Abstract: A charge utilization control system for an electric vehicle includes a controller, an electric motor connected to the controller, a battery connected to the electric motor and an internal combustion engine connected to the controller. The controller is adapted to minimize electric charge stored in the battery as the electric vehicle approaches a charging destination for the battery.

Abstract: A method is provided that includes determining a state of a vehicle ignition switch; determining a state of the vehicle, wherein the vehicle state including at least one of whether the vehicle is in a torque producing mode, whether the vehicle is moving, and whether the vehicle brake system is engaged; and, controlling the vacuum pump in response to the vehicle state and the ignition switch state.

Abstract: A method is provided that includes determining a state of a vehicle ignition switch; determining a state of the vehicle, wherein the vehicle state including at least one of whether the vehicle is in a torque producing mode, whether the vehicle is moving, and whether the vehicle brake system is engaged; and, controlling the vacuum pump in response to the vehicle state and the ignition switch state.

Abstract: An electric vacuum pump backup control system includes a brake on/off switch, a primary electric vacuum pump control interfacing with the brake on/off switch, a secondary electric vacuum pump control interfacing with the brake on/off switch and the primary electric vacuum pump control and an electric vacuum pump interfacing with the primary electric vacuum pump control.

Abstract: A method and system for fuel vapor control in a hybrid vehicle (HEV). The HEV fuel vapor recovery system includes a fuel tank isolation valve, which is normally closed to isolate storage of refueling from storage of diurnal vapors. The method for fuel vapor control includes selectively actuating the fuel tank isolation valve during interrelated routines for refueling, fuel vapor purging, and emission system leak detection diagnostics to improve regulation of pressure and vacuum the HEV fuel vapor recovery system.

Abstract: A method and system for fuel vapor control in a hybrid vehicle (HEV). The HEV fuel vapor recovery system includes a fuel tank isolation valve, which is normally closed to isolate storage of refueling from storage of diurnal vapors. The method for fuel vapor control includes selectively actuating the fuel tank isolation valve during interrelated routines for refueling, fuel vapor purging, and emission system leak detection diagnostics to improve regulation of pressure and vacuum the HEV fuel vapor recovery system.

Abstract: A braking system for a vehicle includes an active booster master cylinder connected with the wheel cylinders, and a controller for operating active booster master cylinder during braking. The primary master cylinder, which is located remotely from the active booster master cylinder, is selectably connected with either a pedal feel emulator or a servo system which applies the brakes using the active booster master cylinder and a hydraulic output from the primary master cylinder in the event that control of the active booster master cylinder becomes impaired.

Abstract: A method and system for fuel vapor control in a hybrid vehicle (HEV). The HEV fuel vapor recovery system includes a fuel tank isolation valve, which is normally closed to isolate storage of refueling from storage of diurnal vapors. The method for fuel vapor control includes selectively actuating the fuel tank isolation valve during interrelated routines for refueling, fuel vapor purging, and emission system leak detection diagnostics to improve regulation of pressure and vacuum the HEV fuel vapor recovery system.

Abstract: A method and system for fuel vapor control in a hybrid vehicle (HEV). The HEV fuel vapor recovery system includes a fuel tank isolation valve, which is normally closed to isolate storage of refueling from storage of diurnal vapors. The method for fuel vapor control includes selectively actuating the fuel tank isolation valve during interrelated routines for refueling, fuel vapor purging, and emission system leak detection diagnostics to improve regulation of pressure and vacuum the HEV fuel vapor recovery system.

Abstract: A charge utilization control system for an electric vehicle includes a controller, an electric motor connected to the controller, a battery connected to the electric motor and an internal combustion engine connected to the controller. The controller is adapted to minimize electric charge stored in the battery as the electric vehicle approaches a charging destination for the battery.

