A smart landing pad comprises a flexible display that shows images or patterns, and a protective layer over the display. The protective layer allows a UAV to land without damaging the display. Locator and range finder devices, coupled to the display, communicate with the UAV. The display is operative for wireless communications with a computer or mobile device that provides on-demand user functions, allowing for dynamically changing or customizing the images/patterns shown on the display. The images/patterns comprise a background area showing changeable images that match an environment where the landing pad is placed, and a target landing area surrounded by the background area. The target landing area includes a changeable insensitive, contrast portion, and changeable marker pattern portions having changeable colors/shapes. The images/patterns also include changeable QR codes on the target landing area. The display is IoT enabled so that data from the landing pad is remotely cloud accessible.

A lighting device for an airport runway with a base carrier, at which at least one lighting unit is fastened, with the lighting unit comprising a light source, a reflector, and a covering glass panel, with the light source and the reflector being combined to a joint lighting module, with the light source and the reflector being assembled on a joint carrier of the lighting module connected to the base carrier in a detachable fashion.

A system and method for a recharging station including a landing pad, a rechargeable component coupled to the landing pad, a power delivery unit configured to deliver powerfrom a power supply unit or power storage unit to the recharging component, and a support component coupled to the bottom of the landing pad.

A system and method for a recharging station including a landing pad, a rechargeable component coupled to the landing pad, a power delivery unit configured to deliver powerfrom a power supply unit or power storage unit to the recharging component, and a support component coupled to the bottom of the landing pad.

A runway light control including a relay switch for connecting to a common conductor and a push-to-talk conductor of the aircraft communications system. The control includes a microcontroller connected to the relay switch and an intensity selector assembly connected to the microcontroller. The selector assembly has first, second, and third intensity selectors. The microcontroller is programmed to intermittently close the relay switch a first preselected number of times when the first intensity selector is actuated to signal the automated variable intensity runway light control station to select a first runway light intensity at the airport. The microcontroller is programmed to close the relay switch a second number of times when the second selector is actuated to select a second runway light intensity. The microcontroller is programmed to close the relay switch a third number of times when the third selector is actuated to select a third runway light intensity.

A runway light control including a relay switch for connecting to a common conductor and a push-to-talk conductor of the aircraft communications system. The control includes a microcontroller connected to the relay switch and an intensity selector assembly connected to the microcontroller. The selector assembly has first, second, and third intensity selectors. The microcontroller is programmed to intermittently close the relay switch a first preselected number of times when the first intensity selector is actuated to signal the automated variable intensity runway light control station to select a first runway light intensity at the airport. The microcontroller is programmed to close the relay switch a second number of times when the second selector is actuated to select a second runway light intensity. The microcontroller is programmed to close the relay switch a third number of times when the third selector is actuated to select a third runway light intensity.

Methods, devices, and systems for airfield luminaire vibration monitoring are described herein. In some examples, one or more embodiments include a computing device comprising a memory and a processor to execute instructions stored in the memory to receive a vibration signal from a sensor on an airfield luminaire, compare the vibration signal from the sensor to a vibration profile for the airfield luminaire, and determine a status of a bolt of the airfield luminaire based on the comparison.

A runway-embedded flash lighting device, includes a body configured to be embedded in a runway; a ceiling member including a flash emission window and disposed in an upper opening of the body and configured to be exposed to a runway surface when the body is embedded in the runway; a light guide member disposed in the flash emission window; an LED flash light source disposed inside the body and configured to emit a flash toward the light guide member; and a heat conducting member, wherein the light guide is configured to allow the flash emitted from the LED flash light source to be emitted from the flash emission window, the heat conducting member is disposed inside the body and includes a first part in contact with the LED flash light source, and a second part in contact with the ceiling member.

A runway-embedded flash lighting device, includes a body configured to be embedded in a runway; a ceiling member including a flash emission window and disposed in an upper opening of the body and configured to be exposed to a runway surface when the body is embedded in the runway; a light guide member disposed in the flash emission window; an LED flash light source disposed inside the body and configured to emit a flash toward the light guide member; and a heat conducting member, wherein the light guide is configured to allow the flash emitted from the LED flash light source to be emitted from the flash emission window, the heat conducting member is disposed inside the body and includes a first part in contact with the LED flash light source, and a second part in contact with the ceiling member.

A light fixture is provided with a heating element. The heating element can be a resistive heating element, such as a Nichrome wire, and resides in grooves of a cover (e.g., a glass globe) of the light fixture. Thus, the heating element acts to directly heat the cover of the light fixture to prevent, decrease, or otherwise correct frosting, freezing, and other elemental effects on the cover when it is exposed to the environment. The heating element is capable of raising the temperature of the cover at least 15° C. from an initial temperature of −20° C. in 30 minutes. A heat sensing element may provide feedback regarding the temperature of the cover for controlling power supplied to the heating element.