Abstract: Techniques and apparatus for driving a transistor gate of a switched-mode power supply (SMPS) circuit. One example gate driver for a switching transistor of an SMPS circuit generally includes a first power supply rail; a reference rail; an output node for coupling to a control input of the switching transistor; a floating supply node; a pulldown transistor having a drain coupled to the output node of the gate driver and having a source coupled to the reference rail; and a pulldown logic buffer having a first power supply input coupled to the floating supply node, having a second power supply input coupled to the reference rail, and having an output coupled to a gate of the pulldown transistor. The floating supply node is configured to selectively receive power from the first power supply rail and the output node of the gate driver.

Abstract: Techniques and apparatus for driving a transistor gate of a switched-mode power supply (SMPS) circuit. One example gate driver for a switching transistor of an SMPS circuit generally includes a first power supply rail; a reference rail; an output node for coupling to a control input of the switching transistor; a floating supply node; a pulldown transistor having a drain coupled to the output node of the gate driver and having a source coupled to the reference rail; and a pulldown logic buffer having a first power supply input coupled to the floating supply node, having a second power supply input coupled to the reference rail, and having an output coupled to a gate of the pulldown transistor. The floating supply node is configured to selectively receive power from the first power supply rail and the output node of the gate driver.

Abstract: The embodiments described herein relate to an improved circuit technique for sensing current conducting in a power transistor coupled with an input power supply. The circuit includes a bi-directional current sensing circuit using current sensing transistor gate control. The circuit includes a forward current sensing transistor to sense current conducting in the power transistor during forward mode current of the circuit and a reverse boost current sensing transistor to sense current conducting during reverse current mode of the circuit. A level shifter is also provided with complementary outputs to either turn on the forward current sensing transistor or turn off the reverse boost current sensing transistor when the circuit is in forward current mode, or to turn off the forward current sensing transistor and turn on the reverse boost current sensing transistor when the circuit is in reverse current mode.

Abstract: The embodiments described herein relate to an improved circuit technique for sensing current conducting in a power transistor coupled with an input power supply. The circuit includes a bi-directional current sensing circuit using current sensing transistor gate control. The circuit includes a forward current sensing transistor to sense current conducting in the power transistor during forward mode current of the circuit and a reverse boost current sensing transistor to sense current conducting during reverse current mode of the circuit. A level shifter is also provided with complementary outputs to either turn on the forward current sensing transistor or turn off the reverse boost current sensing transistor when the circuit is in forward current mode, or to turn off the forward current sensing transistor and turn on the reverse boost current sensing transistor when the circuit is in reverse current mode.

Abstract: A circuit is for generating a signal that indicates whether or not an input current exceeds a pre-established threshold current and, in the affirmative case, that is representative of the difference between the input current and the threshold current. The circuit includes a diode-connected transistor biased with a first constant current in a saturation functioning condition, a sense transistor mirrored to the diode-connected transistor and biased in a linear (triode) functioning condition, a load transistor connected in series to the sense transistor, biased with a second constant current and the control terminal of which is connected in common with the respective terminals of the diode-connected transistor and of the sense transistor. The input current to be compared is injected to a common current node of the load transistor and of the sense transistor, and the output voltage is available on the other current node of the load transistor.

Abstract: A circuit is for generating a signal that indicates whether or not an input current exceeds a pre-established threshold current and, in the affirmative case, that is representative of the difference between the input current and the threshold current. The circuit includes a diode-connected transistor biased with a first constant current in a saturation functioning condition, a sense transistor mirrored to the diode-connected transistor and biased in a linear (triode) functioning condition, a load transistor connected in series to the sense transistor, biased with a second constant current and the control terminal of which is connected in common with the respective terminals of the diode-connected transistor and of the sense transistor. The input current to be compared is injected to a common current node of the load transistor and of the sense transistor, and the output voltage is available on the other current node of the load transistor.

Abstract: A method of feedback controls a switched regulator generating a regulated voltage on an output terminal and being driven by a pulse width modulated (PWM) signal that determines on-phases during which the output terminal is selectively connected to a supply line, and off-phases during which the output terminal is disconnected according to a pulse skipping mode. The method may include comparing the regulated voltage with a reference voltage, and during the on-phase of the PWM signal, selectively connecting or disconnecting the supply line to the output terminal based upon the comparing for keeping the regulated voltage constant. The method may also include incrementing, decrementing, or leaving unchanged a duty-cycle of the PWM signal at every PWM cycle also based upon the comparing.

Abstract: A method of feedback controls a switched regulator generating a regulated voltage on an output terminal and being driven by a pulse width modulated (PWM) signal that determines on-phases during which the output terminal is selectively connected to a supply line, and off-phases during which the output terminal is disconnected according to a pulse skipping mode. The method may include comparing the regulated voltage with a reference voltage, and during the on-phase of the PWM signal, selectively connecting or disconnecting the supply line to the output terminal based upon the comparing for keeping the regulated voltage constant. The method may also include incrementing, decrementing, or leaving unchanged a duty-cycle of the PWM signal at every PWM cycle also based upon the comparing.