Various embodiments may include a dimmer system for controlling the power consumption of a load that can be connected with parallel-connected galvanically isolated dimming channels. The dimmer system may include a plurality of dimming channels, each dimming channel including a sensor for monitoring a temperature of associated switch elements; and a control unit for each dimming channel, the control units configured to shift a respective dimming edge based at least in part on the temperature to distribute power dissipation of the connected load substantially equally across the plurality of dimming channels.

Various embodiments may include a dimmer system for controlling the power consumption of a load that can be connected with parallel-connected galvanically isolated dimming channels. The dimmer system may include a plurality of dimming channels, each dimming channel including a sensor for monitoring a temperature of associated switch elements; and a control unit for each dimming channel, the control units configured to shift a respective dimming edge based at least in part on the temperature to distribute power dissipation of the connected load substantially equally across the plurality of dimming channels.

A controller for controlling a light source module including a first LED array and a second LED array includes a power input terminal, a first power output terminal and a second power output terminal. The power input terminal is operable for receiving electric power from a power converter. The first power terminal is coupled to the first LED array, and the second power output terminal is coupled to the second LED array. The controller is operable for delivering the electric power to the first LED array via the first power output terminal in a first sequence of discrete time slots, and for delivering the electric power to the second LED array via the second power output terminal in a second sequence of discrete time slots. The first sequence of discrete time slots and the second sequence of discrete time slots are mutually exclusive.

The invention relates to a connected device system that is adapted to form a low-bandwidth wireless mesh network (2) between a plurality of devices (3, 4, 5, 6). The connected device system (1) comprises multiple output devices (3, 4, 5) for outputting human-perceptible stimuli and a controller device (6) for controlling the stimulus outputs of the multiple output devices via the wireless mesh network. The controller device is adapted to switch a group of the multiple output devices from a first control mode, in the stimulus outputs are controlled by control messages of a first type, to a second control mode, in which the stimulus outputs are controlled by control messages of a second type. The control messages of the second type are transmitted to the output devices of the group at a higher rate than the control messages of the first type.

The invention relates to a connected device system that is adapted to form a low-bandwidth wireless mesh network (2) between a plurality of devices (3, 4, 5, 6). The connected device system (1) comprises multiple output devices (3, 4, 5) for outputting human-perceptible stimuli and a controller device (6) for controlling the stimulus outputs of the multiple output devices via the wireless mesh network. The controller device is adapted to switch a group of the multiple output devices from a first control mode, in the stimulus outputs are controlled by control messages of a first type, to a second control mode, in which the stimulus outputs are controlled by control messages of a second type. The control messages of the second type are transmitted to the output devices of the group at a higher rate than the control messages of the first type.

An LED tube lamp with overvoltage protection capability is provided. The LED tube lamp includes a lamp tube, two external connection terminals, a rectifying circuit, a filtering circuit, an LED module, and a protection circuit. The protection circuit is coupled between two input terminals of the LED module and configured to perform overvoltage protection when determining that a voltage level between the two input terminals of the LED module reaches or is higher than a predefined voltage value, wherein the protection circuit includes a diode and the predefined voltage value is in a range of about 40V to about 600V.

Disclosed is a phase-cut dimmer, comprising an AC switch coupled in series between an AC supply and a load; a DC power supply powered from a voltage across the switch; a zero-crossing detector of a phase-cut AC voltage across the switch; a timer generating a timing signal of a duty-cycle proportional to a variable fraction of a peak voltage of a sawtooth signal, wherein the sawtooth signal is synchronized to the zero-crossing detector; a blanking signal generator triggered by a duty-cycle detector to reduce the duty-cycle when the duty-cycle of the timing signal exceeds a predetermined maximum limit; and an operation mode selector activated by an output of an inductive load detector.

A LED controller for an LED pixel array includes a switch K1 activated in response to a row and column select signal; a switch K2 activated in response to a pulse width modulation duty cycle; and a switch K3 providing a current source from Vbias. Pixel activation is determined at least in part by state of switch K1 and K2. In operation, the LED pixel in the LED pixel array is selected by switch K1 and a fault determination for the LED pixel is made based on determined Vf on a Vf bus.

Techniques are disclosed for systems and methods to provide lighted vehicle beaconing, particularly for micro-mobility fleet vehicles. A lighted vehicle beaconing system includes a vehicle light assembly configured to be coupled to and/or integrated with a micro-mobility fleet vehicle and a logic device configured to communicate with the vehicle light assembly. The vehicle light assembly includes a programmable light element configured to receive a lighting control sequence and generate a multicolored and/or animated lighting sequence corresponding to the received lighting control sequence. The logic device is configured to determine the lighting control sequence and to generate the multicolored and/or animated lighting sequence by providing the lighting control sequence to the programmable light element of the vehicle light assembly.

A load control device (such as, a dimmer switch) for controlling the amount of power delivered from an AC power source to an electrical load (such as, a high-efficiency lighting load) includes a thyristor (such as, a triac) coupled between the source and the load, a gate coupling circuit arranged to conduct current through a gate terminal of the thyristor, and a control circuit configured to control the gate coupling circuit. The control circuit may control the gate coupling circuit to conduct a pulse of current through the gate terminal to render the thyristor conductive at a firing time during a present half cycle of the AC power source, and allow the gate coupling circuit to conduct at least one other pulse of current after the firing time during the present half cycle.