Abstract: An information display for a vehicle includes an indicator arrangement having a visual display configured to provide driver demand information to a vehicle driver. The visual display includes a dynamic target range for operating the vehicle, which includes a first boundary and a second boundary indicating a driver demand that would cause the engine to start. A control system includes at least one controller, and is configured to receive at least one input related to current operating conditions of the vehicle and to provide at least one output to the indicator arrangement to position the target range on the visual display and to indicate to the driver a current level of driver demand. In this way, the visual display indicates to the driver the current level of driver demand relative to the position of the target range.

Abstract: An information display for a vehicle includes an indicator arrangement having a visual display configured to provide driver demand information to a vehicle driver. The visual display includes a dynamic target range for operating the vehicle, which includes a first boundary and a second boundary indicating a driver demand that would cause the engine to start. A control system includes at least one controller, and is configured to receive at least one input related to current operating conditions of the vehicle and to provide at least one output to the indicator arrangement to position the target range on the visual display and to indicate to the driver a current level of driver demand. In this way, the visual display indicates to the driver the current level of driver demand relative to the position of the target range.

Abstract: A method of controlling an engine 12 during engine shutdown to reduce evaporative emissions is provided. The method includes a step 50 of shutting off a fuel pump 28 of the engine 12. The method also includes a step 52 of burning off the fuel from a fuel rail 24 in a cylinder 18 of the engine 12 after the fuel pump 28 is shut off. During the burning off of the fuel, a duty cycle of each fuel injector 22of engine 12 is controlled to allow the engine 12 to operate generally cyclically about a predetermined air/fuel ratio. The predetermined air/fuel ratio is preferably stoichiometric. By burning off the fuel in the fuel rail 24 after the fuel pump 28 is shut off, the fuel pressure in the fuel rail 24 is reduced. The reduced fuel pressure in the fuel rail 24results in reduced evaporative emissions from the engine 12.

Abstract: The present invention provides a method and system for determining “engine on” status in a Hybrid Electric Vehicle. A controller determines that the engine is necessary and then checks the current “engine on” status. If the engine is not currently running, the controller proceeds to start the engine by commanding the generator to spin or “motor” the engine. The controller then starts fuel and spark within the engine to create combustion. Measuring devices are then used to determine the ion current/breakdown voltage across a spark gap in the engine. The controller receives this measurement and determines whether the measured ion current/breakdown voltage exceeds a calibratable threshold. If the calibratable threshold is exceeded, combustion is occurring and the engine is on. The controller then turns on the “engine on” status flag.

Abstract: The present invention provides a method and system for determining “engine on” status in a Hybrid Electric Vehicle. A controller determines the engine is necessary and then checks the current “engine on” status. If the engine is not currently running, the controller proceeds to start the engine by commanding the generator to spin or “motor” the engine. The controller then starts fuel flow and spark within the engine to create combustion. A measuring device is then used to determine the crankshaft speed. The controller receives this measurement and determines whether the measured variations in crankshaft speed exceed a calibratable threshold. If the calibratable threshold is exceeded, combustion is determined to be occurring and the engine is on. The controller then turns on the “engine on” status flag.

Abstract: A method of determining an operating state of an internal combustion engine in a hybrid electric vehicle drive system comprising an internal combustion engine having an output shaft which is coupled to a generator. The engine includes a fuel injector responsive to a fuel command. The method comprises the steps of determining an ON/OFF status of the fuel command and determining the generator torque. The generator torque provides an indication of the actual engine torque. An engine running flag is set ON when the fuel command is ON and the generator torque value is greater than a predetermined value. Otherwise, the engine running flag is set OFF.

Abstract: The present invention provides a method and system for determining “engine on” status in a Hybrid Electric Vehicle. A controller determines the engine is necessary and then checks the current “engine on” status. If the engine is not currently running, the controller proceeds to start the engine by commanding the generator to spin or “motor” the engine. The controller then starts fuel flow and spark within the engine to create combustion. A measuring device is then used to determine the crankshaft speed. The controller receives this measurement and determines whether the measured variations in crankshaft speed exceed a calibratable threshold. If the calibratable threshold is exceeded, combustion is determined to be occurring and the engine is on. The controller then turns on the “engine on” status flag.

Abstract: The present invention provides a method and system for determining “engine on” status in a Hybrid Electric Vehicle. A controller determines that the engine is necessary and then checks the current “engine on” status. If the engine is not currently running, the controller proceeds to start the engine by commanding the generator to spin or “motor” the engine. The controller then starts fuel and spark within the engine to create combustion. Measuring devices are then used to determine the ion current/breakdown voltage across a spark gap in the engine. The controller receives this measurement and determines whether the measured ion current/breakdown voltage exceeds a calibratable threshold. If the calibratable threshold is exceeded, combustion is occurring and the engine is on. The controller then turns on the “engine on” status flag.