Abstract: A connector assembly suppresses electromagnetic interference (EMI) generated by electronic circuitry on a printed circuit board (PCB). The connector assembly includes a plurality of conductive through-holes on the PCB, a connector, and a magnetic collar. The plurality of conductive through-holes are electrically connected to the electronic circuitry on the PCB. The connector has a plurality of terminal pins extending from a connector surface. The plurality of terminal pins and conductive through-holes may be aligned. The terminal pins are positioned through the conductive through-holes to electrically connect the terminals pins to the electronic circuitry. The magnetic collar surrounds the connector. The magnetic collar may also abut the PCB. The magnetic collar suppresses EMI on voltages propagating through the connector.

Abstract: A driver circuit provides power from a power source to a load. The driver circuit includes a surge protector, an input stage (e.g., full wave rectifier), a controller, an overvoltage protection circuit, and an output stage (e.g., a half bridge inverter). The input stage receives power from the power source and provides a direct current (DC) power rail. The controller operates the output stage to provide power from the DC power rail to the load. The overvoltage protection circuit shuts down the controller when the DC power rail exceeds a predetermined voltage. This ceases operation of the output stage, protecting the output stage from damage while the DC power rail is above the predetermined voltage.

Abstract: A driver circuit includes a combined current and voltage control circuit for driving a light emitting diode (LED) load. The driver circuit includes an isolation transformer having primary, secondary, and auxiliary windings. A primary side circuit is coupled to the primary winding and includes a power factor controller and a switch. The power factor controller controls an output current to the LED load by controlling an operational state of the switch. A secondary side circuit is coupled to the secondary winding. The secondary side circuit includes a proportional and integration (PI) control portion which outputs a control signal. A combined voltage and current control circuit is coupled to the auxiliary winding and includes an optocoupler coupled to the power factor controller and to the PI control section. The combined voltage and current control circuit transmits a control signal from the PI control section to the power factor controller.

Abstract: An apparatus and a method monitor the status of a thermal protection device within a surge protection device (SPD). A monitoring circuit connected to a monitor output signal of the SPD is responsive to the presence of a time-varying voltage on the monitor output signal. The time-varying voltage is present during a selected half of each AC cycle when the thermal protection device is intact such that the SPD is no longer providing surge protection. The time-varying voltage is not present when the thermal protection device is no longer intact. When the time-varying voltage is not present for a selected duration, the monitoring circuit illuminates a light-emitting diode (LED) to indicate that the thermal protection device has failed.

Abstract: A magnetic assembly includes a bobbin having at least first and second end flanges. The bobbin includes a channel wall displaced from the first end flange to from a channel therebetween. The channel receives and frictionally engages an I-core to retain the I-core in the channel. The bobbin includes a passageway that receives a middle leg of an E-core. The passageway includes a plurality of longitudinal ribs that extend from the first end flange toward the second end flange. The ribs are tapered with respect to the inner wall of the passageway. The middle leg of the E-core crushes the ribs. The frictional engagement of the crushed ribs with the middle leg retains the middle leg in the passageway. No taping, gluing or other additional step is required to assemble the bobbin and the two cores.

Abstract: Systems, methods and apparatuses for configuring an unpowered light emitting diode (LED) driver using an RS-232 interface are provided. An LED driver includes an RS-232 serial connector and an RS-232 serial interface controller coupled to the RS-232 serial connector. The RS-232 serial interface controller is configured to provide an RS-232 port for the LED driver. The LED driver includes a voltage regulator coupled between the RS-232 serial connector and the RS-232 serial interface controller. The voltage regulator is configured (i) to receive a voltage regulator input voltage at least in part from the RS-232 serial connector when operating in an unpowered tuning mode, and (ii) to output a regulated voltage. A controller of the LED driver is powered by the regulated voltage during an unpowered tuning operation of the LED driver.

Abstract: A magnetic device for an electronic circuit includes a printed circuit board. A first and second magnetic component assembly can be electrically connected to the printed circuit. The second magnetic component assembly can be stacked on the first magnetic component assembly. The first magnetic component assembly can be positioned between the second magnetic component assembly and the printed circuit board. Each magnetic component assembly can include a bobbin, a winding disposed on the bobbin, and a core extending through the bobbin. A second bobbin on the second magnetic component can be positioned on either a first core or a first bobbin of the first magnetic component assembly. The stacked magnetic component configuration can help reduce the board space required to electrically connect both the first and second magnetic component assemblies to the printed circuit board, which can help increase the power density of the magnetic device.

