The present invention relates to an LED safety sign system, and more particularly, to an LED safety sign system in which a transparent printed circuit board including an LED and a control box mounted with a shock-detecting sensor are connected to each other so that when a shock equal to or greater than a predetermined value is applied to the control box or an automobile accident occurs, the LED of the transparent LED safety sign board automatically emits light to cause a red-edged triangular safety sign body to be lit to display a warning sign, and thus an emergency situation is identified by a driver at a remote distance, thereby preventing additional accident risks.

A vehicle illumination system for a vehicle capable of traveling in an automatic driving mode includes a left-side communication support lamp and a right-side communication support lamp configured to lit light toward an outside of the vehicle and arranged to be visually recognized from the front of the vehicle, and an illumination controller configured to, when the vehicle detects a target object, change an illumination state of at least one of the left-side communication support lamp and the right-side communication support lamp. Each of the left-side communication support lamp and the right-side communication support lamp includes a plurality of light-emitting segments arranged side by side in a right and left direction of the vehicle. The illumination controller is configured to change an illumination state of each of the plurality of light-emitting segments.

A system for implementing strobing of existing vehicle hazard lights including an interface to a vehicle wiring harness configured to receive input to an existing vehicle flasher module, and a strobing circuit that responds to an activation signal from the vehicle wiring harness that is indicative of a hazard flasher deployment event by producing an electrical output through the interface to the vehicle wiring harness that causes a strobing of existing vehicle hazard lamps.

Methods and systems for vehicle safety lighting are disclosed, including a system having a multi-axis accelerometer that detects acceleration of the vehicle along a first axis and a second axis normal to the first axis, and outputs a corresponding first axis acceleration measurement and a second axis acceleration measurement. A controller is coupled to the multi-axis accelerometer, and to an array of light emitter elements (LELs). The controller is configured to determine a vehicle deceleration, based at least in part on a combination of the first axis acceleration measurement and second axis acceleration measurement, and to detect the vehicle deceleration exceeding a brake light threshold and, based at least in part on the detection, output a deceleration light signal to the array of LELs. Digital filtering prevents operation of the safety lighting by accelerometer outputs unrelated to axial deceleration, such as will occur upon encountering a hill, or, in the case of a motorcycle or the like, leaning into a turn.

Apparatus and methods for indicating sudden deceleration may involve modifying a vehicle brake lighting system with a support frame supporting a deceleration sensor, microcontroller, an energy storage component, and power circuitry. A portable deceleration warning system includes a portable sensor unit with an accelerometer, a transmitter, a power supply, and a microprocessor, and at least one portable illumination unit with a light emitter, a receiver, and a power supply. The portable sensor unit mounts reversibly to a vehicle and the portable illumination unit can be worn by an operator or passenger of the vehicle or be temporarily attached to the vehicle.

A vehicle illumination system for a vehicle capable of traveling in an automatic driving mode includes a left-side communication support lamp and a right-side communication support lamp configured to lit light toward an outside of the vehicle and arranged to be visually recognized from the front of the vehicle, and an illumination controller configured to, when the vehicle detects a target object, change an illumination state of at least one of the left-side communication support lamp and the right-side communication support lamp. Each of the left-side communication support lamp and the right-side communication support lamp includes a plurality of light-emitting segments arranged side by side in a right and left direction of the vehicle. The illumination controller is configured to change an illumination state of each of the plurality of light-emitting segments.

A visual deceleration indicator signals to pedestrians and other vehicles that a vehicle is slowing down or coming to a stop. Illuminating devices, such as LEDs, contained in a license plate frame located in the front of the car or otherwise, are activated when the vehicle decelerates. An accelerometer or other sensory device detects deceleration and sends a signal to illuminate the LEDs, thereby letting others know the vehicle is slowing down. The license plate frame may be connected directly to a rear brake light component without the use of accelerometers or other sensors. When the brake is applied, the LEDs in the license plate frame are illuminated. The LEDs may be contained in other forms and located in different positions on the front or side of the car. The indicator might be one color to indicate braking and another color to indicate it is on, but not braking.

Disclosed is a master cylinder for a vehicle brake. The master cylinder includes a cylinder body provided with a hollow bore, a primary piston configured to perform a reciprocating motion in the hollow bore in linkage with a pedal, a secondary piston configured to move in linkage with the motion of the primary piston, and a Brake Light Stop (BLS) sensor module comprising a magnet provided at the primary piston and provided in a ring shape, and a hall sensor installed at an outer side of the cylinder body to correspond to the magnet and configured to control on/off operations of a brake lamp by sensing a magnetic flux density according to the reciprocating motion of the primary piston, wherein the magnet has both sides thereof supported by the primary piston and a return spring that is provided between the primary piston and the secondary piston, respectively.

A variable accelerator light assembly. The variable accelerator light assembly includes a light bar having light elements spanning between a first end and an opposing second end. A sensor connected to a vehicle accelerator pedal of a vehicle detects how much a user depresses the vehicle accelerator pedal, and transmits this information to the light bar. The light elements energize sequentially from a middle portion outward to the opposing first and second end. The progressive actuation of the vehicle accelerator pedal causes an increasing number of the light elements to energize in the sequential configuration.

The present invention relates to a brake controller for a towed vehicle braking system, including a housing or a loom, including an input connector for electrical connection to a towing vehicle and an output connector for electrical connection to a towed vehicle.