Abstract: This application has disclosed a method, a non-transitory storage medium and a battery grading apparatus for automatically grading a lithium-ion battery.

Abstract: Systems and methods are disclosed for monitoring battery usage information. In an embodiment, battery usage data is received from a battery energy storage system comprising a battery pack. The battery usage data may include battery identification information, one or more battery sensor measurements for a period of time, and a cumulative warranty value for the battery pack. A project to which the battery pack belongs may then be determined based on the received battery identification information. Finally, the battery usage data may be stored in a warranty database. The warranty database may store battery usage data for a plurality of battery packs. The warranty database may further be partitioned by project, and the battery usage data for is stored in a partition of the warranty database for the determined project.

Abstract: A power generation system and a power control device are provided that, even if there are provided a storage battery and a power conditioner as two independent devices, are capable of supplying electric power at least to the power conditioner in a power outage. The power generation system (1) includes the control device (41) connected to a second storage battery (42) so the that power conditioner (50) is fed with electric power by a power generation device (10), a commercial power grid (30) and a first storage battery (20).

Abstract: An electronic device includes a display and a controller. The controller obtains time series information regarding an output voltage of a battery; estimates a battery remaining amount which the battery is able to discharge based on the obtained time series information; and controls the display to perform a predetermined display when the estimated battery remaining amount is less than a predetermined reference remaining amount.

Abstract: A power supply system includes a lead battery supplying power to the electric load of the vehicle, a battery sensor unit acquiring a value related to a state of the lead battery, and a battery deterioration determination device determining deterioration of the lead battery based on the value acquired by the battery sensor unit. The battery sensor unit acquires a value of a charge amount of the lead battery, a value of a discharge amount of the lead battery, and a value of a discharge depth of the lead battery. An ECU calculates a value of an effective charge/discharge amount of the lead battery based on a charge amount acquisition value, a discharge amount acquisition value and a discharge depth acquisition value acquired by the battery sensor unit and determines deterioration resulting from softening of a positive electrode active material based on the value of the effective charge/discharge amount.

Abstract: A method of managing a battery system, the battery system including at least one battery cell, at least one sensor configured to measure at least one characteristic of the battery cell, and a battery management system including a microprocessor and a memory, the method comprising receiving by the battery management system, from the at least one sensor at least one measured characteristic of the battery cell at a first time and at least one measured characteristic of the battery cell at a second time. The battery management system estimating, at least one state of the battery cell by applying a physics-based battery model, the physics based battery model being based on differential algebraic equations; and regulating by the battery management system, at least one of charging or discharging of the battery cell based on the at least one estimated state.

Abstract: A state of charge estimation method includes: measuring a voltage of a lithium ion secondary battery that is being charged at a predetermined current rate higher than or equal to a predetermined charging rate; obtaining a rate of increase in the measured voltage; and estimating a state of charge of the lithium ion secondary battery based on the rate of increase in the measured voltage and first reference data. The first reference data are data including a correlation between a state of charge of a reference lithium ion secondary battery and a rate of increase in voltage of the reference lithium ion secondary battery when the reference lithium ion secondary battery is charged at the predetermined current rate.

Abstract: A method and an apparatus for battery modelling. The method includes acquiring battery information from a sensor attached to a battery, the battery information including at least a terminal voltage and a load current; classifying, the battery information as effective data or ineffective data based on a phase of a battery cycle during which the battery information is acquired; identifying one or more parameters of the circuit model associated with the battery based on the effective data; and generating an estimation of a state of the battery using the circuit model having the one or more parameters identified using the effective data. Further, a circuit model is identified using effective data.

