In certain embodiments, driver circuitry generates drive signals to drive driven circuitry to transition between first and second states. The driver circuitry has a first-to-second driver circuit that generates a first drive signal to drive the driven circuitry to transition from the first state to the second state and a second-to-first driver circuit that generates a second drive signal to drive the driven circuitry to transition from the second state to the first state. The driver circuitry includes two complementary triggered current pulse generators (described in U.S. Pat. No. 10,554,206) that combine to efficiently provide switch drive for a FET or other reactive load. The triggered drive has fast edges for low switching losses. In certain embodiments, the low power triggered drive circuitry can respond to a slowly changing feedback signal to switch a FET so as to regulate a power converter output.

An n-type transistor and a p-type transistor are connected in series such that, when the two transistors are turned on, current flows from the collector of the n-type transistor to the collector of the p-type transistor. A positive-feedback capacitor is connected between the collector of one transistor and the base of the other transistor. The two transistors turn on together when the base voltage of the n-type transistor exceeds the base voltage of the p-type transistor by at least the sum of the turn-on threshold voltages of the two transistors and (i) the two transistors turn off together when the base voltage of the n-type transistor fails to exceed the base voltage of the p-type transistor by at least that sum. The positive-feedback capacitor ensures that the two transistors turn fully on and off together. In certain embodiments, the circuitry can be controlled to operate as a current pulse generator.

In certain embodiments, driver circuitry generates drive signals to drive driven circuitry to transition between first and second states. The driver circuitry has a first-to-second driver circuit that generates a first drive signal to drive the driven circuitry to transition from the first state to the second state and a second-to-first driver circuit that generates a second drive signal to drive the driven circuitry to transition from the second state to the first state. The driver circuitry includes two complementary triggered current pulse generators (described in U.S. Pat. No. 10,554,206) that combine to efficiently provide switch drive for a FET or other reactive load. The triggered drive has fast edges for low switching losses. In certain embodiments, the low power triggered drive circuitry can respond to a slowly changing feedback signal to switch a FET so as to regulate a power converter output.

An n-type transistor and a p-type transistor are connected in series such that, when the two transistors are turned on, current flows from the collector of the n-type transistor to the collector of the p-type transistor. A positive-feedback capacitor is connected between the collector of one transistor and the base of the other transistor. The two transistors turn on together when the base voltage of the n-type transistor exceeds the base voltage of the p-type transistor by at least the sum of the turn-on threshold voltages of the two transistors and (i) the two transistors turn off together when the base voltage of the n-type transistor fails to exceed the base voltage of the p-type transistor by at least that sum. The positive-feedback capacitor ensures that the two transistors turn fully on and off together. In certain embodiments, the circuitry can be controlled to operate as a current pulse generator.

An n-type transistor and a p-type transistor are connected in series such that, when the two transistors are turned on, current flows from the collector of the n-type transistor to the collector of the p-type transistor. A positive-feedback capacitor is connected between the collector of one transistor and the base of the other transistor. The two transistors turn on together when the base voltage of the n-type transistor exceeds the base voltage of the p-type transistor by at least the sum of the turn-on threshold voltages of the two transistors and (i) the two transistors turn off together when the base voltage of the n-type transistor fails to exceed the base voltage of the p-type transistor by at least that sum. The positive-feedback capacitor ensures that the two transistors turn fully on and off together. In certain embodiments, the circuitry can be controlled to operate as a current pulse generator.

An n-type transistor and a p-type transistor are connected in series such that, when the two transistors are turned on, current flows from the collector of the n-type transistor to the collector of the p-type transistor. A positive-feedback capacitor is connected between the collector of one transistor and the base of the other transistor. The two transistors turn on together when the base voltage of the n-type transistor exceeds the base voltage of the p-type transistor by at least the sum of the turn-on threshold voltages of the two transistors and (i) the two transistors turn off together when the base voltage of the n-type transistor fails to exceed the base voltage of the p-type transistor by at least that sum. The positive-feedback capacitor ensures that the two transistors turn fully on and off together. In certain embodiments, the circuitry can be controlled to operate as a current pulse generator.