Abstract: A luminaire otherwise lacking connectivity is provided hereby with an isolated method for connecting to a lighting control system. The luminaire comprises an NFC-equipped LED driver having a first antenna. A digital control device with a second antenna is permanently or semi-permanently mounted in or on the luminaire wherein the second antenna is positioned in operable proximity with the first antenna. The digital control device includes a first transceiver in communication with the external device and a first controller to receive and store device configuration data from the external device in volatile memory associated with a second transceiver linked to the first antenna. A controller associated with the LED driver selectively obtains the device configuration data from the volatile memory via the NFC field, and generates output current reference signals for regulating the output current from the LED driver, said reference signals corresponding to the device configuration data.

Abstract: A multiplier signal, and multiplier circuits and methods are provided to improve the total harmonic distortion (THD) and power factor (PF) for a flyback type power factor correction (PFC) circuit. The multiplier signal has a “pulled-up” waveshape that is configured to compensate for the “push-down” effect of varying off times of an electronic switch of the PFC on a line current of the PFC. The multiplier circuit is configured to reduce the multiplier signal during a first operational mode of the multiplier circuit and is further configured to maintain a typical multiplier signal during a second operational mode. The first operational mode occurs before a first phase angle and after a second phase angle during each half-cycle of a power source coupled to the PFC circuit. The second operational mode occurs between the first and second phase angles during each half-cycle.

Abstract: A dimming controller is coupled to receive an out-source current from a dimming interface for each LED driver connected thereto. Based on the out-source current received, the controller can estimate the number of connected LED drivers. When the LED driver(s) are determined to be on based on the received out-source current, the dimming controller generates and transmits a dimming control voltage. The dimming controller is programmable with relationships between the dimming control voltage and operational parameters for the certain type of LED driver and the certain type of LED load. The dimming controller then estimates the power characteristics (e.g., the input power and the output power) of the LED driver and associated LED load based on the programmed relationships. Power characteristics can accordingly be reported to the customer via a dimming controller without requiring specifically designed power measuring devices. Driver failure in the group can be reported in real time.

Abstract: A voltage feedback circuit for a power factor correction circuit couples an output voltage to a voltage feedback input terminal of the power factor correction circuit. The voltage feedback circuit includes a first voltage sensing resistor, a second voltage sensing resistor and a third voltage sensing resistor. A stabilization capacitor is connected across the third voltage sensing resistor. During a normal mode of operation, a feedback voltage has a magnitude determined by the first, second and third voltage sensing resistors. When the output voltage increases rapidly, the stabilization capacitor bypasses the increased voltage around the third voltage sensing resistor to cause the magnitude of the feedback voltage to be determined by only the first and second voltage sensing resistors. The power factor correction circuit detects a transient overvoltage condition at a lower output voltage than if the third voltage sensing resistor were not bypassed.

Abstract: A combination of a common-mode choke and two integrated RF inductors includes first and second E-core. At least one E-core includes first and second protrusions extending from a body portion. Each protrusion is configured to accommodate a respective winding. In a first embodiment, each protrusion extends from the body portion at an angle perpendicular to legs extending from the body portion. In a second embodiment, each protrusion extends from the body portion in an opposite direction from the legs extending from the body portion, and each protrusion includes a respective channel to receive a respective winding. In a third embodiment, each protrusion extends from the body portion in an opposite direction from the legs extending from the body portion, and each protrusion is sized and shaped to extend into a respective opening in a printed circuit board. Each opening is surrounded by a respective printed circuit winding.

Abstract: A lighting device (e.g. LED driver) includes digital dimming, configuration and firmware updating via wireless communication circuitry and associated volatile memory (e.g., SRAM). A power stage converts AC mains input into a DC bus voltage, and further converts the DC bus voltage into output current for driving a load. A power distribution circuit generates a regulated DC voltage based on the DC bus voltage. A wireless interface circuit is linked to a wireless communications network (e.g., NFC), and configured to receive device configuration data during at least first operating conditions when the regulated DC voltage is unavailable, and further to receive dimming control data during second operating conditions when the regulated DC voltage is available. A controller generates gate driving signals for regulating the output current from the power stage, said gate driving signals generated based at least in part on the device configuration data and the dimming control data.

