switch. The ON signal and the OFF signal are coupled to be pulled up in response to a bypass voltage during an initial state. The high side signal is coupled to turn on the high side switch in response to the control circuit pulling the ON signal low, and turn off the high side switch in response to the control circuit pulling the OFF signal low.