Abstract: A battery control device capable of obtaining an allowable charge/discharge current value can further accurately reflect a polarization state of a battery. A battery controller includes a first allowable current value calculation unit, a battery equivalent circuit model, and a correction amount calculation unit. Assuming a non-polarization state, a current limit value of the battery based on an open circuit voltage and upper and lower limit voltages set in the battery, the first allowable current value calculation unit calculates a first allowable current value Imax1. The battery equivalent circuit model estimates a polarization state of the battery when the current limit value is being calculated. The correction unit calculates an allowable current value correction value based on the estimated polarization state for correcting Imax1. A second allowable current value Imax2 which is the corrected first allowable current value is output as an allowable charge/discharge current value of the battery.

Abstract: Methods and systems are provided for reliably prognosing a vehicle component, such as a vehicle battery or an intake air filter. A state of degradation of the component is recursively predicted by updating, based on a sensed vehicle operating parameter, a previously estimated state of degradation of the component, the parameter selected based on the component being diagnosed, as well as based on past driving history and future driving predictions. The predicted state of degradation is then converted into an estimate of time or distance remaining before the component needs to serviced, and displayed to the vehicle operator.

Abstract: A metal-ion battery is provided. The metal-ion secondary battery includes a positive electrode, a first negative electrode, a first separator, a second negative electrode, a second separator, and a control element, wherein the first separator is disposed between the positive electrode and the first negative electrode, and the second separator is disposed between the first negative electrode and the second negative electrode. Furthermore, the control element is coupled to the first negative electrode and the second negative electrode, wherein the control element determines whether to electrically connect the first negative electrode to the second negative electrode.

Abstract: A method includes calculating a first estimated state of charge (SOC) of a battery at a first time, receiving a voltage value representing a measured voltage across the battery at a second time, calculating a filter gain at the second time, and calculating a second estimated SOC of the battery at the second time based on the first estimated SOC, the voltage value, and the filter gain. Another method includes storing, in a memory, a library of equivalent circuit models representing a battery, determining an operational mode of a battery based on a load associated with the battery, selecting one of the equivalent circuit models based on the determined operational mode, and calculating a state of charge of charge (SOC) of the battery using the selected equivalent circuit model.

Abstract: Provided are an apparatus and method for estimating a State of Health (SOH) of a battery, and an apparatus and method for generating an SOH estimation model. The apparatus for estimating an SOH of a battery includes a processor configured to divide sensed data of the battery into one or more regions; and estimate the SOH of the battery by applying different SOH estimation models to the one or more divided regions.

Abstract: An electronic device includes a display and a controller. The controller obtains time series information regarding an output voltage of a battery; estimates a battery remaining amount which the battery is able to discharge based on the obtained time series information; and controls the display to perform a predetermined display when the estimated battery remaining amount is less than a predetermined reference remaining amount.

Abstract: The present invention realizes a power supply device that can, even if an abnormality occurs in a power supply unit, block a current from flowing into the path from the other power supply unit.

Abstract: A method of inspecting an electric power storage device for a short circuit includes voltage measuring of measuring a pre-detection device voltage of the electric power storage device that is pre-charged, current detecting of detecting a temporal change in a current flowing to the electric power storage device from an external electric power supply or a stable current value of the current by continuously applying an output voltage equal to the pre-detection device voltage to the electric power storage device from the external electric power supply, and determining of determining an internal short circuit in the electric power storage device based on the detected temporal change in the current or the stable current value of the current.

Abstract: The present invention includes apparatuses and methods to separate a gas from a gaseous mixture using supercapacitive swing adsorption.

Abstract: Various arrangements for determining the state of health (SOH) of a battery of an electric vehicle are presented. A first OCV of the battery of the electric vehicle may be determined. Coulomb counting on the battery of the electric vehicle may be performed to determine an accumulated capacity value following the first OCV being determined. A second OCV of the battery of the electric vehicle may be determined after performing the coulomb counting. A change in OCV value may be calculated using the determined first OCV and the determined second OCV. A slope value may be determined by dividing the accumulated capacity value by the change in OCV value. The SOH of the battery may then be determined using the slope value.