Abstract: A lighting control system is provided to reduce the time, cost, and potential for error during device commissioning. A controller is programmed to obtain voice commands from a user and to identify and implement device commissioning modes based at least on the obtained voice commands. In a first commissioning mode, the controller configures one or more buttons or equivalent actuators on a control switch mounted in association with a lighting zone. In a second commissioning mode, the controller assigns device grouping and/or configuration data for a plurality of lighting devices (e.g., lighting fixtures, occupancy sensors, light sensors) in operable connection with the control switch. The controller may further in another commissioning mode identify one or more second lighting devices added to or exchanged with one or more of the plurality of first lighting devices and assign device grouping and/or configuration data thereto.

Abstract: A DC-to-AC inverter provides an AC voltage to the primary winding of an output isolation transformer having at least one secondary winding. An AC output voltage from the secondary winding is rectified to generate a DC voltage, which is applied to a load. The current flowing through the load is sensed and compared to a reference magnitude to produce a feedback signal. The feedback signal controls a voltage superposition circuit via an output stage of an optocoupler. The superposition circuit generates a superposition voltage that is applied to a current control circuit, which responds to the superposition voltage to vary a control current to a switching controller, which varies the frequency of the AC voltage to thereby vary the load current. A fault detection circuit senses a short in the output stage of the optocoupler to disable the operation of switching controller to prevent an overvoltage and an overcurrent.

Abstract: The present invention relates to an adaptable sensor assembly to be mounted to a light fixture in a fixture opening of the light fixture. A mount extends from the sensor housing. A break point is defined in the mount. First and second mount portions are located on either side of the break point. Each of the first and second mount portions are able to connect to the light fixture at the fixture opening. The first mount portion may connect to the light fixture if the light fixture has a large gasket lip, and the second portion may connect to the light fixture if the light fixture has a short gasket lip.

Abstract: A DC-to-AC inverter provides an AC voltage to the primary winding of an output isolation transformer having at least one secondary winding. An AC output voltage from the secondary winding is rectified to generate a DC voltage, which is applied to a load. The magnitude of a current flowing through the load is sensed and compared to a reference magnitude to produce a feedback signal. The feedback signal controls a voltage superposition circuit, which produces a superposition voltage. The superposition voltage is applied to an input node of a current control circuit. The current control circuit responds to the superposition voltage to vary a magnitude of a control current to a switching controller in the DC to-AC inverter. The switching controller is responsive to the control current magnitude to vary the frequency of the AC voltage and to thereby vary the load current.

Abstract: A driver circuit includes a load control circuit for supplementing a light emitting diode (LED) load in a low load condition. The low load condition corresponds to an output voltage across the LED load below a predetermined threshold voltage. The driver circuit includes an isolation transformer. A primary side circuit is coupled to a primary winding of the isolation transformer and includes a constant current control integrated circuit (IC) and a switch. The constant current control IC controls an output current to the LED load. A load control circuit is coupled to across the LED load and includes an auxiliary load which ensures that the isolation transformer operates in a continuous mode. The auxiliary load supplements the LED load with in a low load condition, but not in a high load condition. The auxiliary load may be configured to quickly discharge an output capacitor in a power off condition.

Abstract: A lighting device, and method of controlling a power stage thereof, is provided to stabilize operation at low output currents. An output current is sensed as a feedback signal and provided to control circuitry, which further defines upper and lower boundaries for a control band about an average sensed input control value. A reference signal corresponds to the average sensed input control value, wherein adjustments to the reference signal are enabled only when an actual sensed input control value extends beyond the control band. The upper and lower boundaries may be linearly or non-linearly approaching the average control value as a function of increases in the average control value, to prevent control adjustments in particular for low output current conditions. Control signals are generated for driving one or more switching elements in the power stage, based at least in part on the feedback signal and the generated reference signal.

Abstract: A lighting device is provided with input terminals that receive corresponding terminals from any one of an analog or digital dimming device or a driver configuration device. Depending on the type of connected device, different circuits are enabled by a controller to receive dimming control signals from an analog or digital dimming device, or to receive device configuration data from a multiple driver configuration device. A wireless interface circuit receives and stores configuration data via an antenna. The controller automatically detects whether one of the analog or digital dimming device or the driver configuration device is coupled to the input terminals, enables a corresponding one of the analog and digital interface circuit or the driver configuration interface circuit, and generates output current reference signals for regulating the output current from the driving circuit, said reference signals corresponding to the received dimming control signals via the analog and digital interface circuit.

Abstract: A DC-to-AC inverter provides an AC voltage to the primary winding of an output isolation transformer having at least one secondary winding and having an auxiliary winding. The current supplied to a secondary load is reflected back into the primary winding as a reflected secondary current. A first feedback signal has a reflected secondary current component and has a primary magnetizing current component. An auxiliary winding voltage is applied to an inductor to generate an auxiliary current proportional to the primary winding magnetizing current. A second feedback signal is responsive to the auxiliary current. The second feedback signal is combined with the first feedback signal to produce a total feedback signal responsive only to the reflected secondary current. The DC-to-AC inverter responds to the total feedback signal and a reference signal to adjust the AC voltage to maintain the total feedback signal at a magnitude corresponding to the reference signal.

