Example embodiments relate to light system with anti-parallel LEDs. One example light system includes a driver configured to generate a DC current. The light system also includes at least one first group, a first group thereof including a first and a second LED connected in anti-parallel. The light system also includes at least one second group, a second group thereof including a first and a second LED connected in anti-parallel. The at least one second group is connected in series with the at least one first group. Additionally, the light system includes control circuitry configured for selectively operating the first and second group in at least one first one and at least one second mode.

A power adapter arrangement configured to provide power to a load is described. The power adapter arrangement may comprise a power adapter having a first interface comprising a first plurality of contact elements, and a second interface comprising a switch configured to control power applied to a load; and a control attachment removably coupled to the power adapter, wherein the control attachment comprises an actuator element configured to make contact with the power adapter in response to a manual actuation of the control attachment; wherein the actuator element is adapted to provide a signal to the power adapter in response to the manual actuation of the control attachment.

A power adapter arrangement configured to provide power to a load is described. The power adapter arrangement may comprise a power adapter having a first interface comprising a first plurality of contact elements, and a second interface comprising a switch configured to control power applied to a load; and a control attachment removably coupled to the power adapter, wherein the control attachment comprises an actuator element configured to make contact with the power adapter in response to a manual actuation of the control attachment; wherein the actuator element is adapted to provide a signal to the power adapter in response to the manual actuation of the control attachment.

An environmentally-friendly light-emitting diode (LED) with high reliability includes a first solder pad, a second solder pad and a plurality of LED dies. The LED dies are connected to each other in parallel and each of the LED dies has a positive electrode and a negative electrode. The positive electrode and the negative electrode of any one of the LED dies are respectively connected to the negative electrode and the positive electrode of the LED die adjacent thereto via two first conductive wires. The positive electrode and the negative electrode of one of the LED dies are respectively connected to the first solder pad and the second solder pad via two second conductive wires. The special parallel connection structure of the LED can achieve high reliability and satisfy the requirements of environmental protection.

The present disclosure discloses a lamp controller, comprising a DC power supply, a control unit and a switch unit that is controlled to be turned on or turned off by the control unit, an output end of the DC power supply is electrically connected to the control unit and the switch unit in respective, wherein the switch unit comprises three sets of switch circuits, each set of switch circuit comprises a load connecting part as well as a first switch tube and a second switch tube that are independently controlled by the control unit, a first pin of the first switch tube is connected to an output end of the control unit, a second pin of the first switch tube is connected to the DC power supply.

A lighting device is disclosed. An example lighting device includes at least one light emitting diode (“LED”) circuit having a plurality of LEDs, where the plurality of LEDs includes the same or differently colored LEDs. The lighting device also includes a driver including at least one bridge rectifier, a housing including a reflective material or coating, and a power source adapter. The driver receives an AC voltage from the power source adaptor and provides an output voltage to the at least one LED circuit. The lighting device also includes a circuit configured to electrically decouple the driver after detecting the output voltage of the driver is outside a predetermined voltage range.

A lighting device is disclosed. An example lighting device includes at least one light emitting diode (“LED”) circuit having a plurality of LEDs, where the plurality of LEDs includes the same or differently colored LEDs. The lighting device also includes a driver including at least one bridge rectifier, a housing including a reflective material or coating, and a power source adapter. The driver receives an AC voltage from the power source adaptor and provides an output voltage to the at least one LED circuit. The lighting device also includes a circuit configured to electrically decouple the driver after detecting the output voltage of the driver is outside a predetermined voltage range.

A white-light-emitting inorganic light-emitting-diode (iLED) structure comprises first iLEDs electrically connected in series, each first iLED emitting a different color of light from any other first iLED when electrical power is provided to the first iLEDs, and a second iLED electrically connected to one of the first iLEDs, the second iLED emitting the same color of light as the one of the first iLEDs when electrical power is provided to the first iLEDs. The second iLED can be electrically connected in series or in parallel with the one of the first iLEDs. Such iLED structures can be used at least in displays, lamps, and indicators.

A LED lamp string of easy welding, assembly and injection includes at least one rectifier, and multiple LED modules connected in series between positive and negative output ends of the at least one rectifier. Each LED module includes a first PCB, and the first PCB is provided with multiple first welding positions. The first welding positions are welded with a lamp bead and wires thereon. The lamp bead is connected to first ends of the wires, and a second end of the one wire of each LED module is directly connected to the at least one rectifier or is connected to the at least one rectifier after passing through at least one other LED module. It can realize the large-scale production of the welding equipment instead of manual welding, greatly improve the efficiency of the production, avoid false welding and improve the yield rate.

A control circuit for bypassing a diode current and a control method are provided; the control circuit includes a main module, a diode-current sensing module, a driving module; the diode-current sensing module is for sensing a current flowing through a main diode to generate a sensing current; the driving module is for generating a driving current proportional to the sensing current to drive a main switching transistor to be turned on; the main module, the diode-current sensing module, the driving module form a negative feedback loop to reduce the current flowing through the main diode to a preset value. The present disclosure solves problems in the related art, such as heat generation caused by large currents flowing through a body diode or flyback diode when the main switching transistor is in an off cycle, and the control circuit being out of control due to large currents introduced into a substrate.