Abstract: A vehicle information display may include a split braking gauge for conveying information relating to braking operation and efficiency to assist drivers in maximizing energy capture during braking in vehicle with regenerative braking systems. The split braking gauge may incorporate a side-by-side or stacked configuration for conveying both regenerative braking and friction braking values. The split braking gauge may include fixed thresholds or boundaries associated with dynamic threshold values that can change based on current vehicle operating conditions.

Abstract: A system and method is provided for determining a target state of charge (SOC) to charge a storage battery in an electric vehicle using electric power from an external power source. Charging the storage battery to the target SOC occurs prior to starting a drive cycle of the vehicle. The target SOC is determined based on a profile of regenerative braking energy expected to be recovered and a profile of energy expected to be used from the battery during a portion of a future drive cycle.

Abstract: A hydraulic brake assist vacuum maintenance system includes a vacuum source, a vacuum booster/master cylinder interfacing with the vacuum source, a brake pedal interfacing with the vacuum booster/master cylinder, a brake control unit interfacing with the vacuum booster/master cylinder, wheel brakes interfacing with the brake control unit and a hydraulic brake assist interfacing with the brake control unit and adapted to hydraulically operate the wheel brakes upon reduction or cessation of vacuum pressure from the vacuum source to the vacuum booster/master cylinder.

Abstract: To prevent damage of a cord set used to charge a plug-in electric vehicle when the vehicle is driven away while the cord set is attached, an interlock can be provided to disable the vehicle. Such interlock may be based on a protective door over the charging receptacle being open or detection that a cord set is plugged in. However, in the event that the vehicle is in an activated state, the interlock is prevented from disabling the vehicle according to an embodiment of the disclosure. That is, undesirable disabling of the vehicle is prevented when either there is no indication of a cord set being coupled to the vehicle or the vehicle is in an activated state.

Abstract: A controller and a control strategy minimizes shift shock in a hybrid electric vehicle during a downshift conducted while the vehicle is in a regenerative braking mode by maintaining total powertrain torque at a desired target during the downshift. The controller has three preferable modes including modulating just engine torque, modulating just electric motor torque or simultaneously modulating both motor and engine torque.

Abstract: An information display configured to display one or more energy efficiency values of a vehicle. The information display system may comprise an information display configured to display an energy recovered indicator corresponding to a ratio of the braking energy recovered using a regenerative braking system. The information display may include both an overall energy recovered indicator and an instantaneous energy recovered indicator.

Abstract: Driver braking performance feedback may be conveyed to a vehicle operator as a braking efficiency score using a vehicle display system. The display system may include a vehicle display for displaying a braking efficiency indicator or gauge corresponding to the braking efficiency score. The braking efficiency score may be based on a comparison of the total regenerative braking energy recaptured during at least one braking event to a either a maximum amount of braking energy that may be recaptured during the at least one braking event or an actual total braking energy expended during the at least one braking event. The braking efficiency score may be displayed upon the completion of a braking event or upon a completion of a trip including a plurality of braking events. The display may also convey a distance corresponding to a portion of a trip distance achieved through regenerative braking.

Abstract: Driver braking performance feedback may be conveyed to a vehicle operator as a braking efficiency score using a vehicle display system. The display system may include a vehicle display for displaying a braking efficiency indicator or gauge corresponding to the braking efficiency score. The braking efficiency score may be based on a comparison of the total regenerative braking energy recaptured during at least one braking event to a either a maximum amount of braking energy that may be recaptured during the at least one braking event or an actual total braking energy expended during the at least one braking event. The braking efficiency score may be displayed upon the completion of a braking event or upon a completion of a trip including a plurality of braking events. The display may also convey a distance corresponding to a portion of a trip distance achieved through regenerative braking.

Abstract: An information display system and method are provided for displaying an energy efficiency of a vehicle. The vehicle may include an engine and an electric machine that operates to provide torque to propel the vehicle. The vehicle may also include an energy source that provides energy to the electric machine. The information display system may comprise an information display configured to display an efficiency indicator, the efficiency indicator being configured to indicate an efficiency of the vehicle. The information display system may further comprise a controller configured to receive information related to the braking system of the vehicle. The controller further being configured to determine an energy efficiency value based upon the braking system information. The controller may also be configured to transmit the energy efficiency value so that the information display displays the efficiency indicator based upon the energy efficiency value.

