Rectifier with indicator switch

What is claimed is: 1 . A rectifier circuit comprising: an input to be coupled to receive an alternating current (ac) input voltage; a full-wave bridge rectifier coupled to the input and configured to rectify the ac input voltage to output a rectified ac input voltage; a high-impedance circuit comprising an impedance element coupled to the input, wherein the impedance element is configured to be charged by the ac input voltage during at least a portion of a first half-cycle of the ac input voltage; a detection capacitor coupled to be charged by the impedance element during at least a portion of a second half-cycle of the ac input voltage; and a transistor coupled to the detection capacitor and configured to switch between an ON state and an OFF state to generate an indicator signal representative of a fault condition in the ac input voltage based on a voltage across the detection capacitor. 2 . The rectifier circuit of claim 1 , wherein the transistor is configured to switch to the ON state in response to the voltage across the detection capacitor decreasing below a detection threshold voltage. 3 . The rectifier circuit of claim 2 , wherein the detection capacitor is configured to maintain the voltage across the detection capacitor at or above the detection threshold voltage while the ac input voltage has a voltage that is greater than or equal to an input threshold voltage and while the ac input voltage is coupled to the input. 4 . The rectifier circuit of claim 2 , wherein the detection capacitor is configured to allow the voltage across the detection capacitor to decrease below the detection threshold voltage in response to the ac input voltage being removed from the input or in response to the ac input voltage having a voltage that is less than an input threshold voltage. 5 . The rectifier circuit of claim 1 , wherein the transistor is coupled to a terminal of a controller of a power converter, and wherein the indicator signal comprises a voltage at the terminal of the controller. 6 . The rectifier circuit of claim 5 , wherein the terminal of the controller comprises a bypass terminal, and wherein the transistor is configured to decrease the voltage at the bypass terminal by switching to the ON state in response to the voltage across the detection capacitor decreasing below a detection threshold voltage. 7 . The rectifier circuit of claim 1 , wherein the impedance element comprises a capacitor, and wherein a capacitance of the capacitor is less than a capacitance of the detection capacitor. 8 . The rectifier circuit of claim 1 , wherein the first half-cycle of the ac input voltage comprises a positive half-cycle of the ac input voltage, and wherein the second half-cycle of the ac input voltage comprises a negative half-cycle of the ac input voltage. 9 . The rectifier circuit of claim 1 , wherein the first half-cycle of the ac input voltage comprises a negative half-cycle of the ac input voltage, and wherein the second half-cycle of the ac input voltage comprises a positive half-cycle of the ac input voltage. 10 . The rectifier circuit of claim 1 , further comprising: an auxiliary circuit coupled between the high-impedance circuit and the detection capacitor, wherein the auxiliary circuit is configured to prevent current conduction from the impedance element to the detection capacitor during the at least a portion of a first half-cycle of the ac input voltage, and wherein the auxiliary circuit is configured to allow current to conduct from the impedance element to the detection capacitor during the at least a portion of a second half-cycle of the ac input voltage. 11 . A power conversion system comprising: an input to be coupled to receive an alternating current (ac) input voltage; a rectifier circuit coupled to the input, the rectifier circuit comprising: a full-wave bridge rectifier coupled to the input and configured to rectify the ac input voltage to output a rectified ac input voltage; a high-impedance circuit comprising an impedance element coupled to the input, wherein the impedance element is configured to be charged by the ac input voltage during at least a portion of a first half-cycle of the ac input voltage; a detection capacitor coupled to be charged by the impedance element during at least a portion of a second half-cycle of the ac input voltage; and a transistor coupled to the detection capacitor and configured to switch between an ON state and an OFF state to generate an indicator signal representative of a fault condition in the ac input voltage based on a voltage across the detection capacitor; a power converter coupled to receive the rectified ac input voltage from the full-wave bridge rectifier; and a controller coupled to receive the indicator signal from the transistor, wherein the controller is configured to control the power converter based at least in part on the indicator signal. 12 . The power conversion system of claim 11 , wherein the transistor is configured to switch to the ON state in response to the voltage across the detection capacitor decreasing below a detection threshold voltage. 13 . The power conversion system of claim 12 , wherein the detection capacitor is configured to maintain the voltage across the detection capacitor at or above the detection threshold voltage while the ac input voltage has a voltage that is greater than or equal to an input threshold voltage and while the ac input voltage is coupled to the input. 14 . The power conversion system of claim 12 , wherein the detection capacitor is configured to allow the voltage across the detection capacitor to decrease below the detection threshold voltage in response to the ac input voltage being removed from the input or in response to the ac input voltage having a voltage that is less than an input threshold voltage. 15 . The power conversion system of claim 11 , wherein the transistor is coupled to a bypass terminal of the controller, and wherein the transistor is configured to decrease a voltage at the bypass terminal by switching to the ON state in response to the voltage across the detection capacitor decreasing below a detection threshold voltage. 16 . The power conversion system of claim 11 , wherein the impedance element comprises a capacitor, and wherein a capacitance of the capacitor is less than a capacitance of the detection capacitor. 17 . The power conversion system of claim 11 , wherein the first half-cycle of the ac input voltage comprises a positive half-cycle of the ac input voltage, and wherein the second half-cycle of the ac input voltage comprises a negative half-cycle of the ac input voltage. 18 . The power conversion system of claim 11 , wherein the first half-cycle of the ac input voltage comprises a negative half-cycle of the ac input voltage, and wherein the second half-cycle of the ac input voltage comprises a positive half-cycle of the ac input voltage. 19 . The power conversion system of claim 11 , wherein the rectifier circuit further comprises: an auxiliary circuit coupled between the high-impedance circuit and the detection capacitor, wherein the auxiliary circuit is configured to prevent current conduction from the impedance element to the detection capacitor during the at least a portion of a first half-cycle of the ac input voltage, and wherein the auxiliary circuit is configured to allow current to conduct from the impedance element to the detection capacitor during the at least a portion of a second half-cycle of the ac input voltage. 2