Devices, systems and methods for controlling an exterior and dashboard lights of an autonomous vehicle are described. One example of a method for controlling one or more exterior lights includes receiving, from an autonomous driving system (ADS) of the vehicle, an input to control one or more exterior lights that are part of a lighting system of the vehicle, and transmitting, based on the input, a message to a controller area network (CAN) bus of the lighting system, the message being further based on a driver command upon a determination that a driver-initiated message is received. In an example, the lighting system of the vehicle further comprises a plurality of dashboard lights.

Devices, systems and methods for controlling an exterior and dashboard lights of an autonomous vehicle are described. One example of a method for controlling one or more exterior lights includes receiving, from an autonomous driving system (ADS) of the vehicle, an input to control one or more exterior lights that are part of a lighting system of the vehicle, and transmitting, based on the input, a message to a controller area network (CAN) bus of the lighting system, the message being further based on a driver command upon a determination that a driver-initiated message is received. In an example, the lighting system of the vehicle further comprises a plurality of dashboard lights.

A light-emitting diode (LED) luminaire comprising a battery-backup portion is used to replace a luminaire operated only with alternate-current (AC) mains. The battery-backup portion comprises a rechargeable battery, a self-diagnostic circuit, and a front-end communication circuit. The self-diagnostic circuit comprises timers and is configured to provide test schedules and to auto-evaluate battery performance according to the test schedules with test results stored. The LED luminaire further comprises a remote user interface and a concentrator communication circuit configured to communicate with the front-end communication circuit configured to send the test results to the concentrator communication circuit as soon as a rechargeable battery test is performed. When the remote control signals are initiated by the remote user interface with spread-spectrum modulated signals transmitted, the front-end communication circuit can demodulate such signals and subsequently send commands to the self-diagnostic circuit to respond accordingly.

A light-emitting diode (LED) luminaire comprising a battery-backup portion is used to replace a luminaire operated only with alternate-current (AC) mains. The battery-backup portion comprises a rechargeable battery, a self-diagnostic circuit, and a front-end communication circuit. The self-diagnostic circuit comprises timers and is configured to provide test schedules and to auto-evaluate battery performance according to the test schedules with test results stored. The LED luminaire further comprises a remote user interface and a concentrator communication circuit configured to communicate with the front-end communication circuit configured to send the test results to the concentrator communication circuit as soon as a rechargeable battery test is performed. When the remote control signals are initiated by the remote user interface with spread-spectrum modulated signals transmitted, the front-end communication circuit can demodulate such signals and subsequently send commands to the self-diagnostic circuit to respond accordingly.

A lighting control device that controls lighting fixtures includes: a command generator that generates one or more commands for controlling the lighting fixtures; a signal transceiver that communicates with the lighting fixtures; and a communication protocol setter that sets which one of two or more types of communication protocols is to be used. The two or more types of communication protocols include a first communication protocol. The signal transceiver simultaneously transmits, using the first communication protocol, a first command to each of the lighting fixtures. The first command is included in the one or more commands and requests a response. The communication protocol setter sets the first communication protocol as the communication protocol to be used for one or more of the lighting fixtures that have responded to the first command.

A lighting control device that controls lighting fixtures includes: a command generator that generates one or more commands for controlling the lighting fixtures; a signal transceiver that communicates with the lighting fixtures; and a communication protocol setter that sets which one of two or more types of communication protocols is to be used. The two or more types of communication protocols include a first communication protocol. The signal transceiver simultaneously transmits, using the first communication protocol, a first command to each of the lighting fixtures. The first command is included in the one or more commands and requests a response. The communication protocol setter sets the first communication protocol as the communication protocol to be used for one or more of the lighting fixtures that have responded to the first command.

The present invention provides a transceiver (1) for a local lighting system (L1), preferably a local lighting system based on the DALI-2 industry standard, comprising a bus (2) and a control unit (3) electrically connected to the bus (2) for controlling communication via the bus (2). The transceiver (1) comprises a transmitter (1a) configured to transmit wireless signals to a global lighting system (14) comprising one or more luminaires (L2 LN), a receiver (1b) configured to receive wireless signals from the global lighting system (14), and a processing unit (1c) configured to process the received wireless signals from the global lighting system (14). The processing unit (1c) of the transceiver (1) is configured to convert the received wireless signals into bus signals such that the transceiver (1) behaves as an input device of the local lighting system (L1) when electrically connected to the bus (2).

The present invention provides a transceiver (1) for a local lighting system (L1), preferably a local lighting system based on the DALI-2 industry standard, comprising a bus (2) and a control unit (3) electrically connected to the bus (2) for controlling communication via the bus (2). The transceiver (1) comprises a transmitter (1a) configured to transmit wireless signals to a global lighting system (14) comprising one or more luminaires (L2 LN), a receiver (1b) configured to receive wireless signals from the global lighting system (14), and a processing unit (1c) configured to process the received wireless signals from the global lighting system (14). The processing unit (1c) of the transceiver (1) is configured to convert the received wireless signals into bus signals such that the transceiver (1) behaves as an input device of the local lighting system (L1) when electrically connected to the bus (2).

A method of automatically programming a new load control device that replaces an old load control device takes advantage of a remote identification tag (e.g., an RFID tag) located in the vicinity of the old device. The remote identification tag stores an identifier that is representative of a location in which the old device is installed. The method includes the steps of: (1) storing a setting of an old device in a memory of a controller; (2) associating the setting with the identifier of the old device in the memory of the controller; (3) the new device retrieving the identifier from the remote identification tag after the new device is installed in the location of the old device; (4) the new device transmitting the identifier to the controller; and (5) the controller transmitting the setting of the old device to the new device in response to receiving the identifier.

A method of automatically programming a new load control device that replaces an old load control device takes advantage of a remote identification tag (e.g., an RFID tag) located in the vicinity of the old device. The remote identification tag stores an identifier that is representative of a location in which the old device is installed. The method includes the steps of: (1) storing a setting of an old device in a memory of a controller; (2) associating the setting with the identifier of the old device in the memory of the controller; (3) the new device retrieving the identifier from the remote identification tag after the new device is installed in the location of the old device; (4) the new device transmitting the identifier to the controller; and (5) the controller transmitting the setting of the old device to the new device in response to receiving the identifier.