A battery pack includes a housing, rechargeable lithium-ion battery cells enclosed in the housing, terminals, a processing circuit, and a communications interface. The processing circuit is configured to control a supply of electrical power from the rechargeable lithium-ion battery cells to a positive terminal and a negative terminal in response to receiving signals from data terminals. The signals from the data terminals include operational information that includes at least a condition of an electric motor on power equipment coupled with the data terminals. The communications interface is configured to communicate over a wireless communication protocol to receive an identification of a type of power equipment coupled with the plurality of terminals. The processing circuit is configured to adjust one or more functions of the battery pack based upon identification data received from the communications interface, which includes the type of power equipment that is coupled with the plurality of terminals.

In accordance with one aspect of the disclosure, an apparatus is provided that includes a database configured to store one or more vehicle status parameters of a vehicle and one or more secured space status parameters of a secured space. The apparatus further includes a server-based processor operatively coupled or connected to the database and configured to receive one or more of the one or more vehicle status parameters and one or more of the one or more secured space status parameters. The server-based processor is further configured to determine, based on at least one of the one or more vehicle status parameters and at least one of the one or more secured space status parameters whether to change a state of the vehicle.

A method and system for operating a vehicle that includes a plurality of engine starting devices and an internal combustion engine is described. In one example, the method selects one of a plurality of engine starting devices to start an engine based on durability metrics of each of the plurality of engine starting devices. In addition, engine starting device selection may be based on calibration parameters that are generated via a server that is external to the vehicle.

One embodiment includes an engine block heating system. The engine block heating system includes a battery bank. The battery bank is configured to supply at least 2.25 KWatt-hours of energy before needing to be recharged. The battery bank is configured to be mounted in a vehicle comprising an engine block heater. The system further includes interface configured to connect to electrical connections of the engine block heater. The interface comprises an inverter is configured to supply at least 1500 Watts of power to the engine block heater. The engine block heating system is configured to selectively supply power from the battery bank to the engine block heater. The system further includes control circuitry coupled to the interface. The control circuitry stores a user-defined schedule to selectively control when the interface electrically connects the battery bank to the engine block heater.

A wireless lanyard system for a marine vessel propelled by at least one propulsion device, the system comprising an operator fob configured to be worn by an operator of the marine vessel, a helm transceiver configured to receive radio signals from the operator fob an a controller. The controller is configured to define a permitted zone with respect to a helm area of the marine vessel based on at least one vessel condition, determine based on communications between the operator fob and the helm transceiver whether the operator is within the permitted zone with respect to the helm area, and generate a lanyard event when the operator is not within the permitted zone.

A remote startup system includes: a terminal; a center server configured to receive a startup request; and a vehicle having a driving device, the vehicle configured to receive a startup request, and start up the driving device, wherein at least one of the center server and the vehicle includes an information acquisition unit configured to acquire information on transmission availability state of a power transmission device that transmits power of the driving device in the vehicle to driving wheels, or information on an operation state of a rotation prevention device that prevents rotation of the driving wheels when a function of transmitting the startup request is activated or when the startup request is transmitted, and a permission determination unit configured to determine whether to permit the startup of the driving device based on the startup request, based on the information acquired by the information acquisition unit.

The control device of a vehicle includes a position estimating part configured to estimate a position of the vehicle, and a power output part configured to control the internal combustion engine and the electric motor to output power for running use. The power output part is configured to determine a startup position of the internal combustion engine of the vehicle when the vehicle exits from a low emission zone requesting the internal combustion engine be stopped so that startup positions of internal combustion engines of a plurality of vehicles are dispersed at surroundings of the low emission zone.

A compact battery monitoring system for monitoring a vehicle battery in a vehicle having an engine is described. The compact battery monitoring system may comprise a housing, a processor positioned within the housing, one or more sensors operatively coupled with said processor, a data port, a wireless data transceiver, and rechargeable lithium ion battery. The data port may be configured to removeably couple with a second data port positioned outside the housing to provide an electrical connection between the one or more sensors and the vehicle battery, wherein said processor is configured to monitor a parameter of the vehicle battery using said one or more sensors, yielding a monitored battery parameter. The wireless data transceiver within the housing is configured to wirelessly communicate the monitored battery parameter to a remotely situated, portable user device using, for example, ultra high frequency radio waves. A display device may be positioned on the housing, including a plurality of light emitting diodes. The rechargeable lithium ion battery is configured to supply power needed to operate the processor and the wireless data transceiver. When the engine is running, the battery monitoring system draws a charging current from the vehicle battery to charge the lithium ion battery.

An intelligent automotive component such as an engine starter. The intelligent automotive component having an power-link apparatus disposed within an housing comprising a circuitry that furthers allocates and restricts power supply to one or more components of the intelligent automotive component. The intelligent automotive component comprises an control apparatus such as an key fob that allows wireless communication between the intelligent automotive component and key fob.

A battery starting and charging system that monitors battery and other sensor readings; tracks vehicle state, determines a charging voltage based on battery temperature and vehicle state; sets the alternator to charge the battery with the charging voltage; determines current collected parameters based on the battery and other sensor readings; and makes vehicle start predictions based on the current collected parameters. The system can also determine whether the vehicle actually started; add the current collected parameters to a set of start events if it started, and to a set of no-start events if it didn't start. The start prediction can also be based on the sets of start and no-start events for one or multiple vehicles. The collected parameters and start predictions can also be based on collected weather data. The system can use a local interconnect network (LIN) alternator with a LIN network.