Abstract: An electro-hydraulic brake-by-wire system includes a brake pedal, an electronic booster coupled to the brake pedal, a master cylinder coupled to the electronic booster, at least one hydraulic brake circuit disposed in fluid communication with the master cylinder, at least one front hydraulic brake disposed in fluid communication with the at least one hydraulic brake circuit and at least one rear hydraulic brake disposed in fluid communication with the at least one hydraulic brake circuit.

Abstract: A brake pedal simulator air gap filler system includes a brake pedal, a pedal feel simulator engaged by the brake pedal, a pedal push rod engaged by the brake pedal, a master cylinder/booster push rod spaced-apart from the pedal push rod, an air gap between the pedal push rod and the master cylinder/booster push rod, a master cylinder/booster engaged by the master cylinder/booster push rod and an air gap filling apparatus having an air gap filling head in adjacent proximity to the air gap and adapted to selectively engage and disengage the air gap.

Abstract: The present disclosure relates to various vehicle braking assemblies with gap management devices to manage the distance between the pedal arm and power booster under predetermined conditions.

Abstract: The present disclosure relates to various vehicle braking assemblies. Brake pedal arms include, for example, a cam block that is configured to simplify the engagement between the power booster and pedal arm. Cam block can be movable with respect to the pedal arm to manage the gap between the pedal arm and power booster in by-wire braking assemblies.

Abstract: A brake-by-wire automotive braking system includes a master cylinder connected to a number of wheel cylinders, with the master cylinder being actuated by a brake pedal assembly operatively connected with a master cylinder force simulator simulating the resistive force/displacement characteristics of the master cylinder itself. An electronically controlled compliance device selectively immobilizes the master cylinder force simulator so that the resistive force provided by the simulator may be applied selectively to the brake pedal. This produces a transparency in the brake pedal's operational feel, notwithstanding the presence or absence of force provided by the master cylinder force simulator.

Abstract: A method is provided that includes determining a state of a vehicle ignition switch; determining a state of the vehicle, wherein the vehicle state including at least one of whether the vehicle is in a torque producing mode, whether the vehicle is moving, and whether the vehicle brake system is engaged; and, controlling the vacuum pump in response to the vehicle state and the ignition switch state.

Abstract: A braking system for a vehicle includes an active booster master cylinder connected with the wheel cylinders, and a controller for operating active booster master cylinder during braking. The primary master cylinder, which is located remotely from the active booster master cylinder, is selectably connected with either a pedal feel emulator or a servo system which applies the brakes using the active booster master cylinder and a hydraulic output from the primary master cylinder in the event that control of the active booster master cylinder becomes impaired.

Abstract: A plurality of electronically controlled parallel electro-mechanical switches are each configured to deliver power from a power source to an electric motor of an automotive vehicle. The electric motor has an expected number of activation cycles for the life of the automotive vehicle. Each of the electro-mechanical switches has a specified number of activation cycles that defines its useable life. The specified number of action cycles for each of the electro-mechanical switches is less than the expected number of activation cycles of the electric motor.

Abstract: A brake system for a hybrid vehicle includes a master cylinder, such as an active booster master cylinder, and a brake pedal mounted upon a pivoted brake pedal arm. A compliance device extends between the brake pedal arm and the master cylinder and includes a push rod and clevis assembly mating with the brake pedal arm. A composite drive pin including a resin sheath and a metallic core functions as part of the compliance device, by allowing limited motion between the brake pedal arm and brake pedal and the master cylinder push rod, so as to permit selective use of regenerative braking.

Abstract: A brake-by-wire automotive braking system includes a master cylinder connected to a number of wheel cylinders, with the master cylinder being actuated by a brake pedal assembly operatively connected with a master cylinder force simulator simulating the resistive force/displacement characteristics of the master cylinder itself. An electronically controlled compliance device selectively immobilizes the master cylinder force simulator so that the resistive force provided by the simulator may be applied selectively to the brake pedal. This produces a transparency in the brake pedal's operational feel, notwithstanding the presence or absence of force provided by the master cylinder force simulator.