Abstract: Power brakes are typically vacuum assisted, with the vacuum provided from the intake manifold. If the engine is commanded to operate for a long period at a condition with low intake manifold vacuum, the vacuum within the brake booster may drop to a level which is marginal or insufficient for a present or subsequent braking operation. To ensure sufficient vacuum in the intake manifold to provide to the brake booster, the engine may be commanded to operate at a condition to increase intake manifold vacuum by one of: adjusting cam timing, increasing engine speed, and increasing EGR. In the case of a stop-start vehicle, the engine speed is increased from zero to a condition that provides the desired vacuum.

Abstract: A system and method is provided for charging an auxiliary battery in a plug-in electric vehicle with an onboard charging system. The auxiliary battery has a predetermined operating range of charge levels. The auxiliary battery is charged to an upper charge level using an external power source thereby reducing energy used from the onboard charging system to charge the auxiliary battery during a drive mode of the vehicle. The upper charge level may be substantially similar to an upper level of the predetermined operating range of charge levels or greater than the predetermined operating range of charge levels. The auxiliary battery may be allowed to discharge to a lower charge level, which may be substantially similar to a lower level of the predetermined operating range of charge levels or less than the predetermined operating range of charge levels.

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: In the event that the brake pedal and accelerator pedal are depressed simultaneously, powertrain output is decreased monotonically with brake pedal input. In a lower range of brake pedal input, the brakes are prevented from actuating or are allowed to actuate minimally. In a higher range of pedal input, the powertrain output continues to be decreased and the brakes are allowed to actuate. In yet another higher range of pedal input, the powertrain output is substantially decreased such that a minimal powertrain output is achieved. The powertrain may include an internal combustion engine and/or an electric motor. The brake pedal input is determined based on a sensor associated with the brake pedal, the brake booster, or the master cylinder.

Abstract: To prevent damage of a cord set used to charge a plug-in electric vehicle when the vehicle is driven away while the cord set is attached, an interlock can be provided to disable the vehicle. Such interlock may be based on a protective door over the charging receptacle being open or detection that a cord set is plugged in. However, in the event that the vehicle is in an activated state, the interlock is prevented from disabling the vehicle according to an embodiment of the disclosure. That is, undesirable disabling of the vehicle is prevented when either there is no indication of a cord set being coupled to the vehicle or the vehicle is in an activated state.

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 hybrid electric vehicle includes an internal combustion engine, a high voltage traction battery, an electric motor powered by the traction battery, an electric air conditioning (AC) system, and a controller. The controller is programmed to start the vehicle. The vehicle is started by, if a climate control demand requires cooling: (a) if a vehicle start request is a remote start request, starting the engine; (b) if the vehicle start request is a local start request, avoiding starting the engine to provide a silent start.

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 front hydraulic brake disposed in fluid communication with the master cylinder, at least one electronic control unit connected to the brake pedal and at least one rear electronic brake connected to the at least one electronic control unit.

Abstract: A vehicle control system for a vehicle having an onboard diagnostics connector and a connector interface connected to the onboard connector includes at least one external controller adapted for unfastenable connection to the connector interface; and at least one operator control connected to said at least one external controller.

Abstract: A method and system are described for extending an operating range of a motor vehicle, the vehicle having an economy mode of operation. When the vehicle fuel level decreases below a first threshold, an indication is provided to a vehicle user that the vehicle will enter the economy mode of vehicle operation. The economy mode of vehicle operation is automatically entered a predetermined period of time after providing the indication to the vehicle user. The economy mode of vehicle operation is exited in response to a user command to exit the economy mode of vehicle operation.

Abstract: A method and system are described for extending an operating range of a motor vehicle, the vehicle having a first mode of operation and an economy mode of operation. A vehicle range may be estimated based on a vehicle fuel level and the first mode of operation. A distance to a fuel location may also be estimated. The economy mode of vehicle operation may be automatically entered a predetermined period of time after the estimated vehicle range based on the vehicle fuel level and the first operating mode decreases to within a predetermined threshold of the estimated distance to a fuel location.