Abstract: A processor adjusts frequencies of one or more clock signals in response to a voltage droop at the processor. The processor generates at least one clock signal by generating a plurality of base clock signals, each of the base clock signals having a common frequency but a different phase. The processor also generates a plurality of enable signals, wherein each enable signal governs whether a corresponding one of the base clock signals is used to generate the clock signal. The enable signals therefore determine the frequency of the clock signal. In response to detecting a voltage droop, the processor adjusts the enable signals used to generate the clock signal, thereby reducing the frequency of the clock signal droop.

Abstract: A method of detecting a state of charge of a battery, can include: obtaining an open circuit voltage in a present cycle according to an open circuit voltage of a previous cycle, a battery internal resistance of the previous cycle, and a battery capacitance of the previous cycle, where the battery internal resistance and the battery capacitance are updated according to the state of charge of the battery; and determining the state of charge of the battery according to the open circuit voltage in the present cycle.

Abstract: One example includes a battery power system that includes a plurality of battery containers. Each of the battery containers can include a plurality of battery modules that provide output power to a point-of-interconnect associated with a power grid. Each of a portion of the plurality of battery containers includes a plurality of original battery modules and at least one of a plurality of redistributed battery modules from a redistributed battery container. The redistributed battery container includes battery modules of a substantially similar state-of-health to the plurality of original battery modules of each of the portion of the plurality of battery containers. The redistributed battery container includes a plurality of newer battery modules with a substantially similar state-of-health that is greater than the state-of-health of the plurality of original battery modules and which were subsequently installed after redistribution of the plurality of redistributed battery modules.

Abstract: A method for evaluating voltage sensor output using a diagnostic system includes: measuring an overall fuel cell stack voltage using a stack voltage sensor; identifying a fuel cell voltage of a first end cell using a first end cell voltage sensor and a second end cell using a second end cell voltage sensor; determining if a maximum value of the overall fuel cell stack voltage, the fuel cell voltage of the first end cell or the second end cell is less than a sensor limit, and if a minimum value of the fuel cell voltages is greater than the sensor limit; performing a test to identify if the maximum value is greater than an average sensor signal value and if the average sensor signal value is greater than the minimum value; and conducting a test to identify if the minimum value is less than a first predetermined threshold.

Abstract: A method of recycling a battery pack includes first to third steps. The first step is a step of estimating an amount of generation of Ni2O3H in a positive electrode of the battery pack based on a voltage value and a temperature of the battery pack. The second step is a step of recycling the battery pack for a high-capacity application when the estimated amount of generation is equal to or smaller than a prescribed reference amount. The third step is a step of recycling the battery pack for a high input-and-output application when the estimated amount of generation is greater than the reference amount and not greater than a reference amount.

Abstract: A system for placing a battery module in a sleep mode may include one or more sensors that monitor at least two properties associated with one or more batteries within the battery module that provides energy to a vehicle. The at least two properties may include two or more of: a state of charge, an input voltage, an input current, and a temperature. The system may also include a processor that receives measurements of the at least two properties from the one or more sensors, compares the measurements of the at least two properties to at least two respective thresholds, and places the battery module in the sleep mode when one of the measurements of the at least two properties is greater than a respective one of the at least two respective thresholds.

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: Provided is a low-cost battery pack capable of predicting a remaining battery life of a rechargeable battery with high accuracy. A remaining battery life prediction device includes: a voltage detection unit configured to measure a battery voltage and a battery temperature of the battery; a calculation unit configured to perform predictive calculation of a remaining battery life based on the battery voltage and the battery temperature; and a control unit configured to control operation of the remaining battery life prediction device and the calculation unit, the remaining battery life prediction device being configured to predict a remaining life of the battery with a calculation flow of for a predetermined time period, recursively calculating the remaining battery life based on the measured battery voltage and battery temperature and an internal impedance of the battery in a battery equivalent circuit.

