Abstract: A vehicle power system includes loads, a battery coupled to the loads, an ultra-capacitor coupled to the battery, and a bypass circuit. The loads, the ultra-capacitor, and the battery are electrically coupled in series.

Abstract: Method and apparatus are disclosed for energy-consumption detection of vehicles in an off state. An example vehicle includes a controller area network (CAN) including CAN buses, a gateway module, and electronic control units (ECUs) that are each connected to one of the CAN buses. Upon activating while the vehicle is in an off state, a first of the ECUs sends a message via a corresponding one of the CAN buses to activate the gateway module. The message includes activation data and the gateway module stores the activation data.

Abstract: A vehicle includes an electric power converter, a power source, a detection circuit, at least one processor, and at least one memory. The electric power converter filters voltage ripple generated by the electric power converter. The detection circuit determines an unfiltered measurement of the power source and a filtered measurement of the power source and generates a differential signal by comparing the unfiltered measurement and the filtered measurement. Said memory stores instructions executable by said processor. The instructions causes said processor to determine a state of health of the power source based at least in part on the differential signal.

Abstract: A vehicle power management system includes a primary power bus for powering a first non-critical load, a secondary power bus for powering a second non-critical load, and a first relay electrically connected between the primary power bus and the first non-critical load. The vehicle power management system further includes a second relay electrically connected between the secondary power bus and the second non-critical load. The first inductor is electrically connected to the secondary power bus and the second inductor is electrically connected to the primary power bus.

Abstract: A system includes a first DCDC converter arranged to output electrical power only to a first battery and to first loads in a first specified set. The first specified set includes loads provided to control and perform steering and braking. The system further includes a second DCDC converter arranged to output electrical power to loads isolated from the first loads provided to control and perform steering and braking.

Abstract: A vehicle includes an engine and at least one controller. The at least one controller periodically determines an estimated current to be demanded by vehicle electrical loads during an auto stop of the engine, compares the estimated current with a threshold current, and inhibits an auto stop of the engine if the estimated current is greater than the threshold current for a predetermined period of time.

Abstract: A power distribution system for a vehicle includes a plurality of switching devices arranged in a circuit to selectively control power flow between a plurality of buses operating within a same voltage range. The power distribution system further includes a controller programmed to, in response to the switching devices being in a state to transfer power between the buses and a current flowing through one of the buses exceeding a predetermined current, operate the switching devices to isolate the buses.

Abstract: A computer that includes at least one processor and memory. The processor of the computer can be programmed to execute instructions stored on the memory that include controlling, based on a temperature, which of a plurality of power sources of a vehicle battery are coupled to a starter circuit during a vehicle ignition event.

Abstract: A power distribution system for a vehicle includes a switching circuit configured to selectively enable power flow between a first bus and a second bus operable within a common voltage range. The power distribution system further includes a controller programmed to, in response to power flow being inactive and a current flowing through the first bus exceeding a current threshold, operate the switching circuit to enable power flow from the second bus to the first bus.

Abstract: A power distribution system for a vehicle includes a plurality of switching devices arranged in a circuit to selectively control power flow between a plurality of buses operating within a same voltage range. The power distribution system further includes a controller programmed to, in response to the switching devices being in a state to transfer power between the buses and a current flowing through one of the buses exceeding a predetermined current, operate the switching devices to isolate the buses.

Abstract: A computer that includes at least one processor and memory. The processor of the computer can be programmed to execute instructions stored on the memory that include controlling, based on a temperature, which of a plurality of power sources of a vehicle battery are coupled to a starter circuit during a vehicle ignition event.

Abstract: An automotive vehicle includes an engine, a plurality of electrical load subsystems, and at least one controller. During an auto start of the engine, the at least one controller detects a starter disengage condition. In response to detecting the starter disengage condition, the at least one controller periodically determines a value of an operating parameter associated with the vehicle, causes a first subset of the electrical load subsystems to be enabled when the value of the operating parameter falls with a first predefined range of values, and causes a second subset of the electrical load subsystems to be enabled when the value of the operating parameter falls within a second predefined range of values.

Abstract: A vehicle includes an engine and a controller programmed to autostart and autostop the engine. In an autostopped state, engine autostarts are inhibited in the presence of transient currents caused by activation of electrical loads. Engine autostarts are inhibited for a predetermined duration after activation of the electrical load when a battery current is greater than an autostart current threshold.

Abstract: A vehicle includes an engine and a controller programmed to autostart and autostop the engine. In an autostopped state, engine autostarts are inhibited in the presence of transient currents caused by activation of electrical loads. Engine autostarts are inhibited for a predetermined duration after activation of the electrical load when a battery current is greater than an autostart current threshold.

Abstract: A vehicle includes an engine, an electrical load and a stop/start system. The stop/start system selectively auto stops the engine when a speed of the vehicle is approximately zero, and in response to a request to activate the electrical load while the engine is auto stopped, auto starts the engine prior to activating the electrical load.

Abstract: The criteria used to determine whether to initiate an auto stop of an engine may be altered based on a number of previous auto stops of the engine, a total auto stop off time of the engine, or a total throughput of a battery. Altering the criteria may influence a frequency with which the engine is auto stopped.

Abstract: A vehicle includes an engine, an electrical load and a stop/start system. The stop/start system selectively auto stops the engine when a speed of the vehicle is approximately zero, and in response to a request to activate the electrical load while the engine is auto stopped, auto starts the engine prior to activating the electrical load.

Abstract: The criteria used to determine whether to initiate an auto stop of an engine may be altered based on a number of previous auto stops of the engine, a total auto stop off time of the engine, or a total throughput of a battery. Altering the criteria may influence a frequency with which the engine is auto stopped.

Abstract: An automotive vehicle includes an engine, a plurality of electrical load subsystems, and at least one controller. During an auto start of the engine, the at least one controller detects a starter disengage condition. In response to detecting the starter disengage condition, the at least one controller periodically determines a value of an operating parameter associated with the vehicle, causes a first subset of the electrical load subsystems to be enabled when the value of the operating parameter falls with a first predefined range of values, and causes a second subset of the electrical load subsystems to be enabled when the value of the operating parameter falls within a second predefined range of values.

Abstract: A vehicle includes an engine and at least one controller. The at least one controller periodically determines an estimated current to be demanded by vehicle electrical loads during an auto stop of the engine, compares the estimated current with a threshold current, and inhibits an auto stop of the engine if the estimated current is greater than the threshold current for a predetermined period of time.