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.

A battery pack for selectively providing electrical power to power equipment includes a housing, a plurality of rechargeable lithium-ion battery cells, and a printed circuit board. The housing defines an internal cavity and an external terminal connection. The external terminal connection includes a plurality of high voltage connection pins and a plurality of low voltage connection pins. The plurality of rechargeable lithium-ion battery cells are received within the internal cavity and are configured to supply electrically power through the external terminal connection to the power equipment. The printed circuit board is received within the housing and includes a controller and a transceiver. The transceiver includes a near-field communication chip in communication with the controller. The near-field communication chip is configured to detect a near-field communication tag on power equipment and communicate information from the near-field communication tag to the controller.

A battery charging system comprising a battery charger configured to deliver power to a rechargeable battery, wherein the battery charger comprises a wireless data transceiver; and a remote server communicatively coupled to the battery charger through a network via said wireless data transceiver and configured to communicate one or more battery charge parameters or battery charger control commands between the battery charger and a remotely situated portable user device.

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.

Methods and systems for managing mobile devices for connection with a vehicle are provided. A processor is configured to determine whether a mobile device is within a predetermined distance of the vehicle based on a comparison between the first geographical data of the mobile device and second geographical data of the vehicle. Responsive to determining that the mobile device is within the predetermined distances of the vehicle based on the comparison, the processor is configured to enable Bluetooth functionality on the mobile device.

An intelligent automotive component adapted to perform as an regulated apparatus. Further, the intelligent automotive component comprises an power-link apparatus comprising an circuitry that furthers allocates or restricts power supply to one or more components of the intelligent automotive component. The intelligent automotive component further comprises an key fob that allows wireless communication with the intelligent automotive component to enable or disable the apparatus.

In some embodiments of the present disclosure, sensors mounted on a vehicle can allow opportunities for coasting to be predicted based on environmental conditions, route planning information, and/or vehicle-to-vehicle or vehicle-to-infrastructure signaling. In some embodiments of the present disclosure, these sensors can also predict a need for power and/or an end of a coast opportunity. These predictions can allow the vehicle to automatically enter a coasting state, and can predictively re-engage the engine and/or powertrain in order to make power available with no delay when desired by the operator.

An engine control and input system for a device having a tool driven by an engine, includes an input and control module having one or more inputs and a controller responsive to actuation of the inputs to permit user control of at least one engine operating parameter by user actuation of the inputs. The system may include a touch screen display that displays icons to the user relating to the inputs and the at least one engine operating parameter, and wherein the touch screen display is responsive to the user selecting one of the inputs by touching an associated one of the icons provided by the display. At least one of the inputs may relate to one or more of changing engine speed, starting the engine, causing the engine to drive the tool, turning on a light, actuating a heater or warmer or stopping engine operation.

Implementations provide techniques for remote starter adapter for use with a communication device. In one implementation, a system comprising a memory and an adapter coupled, operatively coupled to the memory, having an interface to connect to a remote starter. The adapter is to receive, via a wireless connection, a probe request from a communication device, the probe request comprising a command data structure. It is determined whether to change a status of an indicator based on the command data structure. Responsive to changing the statue of the indicator, a signal associated with the adapter is generated. Thereupon, the signal is transmitted, via the interface, to an input circuit to activate the remote starter.

A battery pack for use in providing starting power for a starter motor of an internal combustion engine and to supply power to one or more auxiliary loads. The battery pack includes an outer housing that encloses a plurality of battery cells. The battery pack further includes a control module. The control module includes a processing circuit configured to control one or more functions associated with the internal combustion engine and an interface circuit configured to interface with the internal combustion engine.