Abstract: A work machine includes an engine, a motor-generator, a battery, a power detector, a temperature detector, and circuitry. The engine is to move the work machine. The motor-generator is to move the work machine and to generate electric power. The battery is to store the electric power generated by the motor-generator. The power detector is to detect a charge level of the electric power stored in the battery. The temperature detector is to detect a temperature of the battery. The circuitry is configured to control the motor-generator in accordance with the charge level selectively to move the work machine or to generate electric power when the temperature of the battery detected by the temperature detector is within a temperature range.

Abstract: Systems, methods, and non-transitory computer readable media can provide a vibrating source configured to cause movement of a camera sensor to generate a bias for the camera sensor. A high frequency accelerometer configured to measure movement of the camera sensor can be provided. A plurality of images of a scene can be captured using the camera sensor based on the generated bias at a resolution supported by the camera sensor, wherein the high frequency accelerometer measures movement of the camera sensor during the capture of the plurality of images.

Abstract: There is provided a sensing device for measuring a level of an analyte. The sensing device includes a sensing element configured to sense the analyte and produce an electrical output which is variable based on the level of the analyte sensed, a measurement circuit including a reference element for providing an electrical property, the measurement circuit being connected to the sensing element and configured to provide a measurement output signal based on the electrical property of the reference element and the electrical output of the sensing element, whereby the measurement output signal indicates the level of the analyte sensed with respect to the electrical property of the reference element. There is also provided a corresponding method of fabricating the sensing device.

Abstract: The present invention concerns a method and apparatus for battery charging. The method comprises the steps of connecting a battery to a battery charging apparatus and supplying a voltage and current to the battery, wherein a constant voltage is supplied for an extended period of time. At the beginning of the constant voltage being supplied, the initial charging current being supplied to the battery is noted (Amp). During the period in which a constant voltage is supplied, the rate of change of the charging current supplied to the battery (dl/dt) is monitored. The method includes calculating the ratio: K=Amp/(dl/dt) during the period in which a constant voltage is supplied, and when K equals a preselected value, maintaining the charging current at the instant value for an extended period of time.

Abstract: A method performed by an electronic controller includes determining a charge level of a power supply configured to provide power to a medical device, and estimating, based on the charge level of the power supply, a first power supply life for operating the medical device according to a first mode. Further, the method includes estimating, based on the charge level of the power supply, a second power supply life for operating the medical device according to a second mode. As recited, operating the medical device according to the first mode has a different power use or consumption characteristic from operating the medical device according to the second mode. The method also includes generating a notification indicative of the first power supply life and the second power supply life.

Abstract: A high voltage battery pack includes a set of battery bricks, wherein the battery bricks each have a positive and a negative terminal. Each battery brick is connected in series or in parallel to an adjacent battery brick to generate a total voltage of the battery pack. A battery pack lower assembly holds the battery bricks. A battery pack upper assembly includes a battery pack upper housing and a circuit board connected to the battery pack upper housing, the circuit board having brick connectors attached thereto. The brick connectors are positioned to come into physical contact with the positive and negative terminals of the battery bricks to generate the total voltage of the battery pack, and the battery pack upper housing defines a physical separation distance between the brick connectors and an exterior of the battery pack upper housing.

Abstract: A system includes a battery and a power management unit connected with the battery. The power management unit controls power to the battery. A spare power unit can connect with the power management unit and the battery. The power management unit stores excess charge to the spare power unit and to divert stored charge to the battery when the battery is charged less than a determined percentage.

Abstract: A secondary battery restoring method includes a first step of determining whether or not a value of an input-output characteristic of a secondary battery or a battery module is within a predetermined range of reference values, and a second step of adjusting the secondary battery or the battery module to a predetermined low SOC condition of from 0% to 20% SOC and thereafter leaving the secondary battery or the battery module to stand if, in the first step, the value of the input-output characteristic is determined to be outside the predetermined range of reference values.

