A method and apparatus for monitoring an internet-of-things (IoT) battery device (IBD). An example IBD includes a radio transceiver to communicate with an IoT charging device (ICD), a battery, and a battery monitor to determine a state of charge for the battery. An alerter is included to send an alert message to the ICD, via the radio transceiver, to indicate that the SoCh is less than an alert threshold.

An approach is provided for battery management in route navigation. A battery management module determines a request to calculate at least one navigation route. The battery module then determines battery charging information associated with presenting guidance information via at least one application of at least one device during the at least one navigation route. Further, the battery management module causes, at least in part, a presentation of the battery charging information on at least one user interface of the at least one device. In one embodiment, the charging information can be updated based on selecting one or more segments of the at least one navigation route to hibernate. In yet another embodiment, alternative content that is less battery intensive can be presented during the hibernated segments in place of active navigation information.

An interactive logo includes a graphical mark, at least one property of the graphical mark, and a logo surface. The graphical mark is disposed on an enclosure of the electronic device to identify a company, an organization, or a brand. At least one property of the graphical mark changes corresponding to an amount of power remaining from a battery to power the electronic device.

An apparatus for determining a state of a rechargeable battery or of a battery has a sensor device and an evaluation device. The sensor device brings about an interaction between an optical signal and a part of the rechargeable battery or of the battery, which part indicates optically acquirable information about a state of the rechargeable battery or of the battery, and detects an optical signal caused by the interaction. The sensor device furthermore provides a detection signal having information about the detected optical signal. The evaluation device determines information about a state of the rechargeable battery or of the battery on the basis of the information of the detection signal. Furthermore, the evaluation device provides a state signal having the information about the determined state.

A system for monitoring battery status and estimating battery life including a battery monitor configured to connect to a battery. The battery monitor comprises a voltage detection circuit, a temperature sensor and a wireless transmitter configured to transmit voltage and temperature data measured by the voltage detection circuit and the temperature sensor. The system further includes a remote device operative to receive battery voltage and temperature data from the battery monitor, generate a real-time indication of battery voltage, and generate predicted battery life data.

A system for determining an operating mode of a battery includes a voltage sensor configured to detect a present voltage across terminals of the battery. The system further includes a non-transitory memory configured to store previously detected voltages across the terminals of the battery, and a previous operating mode of the battery. The system further includes a processor coupled to the voltage sensor and the non-transitory memory and configured to determine the operating mode of the battery by comparing the present voltage across the terminals of the battery to the previously detected voltages of the battery and based on the previous operating mode of the battery.

A system for determining an operating mode of a battery includes a voltage sensor configured to detect a present voltage across terminals of the battery. The system further includes a non-transitory memory configured to store previously detected voltages across the terminals of the battery, and a previous operating mode of the battery. The system further includes a processor coupled to the voltage sensor and the non-transitory memory and configured to determine the operating mode of the battery by comparing the present voltage across the terminals of the battery to the previously detected voltages of the battery and based on the previous operating mode of the battery.

A monitoring system for a battery system of a transportation vehicle having a primary monitoring device for providing control functions and/or supervisory functions for the battery system and a connecting arrangement for the exchange of control signals and/or supervisory signals with the primary monitoring device, wherein the connecting arrangement is electrically connected to the primary monitoring device and wherein a secondary monitoring device for providing a reduced range of the control functions and/or supervisory functions is electrically connected to the connecting arrangement.

A monitoring system for a battery system of a transportation vehicle having a primary monitoring device for providing control functions and/or supervisory functions for the battery system and a connecting arrangement for the exchange of control signals and/or supervisory signals with the primary monitoring device, wherein the connecting arrangement is electrically connected to the primary monitoring device and wherein a secondary monitoring device for providing a reduced range of the control functions and/or supervisory functions is electrically connected to the connecting arrangement.

A computer-based processing system (e.g., host server) is operable for receiving historical device operation information (power consumption data) collected during operation of the remote battery-operated device in accordance with a first set of operating parameters, including rechargeable battery information (such as the number of charging cycles experienced). The first set of operating parameters enable operation of the battery-operated device in a first operating mode. The processing system calculates an observed battery life for the device based on the received historical power consumption data and a power capacity value representing a power capacity of the battery resident in the device. This observed battery life may be output to a user and used to determine whether the device will meet a predetermined operational life. If not, parameters for the device can be modified and a new projected battery life calculated (simulation), with the new modified parameters controlling power consumption in the device.