Abstract: A method for testing an emergency lighting product connected to a network includes creating, at a network control device, a first test schedule for causing the emergency lighting product to perform a test, where the test is scheduled to be performed by the emergency lighting product based on a signal received from the network control device after a first time period. The method further includes creating, at the emergency lighting product, a second test schedule for causing the emergency lighting product to perform the test after a second time period, where the second time period is longer than the first time period and begins at the same time as the first time period, and determining, by the emergency lighting product after the second time period, that the signal has not been received from the network control device, and performing, by the emergency lighting product, the test.

Abstract: A method for testing an emergency lighting product connected to a network includes creating, at a network control device, a first test schedule for causing the emergency lighting product to perform a test, where the test is scheduled to be performed by the emergency lighting product based on a signal received from the network control device after a first time period. The method further includes creating, at the emergency lighting product, a second test schedule for causing the emergency lighting product to perform the test after a second time period, where the second time period is longer than the first time period and begins at the same time as the first time period, and determining, by the emergency lighting product after the second time period, that the signal has not been received from the network control device, and performing, by the emergency lighting product, the test.

Abstract: Aspects are described for a test configuration for emergency lighting fixtures. In one example, a light fixture includes a lighting element, a battery, a clock, and a processor. The processor is configurable via a user interface. The processor is configured to test the light fixture. The testing includes illuminating the lighting element for a predetermined duration using the battery as a power source. The testing is initiated by a timer that uses the clock. The processor of the light fixture receives input, via the user interface, adjusting a value for the start timer. Based on the start timer expiring, the processor initiates a test of the light fixture for the predetermined duration. The processor further indicates a result of the test via the user interface. Based on the test being successful, the processor resets the start timer.

Abstract: Aspects are described for dual-distribution lighting devices. For example, a dual-distribution lighting device includes a forward-throw module with a first lighting element that can provide directional light, a wide-throw module with a second lighting element that can provide light with a wide distribution, an interface element that can to receive input, and a processing device. In response to the input being received via the interface element, the processing device deactivates one of the forward-throw and wide-throw modules and activates the other of the forward-throw and wide-throw modules, thereby causing the dual-distribution lighting device to switch between providing directional light and a wide distribution of light.

Abstract: Aspects are described for dual-distribution lighting devices. For example, a dual-distribution lighting device includes a forward-throw module with a first lighting element that can provide directional light, a wide-throw module with a second lighting element that can provide light with a wide distribution, an interface element that can to receive input, and a processing device. In response to the input being received via the interface element, the processing device deactivates one of the forward-throw and wide-throw modules and activates the other of the forward-throw and wide-throw modules, thereby causing the dual-distribution lighting device to switch between providing directional light and a wide distribution of light.

Abstract: Aspects are described for a test configuration for emergency lighting fixtures. In one example, a light fixture includes a lighting element, a battery, a clock, and a processor. The processor is configurable via a user interface. The processor is configured to test the light fixture. The testing includes illuminating the lighting element for a predetermined duration using the battery as a power source. The testing is initiated by a timer that uses the clock. The processor of the light fixture receives input, via the user interface, adjusting a value for the start timer. Based on the start timer expiring, the processor initiates a test of the light fixture for the predetermined duration. The processor further indicates a result of the test via the user interface. Based on the test being successful, the processor resets the start timer.

Abstract: An enhanced battery saving capacity device (200) and method (300) is disclosed. In its simplest form, the method (300) includes the steps of: detecting (310) an off state by detecting a load current below a threshold; and entering (320) a battery saver mode including a duty cycle test period, by: providing a periodic test signal; disconnecting a battery for a first interval of time; and reconnecting the battery for a second interval in synchronization with the periodic test signal, to determine whether the load current exceeds the threshold. The method (300) can reduce power drain when an electronic device is off or stored for an extended period of time. It can also extend the shelf life and minimize the possibility of damage to the life cycle of a battery, by lowering the possibility of severe discharge of a battery.

Abstract: A system and method for wireless charging are provided. A control circuit charges one or more cells in a secondary wireless charging circuit that receives power wirelessly from a primary. The control circuit determines the state of charge and temperature of the cells. The control circuit then calculates a current limit as a function of a combination of the state of charge, input voltage to the control circuit for the wireless controller, FET power dissipation and the temperature and adjusts a wireless power control device in the secondary such that its current limit is set to the state of charge current limit. Different temperature limits can be used for different states of charge such that the cells can be charged at higher temperatures at low states of charge than at higher states of charge.

Abstract: Methods and apparatus for dynamically adjusting an over-current protection threshold (514) are disclosed. A dynamic over-current protection circuit (104) receives a first trigger to switch to a high discharge current mode. The dynamic over-current protection circuit (104) starts a high-current timer (210) and increases the over-current protection threshold (514) in response to receiving the trigger. The dynamic over-current protection circuit (104) decreases the over-current protection threshold (514) and starts a hold-off timer (212) in response to an expiration of the high current timer (210). The hold-off timer (212) prevents a second trigger from causing a switch to the high discharge current mode until the hold-off timer expires.

Abstract: Methods and apparatus for dynamically adjusting an over-current protection threshold (514) are disclosed. A dynamic over-current protection circuit (104) receives a first trigger to switch to a high discharge current mode. The dynamic over-current protection circuit (104) starts a high-current timer (210) and increases the over-current protection threshold (514) in response to receiving the trigger. The dynamic over-current protection circuit (104) decreases the over-current protection threshold (514) and starts a hold-off timer (212) in response to an expiration of the high current timer (210). The hold-off timer (212) prevents a second trigger from causing a switch to the high discharge current mode until the hold-off timer expires.

Abstract: A system (300) and method (400) for wireless charging are provided. A control circuit (304) charges one or more cells (301) in a secondary wireless charging circuit (308) that receives power wirelessly from a primary (312). The control circuit determines the state of charge and temperature of the cells. The control circuit then calculates a current limit as a function of a combination of the state of charge, input voltage to the control circuit for the wireless controller, FET power dissipation and the temperature and adjusts a wireless power control device (305) in the secondary such that its current limit is set to the state of charge current limit. Different temperature limits can be used for different states of charge such that the cells can be charged at higher temperatures at low states of charge than at higher states of charge.

Abstract: An enhanced battery saving capacity device (200) and method (300) is disclosed. In its simplest form, the method (300) includes the steps of: detecting (310) an off state by detecting a load current below a threshold; and entering (320) a battery saver mode including a duty cycle test period, by: providing a periodic test signal; disconnecting a battery for a first interval of time; and reconnecting the battery for a second interval in synchronization with the periodic test signal, to determine whether the load current exceeds the threshold. The method (300) can reduce power drain when an electronic device is off or stored for an extended period of time. It can also extend the shelf life and minimize the possibility of damage to the life cycle of a battery, by lowering the possibility of severe discharge of a battery.