Abstract: A system for controlling an AC power inverter has a charging power source (e.g., vehicle alternator), a battery (e.g., vehicle crank battery), a DC to AC power inverter, a shunt or current-measuring device (which may either be internal to, or external to, the AC power inverter), electrical connections (i.e., cables and connections between the charging power source, battery, AC power inverter, and shunt), and a control module; wherein the control module is capable of measuring shunt voltage, battery voltage, elapsed time, and is capable of turning the AC power inverter On and Off based upon certain criteria (i.e., control logic).

Abstract: A method and system to automatically load an application. Based on automatically generated statistics tracking proximities of application access and detected events, an application is selected with a greatest probability of being accessed within a time proximity of an event that is defined by operating environment criteria associated with launching the application. An association is determined, based on the statistics, between a user's launching of the application in proximity to a particular time of day over a plurality of days. In response to detecting an occurrence of the event and based on the association, the application is automatically loaded into a background of the device independent of a present user command to load the application. Based on loading the application and receiving an indication of user presence within a predetermined period of time after the occurrence of the event, the application is brought into a foreground of the device.

Abstract: A secondary battery protecting integrated circuit protects a secondary battery by controlling a switch circuit inserted in series on a path connected to a first electrode of the secondary battery. The secondary battery protecting integrated circuit includes: a sense terminal connected to a monitor terminal provided so that a first electric potential of the first electrode is monitorable; a first power supply terminal connected to the path; a second power supply terminal connected to a second electrode of the secondary battery; an internal wiring line configured to connect the first power supply terminal and the sense terminal; an internal switch on the internal wiring line; an abnormality detecting circuit configured to detect a predetermined abnormality; and a switch control circuit configured to turn on the internal switch when the predetermined abnormality is not detected, and configured to turn off the internal switch when the predetermined abnormality is detected.

Abstract: A rechargeable battery pack (20) for an electric or hybrid vehicle (1), comprising: at least one electric connection member (23) to a powertrain unit (5) of the electric or hybrid vehicle (1); a plurality of mutually electrically connected cells (30); at least one first circuit block (40) integrated in the rechargeable battery pack (20) and comprising a radio communication interface (45).

Abstract: Aspects acquire at least one first battery state when a battery of the electronic device is in a first dormant state; acquire at least one second battery state of the battery in a second dormant state and the charge level or discharge capacity of the battery during the first dormant state and the second dormant state when it is confirmed that the battery enters the non-dormant state from the first dormant state, and enters the second dormant state from the non-dormant state; and calculate the actual full charge level of the battery on the basis of at least the first battery state, at least the second battery state and the charge level or discharge capacity. The technical problem that the calibration of battery capacity can only be conducted in a full charged state for the battery existing in the electronic device in prior art is solved by the above-mentioned technical solution provided in the present invention.

Abstract: Battery status information may be provided to an information handling system, such as a laptop computer, through the same cable as the power. The transfer of battery status information may be facilitated by a power delivery (PD) controller in the external battery that communicates with a power delivery (PD) controller in the laptop computer. One cable type that can support the transfer of battery status information is a Universal Serial Bus (USB) Type-C cable. Battery status information may be transferred as packetized data according to a vendor-defined messaging (VDM) protocol from the external battery to the laptop computer. An embedded controller within the laptop computer may decode the packets and report the battery status information to components within the laptop computer. The battery status may be accessed through application programming interfaces (APIs) by third-party applications or displayed through the operating system.

Abstract: A battery state estimation method and apparatus are provided. Sensing data of a battery is received, and feature information is acquired by preprocessing the sensing data. The preprocessed sensing data is selected based on the feature information, and state information of the battery is determined based on at least one of the selected preprocessed sensing data or previous state information of the battery.

Abstract: The present invention discloses a battery internal resistance measuring device and a method thereof, wherein the battery internal resistance measuring device comprises a voltage detecting unit, at least one measurement resistor, at least one switch, and a measurement controller. By means of further explanation, the measurement controller at least comprises a differential value calculating unit for treating a differential value calculation or a slope calculation to each two of adjacent voltage sampling values on a waveform of a discharge voltage signal of the battery, such that the measurement controller can subsequently find out a discharge starting point and a discharge ending point according to data of the differential value calculations or the slope calculations. Eventually, the measurement controller calculates an internal resistance of the battery after picking up an open-circuit voltage and a short-circuit voltage from the discharge starting point and the discharge ending point.