Abstract: A power converter as disclosed herein includes circuitry to reduce switching current spikes as conventionally appear at startup, and control the current spikes in a predictable way, thereby improving reliability of the power converter. A controller generates drive signals to half-bridge switching elements, an output therefrom corresponding to a frequency of the gate drive signals. A resonant tank comprises a resonant capacitor, DC blocking capacitor, a resonant inductor, and a load. Pre-charge circuitry is coupled to the resonant tank and, after initially receiving power from the DC power source and prior to controller startup, pre-charges at least the DC blocking capacitor to a steady state operating value. By pre-charging the DC blocking capacitor to its steady state voltage even before startup of the controller, AC current is introduced into the resonant inductor after the low-side switching element is first turned on and soft switching is provided throughout.

Abstract: A surge protection device for an LED lighting system provides a failure detection circuit which shuts off an indicator lamp when upon failure of surge protection components. Surge suppression circuits are coupled between respective first and second, and second and third lines for receiving an AC mains input. The surge suppression circuits include a thermal cutoff device and a clamping device, with a fault detection circuit coupled between each respective series circuit. The fault detection circuit activates an indicator lamp when the surge protection device is in a normal operation mode. The fault detection circuit shuts off the indicator lamp when the surge protection device is in a short circuit fault mode, corresponding to failure of at least one component from a surge suppression circuit. Detection of an unlit indicator lamp may serve as a warning to an operator that the associated surge protection device should be replaced.

Abstract: A system and a method offset the effect of a reduced load current on a power factor controller connected to a DC-to-DC converter having a switching DC-to-AC inverter driving an output rectifier that produces the load current. A frequency-dependent load impedance is coupled to the output of the inverter. The frequency-dependent load impedance is configured to have a first impedance when the inverter is operating at the minimum operating frequency. The frequency-dependent load impedance has a second impedance when the inverter is operating at the maximum operating frequency. The second impedance is lower than the first impedance and produces a dummy load current that is added to the actual load current to provide a sufficient total load current to cause the power factor controller to operate in a continuous mode even when the actual load current is insufficient to cause the power factor controller to operate in a continuous mode.

Abstract: A lighting system includes various ballasts or LED drivers having respective dimming interface circuits coupled in parallel to an external dimming device. Each device includes a controller regulating output to a lighting load based on desired dimming output. Dimming interface circuits coupled are between the controller and the external dimming device, each configured to dynamically adapt a level of constant current sourced from the dimming interface circuit to the external dimming device via first and second interface terminals, based on a determined analog mode or digital mode associated with the external device. The dimming interface circuit generates dimming control signals to the controller based on dimming input signals received via the first and second interface terminals, and in a digital mode, the interface circuit generates digital pulse signals to the external dimming device via the interface terminals for bidirectional communications therewith.

Abstract: An LED driver is provided having a gate drive integrated circuit with an adaptive operating mode which operates between a first operating mode and a second operating mode. The gate drive integrated circuit is designed to primarily operate in the first operating mode which includes a predetermined minimum on-time and a predetermined maximum off-time for enabling and disabling gate drive signals to a switch, respectively. The second operating mode begins at the minimum on-time and the maximum off-time. The LED driver further includes a controller configured to monitor an on-time and an off-time of the gate drive signals. The controller is further configured responsive to the second operating mode to fix the on-time equal to the predetermined minimum on-time and to continually adjust the off-time greater than or equal to the maximum off-time.

Abstract: A connector assembly suppresses electromagnetic interference (EMI) generated by electronic circuitry on a printed circuit board (PCB). Certain embodiments of the connector assembly include common features such as conductive through-holes on the PCB, and a connector having terminal pins positionable through the conductive through-holes. The first embodiment includes a magnetic wafer positionable between the connector and the PCB. The second embodiment includes a plurality of stackable magnetic wafers positionable in a stack between the connector and the PCB. The third embodiment includes a magnetic cup wafer positionable between the connector and the PCB. The fourth embodiment, combines the cup wafer with the stackable magnetic wafers of the second and third embodiments. Each magnetic wafer includes wafer holes for the terminal pins to pass through. The magnetic wafers are configured to increase inductance and provide effective EMI noise suppression.