Abstract: A magnetic component for an electronic circuit includes a core having a core body and a core leg extending from the core body. The core body defines a core body height, and the core leg defines a core leg height less than the core body height. A conductive winding is positioned about the core leg. The winding defines a winding height. A winding height offset ratio is defined as the winding height divided by the core body height. In some embodiments the winding height offset ratio is less than about 1.1. The winding can be positioned on a bobbin structure disposed about the core leg. The magnetic component can be positioned in an enclosure to form an electronic device such as a power control or a power supply, and a thermally conductive gap-filler can be positioned between the magnetic component and the enclosure wall to dissipate heat from the magnetic component.

Abstract: A current source generates an output current having a nominal DC magnitude between a current output node and a reference node. The output current varies with respect to the nominal DC magnitude by a time-varying magnitude. An LED load and a sensing resistor are connected in series between the current output node and the reference node to receive at least a first portion of the output current as a load current. The load current flows through the sensing resistor and generates a sensed voltage proportional to the load current. A current regulator connected between the current output node and the reference node receives a second portion of the output current as a shunt current. The current regulator also receives the sensed voltage, and selectively increases or decreases the shunt current to reduce the effect of the time varying magnitude of the output current on the load current.

Abstract: A light fixture is provided or retrofitted with wireless LED lighting system requiring no additional wireless devices. An LED driver housing has power output terminals and control input terminals for an LED driver disposed therein. An LED lighting device includes driver input terminals to receive the output power from the LED driver, and to which an LED array and a wireless communication module are coupled to receive power therefrom. The wireless communication module comprises a transceiver configured to send and receive wireless communication signals with respect to an external device, and a controller linked to the transceiver and configured to generate lighting output control signals. Dimming control signals received via the transceiver may be processed by the controller and transmitted to the driver without requiring additional hardware or wiring within or attached to the driver. The lighting device also can wirelessly receive occupancy sensor data or LED configuration information.

Abstract: A protection system for an LED driver includes a voltage rail, an input voltage source, and a surge protector connected between the input voltage source and the voltage rail. The voltage change sensing block detects a change in a voltage associated with the input voltage source. The protection system further includes a voltage sensing block connected to the voltage change sensor. A half-bridge switching circuit may include a switch controller, a first switching element, and a second switching element. The switch controller controls an operating state of each of the first switching element and the second switching element. A reset block disables at least one of the switch controller, the first sensing element, and the second switching element, responsive to a control signal associated with at least one of the voltage change sensing block and the voltage sensing block.

Abstract: An LED driver circuit capable of being tuned via an unpowered tuning process and associated methods are provided. A radio frequency (RF) coupling circuit receives an RF tuning signal having a plurality of cycles of an RF carrier. The RF coupling circuit outputs a coupled RF tuning signal to a direct current (DC) generator circuit which rectifies the coupled RF tuning signal and outputs a rectified RF tuning voltage. A RF demodulation circuit receives the rectified RF tuning signal and selectively converts each burst of the rectified RF tuning signal to a single DC pulse. The RF demodulation circuit includes a Zener diode limiting the emitted voltage from the RF demodulation circuit. The microcontroller receives the output of the RF demodulation circuit, receives the regulated voltage, and controls one or more tuning operations of the LED driver circuit.

Abstract: An LED driver circuit provides a direct input line sensing step dimming interface for controlling an LED load. The LED driver circuit includes an input voltage source, a first input line, a second input line, and a neutral line. A diode bridge is coupled to the neutral line and to each of the first line switch and to the second line switch at a side of each opposite to the input voltage source. The LED driver circuit includes a first isolation circuit and a second isolation circuit and a microcontroller having a first sense input and a second sense input. The microcontroller receives at least one of the first sense input and the second sense input from the first and second isolation circuits. The microcontroller controls LED driver circuit output to a load according to the received sense input.