Abstract: Methods and systems are provided for an adaptive state-of-charge for a portable imaging system. In one embodiment, a method comprises controlling an x-ray source to generate an x-ray exposure, measuring a voltage of a power supply coupled to the x-ray source during the x-ray exposure, and adjusting an available capacity of the power supply based on the voltage. In this way, the full capacity of a power supply may be utilized while compensating for aging of the power supply.

Abstract: An information handling system touchscreen display interacts with totem devices by recognizing and tracking spectral signatures of the totem devices so that totem positions are reported as a single length, width and rotational orientation message to a host operating system. Ignore zones and hysteresis time periods are defined from the position message based upon totem context so that the host operating system processes touchscreen inputs with minimal latency and improved accuracy. Communication and battery charging are provided to the totem by the touchscreen display will illumination directed to the totem position.

Abstract: Systems and methods that may be implemented to monitor and record (store) information related to environmental conditions, operating conditions and/or events to which a battery-powered information handling system has been exposed while the battery powered information handling system is not powered. In one embodiment this stored environmental, system operating and/or event information may be made available to one or more system programmable integrated circuits at a following system restart or operating system (OS) boot. Such stored information may be used, for example, to determine one or more actions during a subsequent system restart or OS reboot, and/or to better enable root cause analysis of no-POST (power on self-test) type failures.

Abstract: A pickup location and a drop off location are received. An amount of travel-related charge is estimated based at least in part on the pickup and drop off location. An amount of stored charge in a second, removable battery is measured and it is decided whether to charge a first battery from the second, removable battery based at least in part on the amount of travel-related charge and the measured amount of stored charge in the second, removable battery. In response to deciding to charge the first battery from the second, removable battery, the first battery from the second, removable battery is charged. In response to deciding not to charge the first battery from the second, removable battery, the first battery from the second, removable battery is not charged.

Abstract: A battery system includes a plurality of battery modules connected in parallel. Each battery module includes a battery, a first output terminal and a second output terminal, a switch circuit connected between the battery and the first output terminal, and a battery manager to detect a battery voltage of the battery and control the switch circuit. Each battery manager is connected to other battery managers through a communication bus and transmits module information of a corresponding battery module to the other battery managers through the bus. Each batter manager also receives module information from the other battery managers through the bus and controls a corresponding switch circuit based on the module information.

Abstract: The present disclosure discloses an apparatus and method for estimating a remaining service life of a battery that enables providing a relatively exact remaining service life of the battery to a user even when a parameter of the battery does not change sufficiently enough to enable measurement of the remaining service life due to reasons such as the battery not being used or the like.

Abstract: A battery system includes battery modules connected in parallel Each battery modules includes a battery, a first and second output terminals, a switch arrangement connected between the battery and the first output terminal, and a battery manager. The battery manager is to detect a current of the battery, determine whether an overcurrent condition exists based on the detected current, and control the switch arrangement. The battery manager to transmit module state information to the battery managers in remaining ones of the battery modules, and the battery managers in the battery modules control their switch arrangements based on the module state information.

Abstract: A method comprises a client executing on a processor of a UE, where the client is monitoring an application log and communication log for a plurality of user applications and communication applications. The client measures a volume of transactions and a set of performance metrics associated with UE resource usage. The client generates a custom device profile that establishes baselines for each of the plurality of user applications and identifies any deviations from the baselines. The client creates a bounded threshold based on the deviations, and detects that at least one of the plurality of user applications has exceeded the bounded threshold. The client determines that the bounded threshold was exceeded based on an application trigger and a network trigger, and in response, initiates a response action. The client also captures the communication log, the application log and application cache corresponding to the user application.