Abstract: One embodiment of the present invention includes a current regulator circuit. The circuit includes at least one switch configured to periodically couple and decouple a respective at least one voltage rail to an inductor to maintain a current through the inductor. The circuit also includes a pulse-width modulation (PWM) controller configured to set a duty-cycle associated with a switching signal to control the at least one switch based on a feedback signal that is associated with a magnitude of the current. The circuit also includes a switch-controlled current path configured to shunt the current from a load in response to a control signal. The circuit further includes an error circuit configured to provide an error term to the PWM controller upon activating the control signal to adjust the duty-cycle substantially instantaneously in response to the control signal.

Abstract: An apparatus to power and dim LEDs is provided. The apparatus generally comprises a boost converter having an output node, a regulator node, a sensing network, and an impedance network. LEDs, which are coupled in series with one another, are coupled between the output node and the impedance network of the boost converter. A zener diode is coupled to the output node and coupled to the sensing network, and a dimming circuit is coupled to the boost converter. The dimming circuit includes a diode coupled to the impedance network, a switch coupled between the diodes and ground (which receives the signal for dimming the plurality of LEDs), and a network coupled to the regulator node and to the node between the second diode and the second switch.

Abstract: An apparatus to provide overvoltage protection is shown. The apparatus comprises a boost converter (having an output node, a sensing network, and an impedance network) and a zener diode. The zener diode is coupled to the output node and to the sensing network. The breakdown value of the zener diode is selected to be greater than a desired voltage drop across a load when the load is coupled to the output node, and the zener diode creates an overcurrent fault in the boost converter when the voltage at the output node is greater than its breakdown value.

Abstract: Synchronization circuitry and synchronization system for synchronizing converters/controllers that are electrically-coupled to a common synchronization node. The synchronization system includes synchronization circuitry, oscillation circuitry, and a leading edge detector and pulse generator. The synchronization circuitry includes pull-up circuitry and pull-down circuitry for generating a voltage pulse-train at the synchronization node. The oscillation circuitry controls which of the pull-up and the pull-down circuitry is driven ON and which is driven OFF.

Abstract: One embodiment of the present invention includes a current regulator circuit. The circuit includes at least one switch configured to periodically couple and decouple a respective at least one voltage rail to an inductor to maintain a current through the inductor. The circuit also includes a pulse-width modulation (PWM) controller configured to set a duty-cycle associated with a switching signal to control the at least one switch based on a feedback signal that is associated with a magnitude of the current. The circuit also includes a switch-controlled current path configured to shunt the current from a load in response to a control signal. The circuit further includes an error circuit configured to provide an error term to the PWM controller upon activating the control signal to adjust the duty-cycle substantially instantaneously in response to the control signal.

Abstract: Various embodiments of the present invention provide rectifier controllers, power supplies and methods for operating such. As one example, a rectifier controller circuit is disclosed that includes a transistor, a phase locked loop circuit, a period counter and a combinational logic circuit. One leg of the transistor is electrically coupled to a switch node of a power supply, and is in parallel to a diode of the power supply. The phase locked loop circuit receives a signal representing a voltage at the switch node, and is operable to synchronize to a period of the signal representing the voltage at the switch node. The period counter divides the period of the signal representing the voltage at the switch node into segments.

Abstract: Synchronization circuitry and synchronization system for synchronizing a plurality of convert/controllers that is electrically-coupled to a common synchronization node are disclosed. The synchronization system includes the synchronization circuitry, oscillation circuitry, and a leading edge detector and pulse generator. The synchronization circuitry includes pull-up circuitry and pull-down circuitry for generating a voltage pulse-train at the synchronization node. The impedance of the pull-down circuitry is at least an order of magnitude greater than the impedance of the pull-up circuitry. The oscillation circuitry controls which of the pull-up and the pull-down switching device is driven ON and which is driven OFF.

Abstract: A battery protection circuit includes a moisture detection circuit, a temperature sensing circuit, and a high-temperature battery discharge circuit. The moisture detection circuit includes a pair of conductive traces closely spaced on a substrate such that a resistive path is formed between the traces when moisture forms on the substrate. The traces are connected between the positive battery terminal and a pull-down current source. When moisture forms on the substrate, pull-up current flows between the traces, and a resulting voltage change on one of the traces is detected by circuit element such as a logic inverter. The temperature sensing circuit includes a voltage reference circuit that generates a proportional-to-temperature voltage and temperature-independent voltage reference signals corresponding to various predetermined temperatures.

Abstract: A battery protection circuit includes back-to-back connected metal-oxide-semiconductor field-effect transistors (MOSFETs). Detection circuitry detects whether the battery is in a normal charge condition, an overcharged condition, or an over-discharged condition, and for the overcharged and over-discharged conditions the circuitry asserts a corresponding enable signal. For each MOSFET, a corresponding gate voltage regulating circuit controls the gate voltage such that (i) when the corresponding enable signal is de-asserted, the gate voltage is sufficient to enable the MOSFET to strongly conduct current in either direction, and (ii) when the corresponding enable signal is asserted, the gate voltage is a function of the polarity of drain-to-source voltage of the MOSFET.

Abstract: A signal processor operates on a microprocessor or state machine based system to ensure that the central processing unit (CPU) and pulse generator (PG) have finished their instructions before allowing a new transition on the system master clock. The CPU and PG contain circuitry which allows them to indicate when they are busy. These signals are fed to the signal processor to indicate when the CPU and PG are ready to start another instruction. The signal processor functions to prevent a noise glitch on the system clock from causing another operation to start before the one in process has finished. The output of the signal processor becomes the master clock signal used by the system.