In a method for monitoring the operational reliability of a braking system in a vehicle. A brake pedal actuation is monitored via a brake light switch. An error signal is generated if the brake light switch generates a switch signal, without a braking intent of the driver being registered via a sensor signal of a sensor.

A vehicular, adaptive brake light to custom light sequencing system generally includes an OEM vehicular brake light circuit electrically connected to OEM brake lights of a vehicle, and an aftermarket flashing circuit electrically connected within or to the OEM vehicular brake light circuit to cause the OEM brake lights to flash. The system further includes an aftermarket directional indicator circuit electrically connected within or to the OEM vehicular brake light circuit and electrically connected to the aftermarket flashing circuit to effectuate a flashing of at least one of an OEM left brake light and an OEM right brake light. The system also includes an aftermarket hazard light circuit that is electrically connected within or to the OEM brake light circuit and to the aftermarket flashing circuit to effectuate a flashing hazard by the OEM brake lights. Alternate sequencing systems include solid state electronics and protection against environmental contaminants.

The condition responsive vehicular taillight is a safety device. The condition responsive vehicular taillight incorporates a vehicle and a control circuit. The control circuit mounts in the vehicle. The control circuit senses changes in the momentum of the vehicle. The control circuit generates a visual indication of the changes in the momentum of the vehicle. The visual indication is visible from the exterior of the vehicle. The visual indication is visible when viewed from the rear side of the vehicle.

An integrated electronic brake system includes a main control section configured in a first area to receive one or more of a value from a pedal sensor, a value from a cylinder pressure sensor, a value from a wheel speed sensor, or an EPB signal to perform EPB control and drive a main braking valve and a braking motor for the main braking of a vehicle, and to drive an additional braking valve for the additional braking, a sub-control section configured in a second area to receive one or more of the value from the pedal sensor, the value from the wheel speed sensor, or the EPB signal to perform the EPB control and drive the main braking valve and the braking motor through a bypass circuit, and a connection bus connecting the first area and the second area mounted in one box to transfer signals between the main control section and the sub-control section.

A brake lamp control method of a vehicle is provided. The method includes determining whether a deceleration of the vehicle based on regenerative brake through the electric motor is present in a hysteresis period between an off threshold as a reference for turning off a brake lamp and an on threshold as a reference for turning on the brake lamp. When the deceleration of the vehicle is present in the hysteresis period, the method includes determining a state of the brake lamp before the deceleration of the vehicle enters the hysteresis period. In response to determining that the brake lamp is turned on or off for a reason except for the regenerative brake before the deceleration of the vehicle enters the hysteresis period, a request for turning on the brake lamp is set or reset based on the regenerative brake in response to the determined state of the brake lamp.

A brake pump for vehicles having a pump body and an actuation device, operatively associated with the pump body. The actuation device being operable to generate a braking. A piston is housed inside a housing of the pump body, the piston being operable by the actuation device to vary the pressure of a brake fluid in a braking system to which the brake pump belongs, to generate the braking. The brake pump also has a switch group and an auxiliary actuation element.

A switch device may include a rod movable in association with an operation of a brake pedal, a main body case in which one end side of the rod is disposed, a movable board disposed in the main body case, and a connecting mechanism configured to connect the rod and the movable board. The movable board may be displaceable via the movement of the rod such that a movable contact point of the movable board is in contact with or separate from a fixed contact point. The connecting mechanism may include a protruding portion radially protruding from the rod, and a wall portion provided in the movable board. After pushing the rod into the main body case by a predetermined length, a tooth portion disposed on the protruding portion may mesh with a tooth portion disposed on the wall portion connecting the rod and the movable board.

A brake lamp control method of a vehicle is provided. The method includes determining whether a deceleration of the vehicle based on regenerative brake through the electric motor is present in a hysteresis period between an off threshold as a reference for turning off a brake lamp and an on threshold as a reference for turning on the brake lamp. When the deceleration of the vehicle is present in the hysteresis period, the method includes determining a state of the brake lamp before the deceleration of the vehicle enters the hysteresis period. In response to determining that the brake lamp is turned on or off for a reason except for the regenerative brake before the deceleration of the vehicle enters the hysteresis period, a request for turning on the brake lamp is set or reset based on the regenerative brake in response to the determined state of the brake lamp.

A taillight system including a brake light assembly, a connection assembly, a control assembly and a vehicle assembly. The brake light assembly includes a brake light having a display screen and LEDs. The connection assembly includes a connection plug that permits the brake light to be retrofitted onto existing vehicles. The brake light functions as standard brake lights do. However, the display screen and the LEDs allow for a personalized design selected by a user to be displayed and emitted by the LEDs. The design allows for the user to express their creativity and personality. The user may control the design, color and other features of the design with a remote or with a mobile device. Once the brake light is needed for standard functions of the vehicle the display screen corresponds with emitting those vehicle signals instead of the ornamental design.

Systems and methods for vehicle braking signals are described herein. In some embodiments, the system and methods improve the brake lights on automobiles.