Abstract: A driver circuit provides current to a light source from a resonant tank having a single inductive element. The driver circuit is coupled to DC power source having a power rail and a ground, and includes a power inverter providing AC input to the tank, which further includes a DC blocking capacitor and a primary winding of the inductive element coupled in series between the output of the inverter and the ground. A leakage inductance of the inductive element provides resonant inductance for the tank. The inductive element further distributes power output from the resonant tank to a plurality of secondary windings coupled to an output rectifier. A resonant capacitor coupled across output ends of the secondary windings provides resonant capacitance for the tank. The output voltages across the secondary windings are clamped to a value based in part on a turns ratio between respective secondary windings.

Abstract: A magnetic assembly includes a bobbin and first and second cores. Each core has a main body. At least one of the cores has first and second outer legs and a center leg extending from the main body. The bobbin includes a first channel on a first end flange and a second channel on a second end flange. Each channel includes a plurality of crushable ribs that extend into the channel. The first and second cores are inserted into the respective first and second channels to engage and crush the crushable ribs. The crushed ribs frictionally engage the main bodies of the two cores to retain the two cores in a fixed relationship with the bobbin without requiring tape or glue. In one embodiment, both cores are E-cores. In another embodiment, one core is an extended E-core and the other core is an I-core.

Abstract: An LED driver circuit controls the currents through a plurality of strings of light-emitting diodes (LEDs), which are connected in series. Each LED string has an associated current regulator. The LED strings are connected between the voltage rail and a reference rail on the output of an AC-to-DC rectifier to receive an unfiltered rectified DC voltage. A first current regulator is active during a first voltage range of the DC voltage to provide a current of a first magnitude to a first LED string only. A second current regulator is active during a second voltage range to provide a current of a second magnitude to the first LED string and to a second LED string. A third current regulator is active during a third voltage range to provide a current of a third magnitude to the first LED string, to the second LED string and to a third LED string.

Abstract: A resonant power converter is provided with capacitive switching mode protection. The converter produces output current and voltage according to an operating frequency, which is desirably maintained above a resonant frequency for the power converter. A controller regulates the operating frequency based on an output current relative to a reference value, which may be provided via a dimming interface. A capacitive switching mode is determinable, based on a positive relationship in a detected direction of change in an output value relative to a detected direction of change in the operating frequency. When the capacitive switching mode is determined, a preceding operating frequency is enacted and the controller disables regulation of the operating frequency therefrom. Inductive mode switching is determinable with a negative relationship between detected direction of change in the output value relative to direction of change in the operating frequency, wherein regulation of operating frequency is renewed.

Abstract: A magnetic assembly includes a single bobbin structure that supports a first coil and a second coil. A first E-core has a center leg positioned within the first coil. A second E-core has a center leg positioned within the second coil. An I-core is positioned between the first E-core and the second E-core. The I-core completes a first set of magnetic paths between the center leg and outer legs of the first E-core and also completes a second set of magnetic paths between the center leg and outer legs of the second E-core. The two E-cores and the I-core are stacked in a vertical E-I-E configuration with respect to a common set of pin rails. In one embodiment, the first coil and the first E-core are configured as a transformer; and the second coil and the second E-core are configured as an inductor.

Abstract: A lighting apparatus includes a printed circuit board. A first light source and a second light source can be mounted on the printed circuit board. A first optical member can receive and redirect light from the first light source, and a second optical member can receive and redirect light from the second light source. A vent aperture can be defined in the printed circuit board, the vent aperture being positioned between the optical members. The apparatus can include first and second thermally conductive sheets thermally coupled to the printed circuit board, the first thermally conductive sheet disposed on a first back side of the first optical member, the second thermally conductive sheet disposed on a second back side of the second optical member. The apparatus can include a housing having a housing vent, the housing vent and the vent aperture defining a first convective path between the optical members.

Abstract: An adjustable auxiliary power supply for a light emitting diode (LED) driver for adjusting an auxiliary power output includes a voltage regulator configured to receive a regulator input voltage and to output an auxiliary power supply voltage selected from a first output voltage and a second output voltage according to a voltage selection signal used to control an LED lighting setting. The adjustable auxiliary power supply includes a first and second input voltage circuits configured to selectively output respective first and second input voltages to the voltage regulator. The adjustable auxiliary power supply includes an adjustable resistance circuit coupled to the voltage regulator. The adjustable resistance circuit controls the auxiliary power supply voltage based upon an adjustable resistance setting of the adjustable resistance circuit. The adjustable resistance setting is configured to correspond to at least one of the first output voltage and the second output voltage.