Abstract: A method and apparatus for adjusting the charge for a battery under a power sharing arrangement is disclosed. In one embodiment, the method comprises determining if power output capacity of an alternating current (AC) adapter is less than or greater than a system power requirement for a system that receives power from the AC adapter and a battery, determining a charge current for charging the battery from the AC adapter, based on a voltage range of the battery, the current charge being less than excess current available from the AC adapter in view of determining that the power output capacity of the AC adapter is greater than the system power requirement, and controlling a battery charger to charge the battery with the charge current by specifying the charge current to the battery charger if the power output capacity of the AC adapter is greater than the system power requirement.

Abstract: A template battery comprises one or more layers that fill into a dead space on a substrate. The substrate comprises one or more components. The one or more layers of the template battery are arranged as a mirror image of the topography of the one or more components on the substrate. A template battery is coupled to a charge controller. The charge controller is coupled to the main battery.

Abstract: Estimating a charge state for a flat-voltage profile battery can be accomplished using impedance measurements. For example, an impedance measurement can be used to form a fuel gauge for a lithium-air (Li-Air) battery. As the impedance of a Li-Air battery increases during discharge, it corresponds to a state of charge (i.e., a charge state). The impedance can be used to create charge state data to use with a fuel gauge.

Abstract: An optical apparatus includes a housing including an opening for letting a light flux pass through a first window member configured to let the light flux pass through, and to cover the opening, a second window member, overlapped with and fixed to the first window member, configured to let the light flux pass through, and a sealing member that is made of a stretchable material, and that is provided along an outer edge of the first window member or the second window member so as to form a sealed space portion between the first window member and the second window member.

Abstract: In embodiments, an apparatus may include a battery life monitor. The battery life monitor may, in some embodiments, receive a battery level indicator indicative of a current charge level of a battery that is coupled with the apparatus and a first temperature that may indicate a temperature of a current location of the apparatus. The battery life monitor may also receive one or more additional temperatures that indicate respective temperatures of one or more locations in which the apparatus is likely to be operated prior to discharge of the current charge level of the battery. Based at least in part on the current charge level, the first temperature indicator, and the one or more additional temperatures, the battery life monitor may calculate one or more battery life estimates that correspond with the one or more locations. Other embodiments may be described and/or claimed.

Abstract: These present disclosure provides a flexible battery comprising a top layer and a bottom layer coupled at a number of attachment points to form chambers within the battery to retain a shape of the battery under an increase in internal pressure. The flexible battery can include an anode and separator and a cathode, where the separator is a flexible polymer.

Abstract: A battery cell includes a first current collector, a cathode in electrical contact with the first current collector, and a second current collector. The second current collector includes a metal foam having a porous structure, and an electrically insulating layer on outer surfaces of the porous structure facing the cathode. The electrically insulating layer isolates the outer surfaces facing the cathode from ions provided by the cathode. The electrically insulating layer is configured to allow an electrolyte to transport ions from the cathode to an inner portion of the porous structure of the metal foam. The battery cell may further include a separator to separate the cathode and the first current collector from the second current collector. When the battery cell is in at least a partially charged state, ions form an anode including a metal plating within the inner porous structure of the metal foam.

Abstract: Because a rechargeable battery has an increased number of uses (e.g., cycles), the battery's internal impedance can increase and the efficiency of the battery can become degraded. This internal resistance can cause cutoff voltage thresholds and cutoff current thresholds to prematurely stop a phase of battery charging, as these cutoff values can be based on low-cycle count batteries. New cutoff values can, instead, be based on battery impedance. Use of an adjusted cutoff current threshold during a constant voltage cycle can increase the capacity of high-cycle count batteries. Use of an adjusted cutoff voltage threshold in step charging can increase the charging speed of high-cycle count batteries. These increases in efficiency by using adjusted cutoff values can increase as the battery is further high-cycle count, in comparison with low-cycle count cutoff values used with high-cycle count batteries.

Abstract: A system and method for a battery cell having an anode and a cathode, and a separator disposed between the anode and the cathode. A conductive layer disposed in the separator facilitates detection of dendrite growth from the anode into the separator, the detection correlative with a reduction in voltage between the anode and the conductive layer. A detection interface component coupled to the conductive layer is configured to facilitate routing of a signal from the conductive layer to a circuit external to the battery cell, the signal indicative of the detection. The battery cell may be part of a battery or battery pack which may be utilized by an electronic device.

Abstract: A system for increasing the life of a battery cell by limiting the charging of the battery to less than full charge in response to a predicted electricity draw of a connected device being less than the full capacity of the battery before a predicted recharge will occur. The current draw of the connected device may be affected by the amount of time before a next recharge and environmental factors. The system may further comprise one or more sensors to gather data pertaining to environmental conditions that may be used in the calculation of a charge termination value. The charge termination value is an amount of charge to power the device for a duration of time at least until a predicted recharge begins.

Abstract: A battery cell is formed to efficiently use unoccupied space in an electronic device. The battery cell may be formed by disposing an electrically insulating material on at least a first surface of a circuit board having components to create an electrical barrier and disposing a battery cell on the electrically insulating material. In some embodiments, a portion of the battery cell is configured to be partially disposed between components of the circuit board components, thus utilizing previously unoccupied space in the electronic device to store energy.

Abstract: Systems and methods are disclosed for estimating a full-charge battery cell capacity without a coulomb counting device. First and second measured voltages of the battery cell are measured during a charging or discharging period. The first and second measured voltages of the battery cell are converted to percentages of remaining battery life. The amount of charge delivered to the battery cell and/or delivered from the battery cell during charging/discharging is calculated. The change in the percentage of remaining battery life is compared to the amount of charge delivered to the battery cell and/or delivered from the battery cell to calculate various battery cell evaluation calculations, including a full-charge battery cell capacity.

Abstract: A template battery comprises one or more layers that fill into a dead space on a substrate. The substrate comprises one or more components. The one or more layers of the template battery are arranged as a mirror image of the topography of the one or more components on the substrate. A template battery is coupled to a charge controller. The charge controller is coupled to the main battery.

Abstract: Various embodiments may be generally directed to techniques for using an observed battery stress history to manage operation of a computing system component in a high power performance mode when powered by a battery. Various embodiments include techniques for tracking stresses to a battery. Various embodiments include techniques for comparing the battery stress history to a degradation baseline for the battery. Various embodiments include techniques for developing a degradation baseline for a battery including, for example, a degradation baseline based on expected stress to a battery and/or a degradation baseline based on a battery reliability model. Various embodiments include techniques for determining a battery stress surplus or deficit. Various embodiments include techniques for managing operation of a performance enhancing mode or high power performance mode of a computing system component based on the determined battery stress surplus or deficit.

Abstract: A battery cell includes a first current collector, a cathode in electrical contact with the first current collector, and a second current collector. The second current collector includes a metal foam having a porous structure, and an electrically insulating layer on outer surfaces of the porous structure facing the cathode. The electrically insulating layer isolates the outer surfaces facing the cathode from ions provided by the cathode. The electrically insulating layer is configured to allow an electrolyte to transport ions from the cathode to an inner portion of the porous structure of the metal foam. The battery cell may further include a separator to separate the cathode and the first current collector from the second current collector. When the battery cell is in at least a partially charged state, ions form an anode including a metal plating within the inner porous structure of the metal foam.

Abstract: A battery cell structure may include a battery cell, a first pouch layer to substantially surround the battery cell, a second pouch layer to substantially surround the first pouch layer, and a shielding layer in the battery cell structure.

Abstract: Because a rechargeable battery has an increased number of uses (e.g., cycles), the battery's internal impedance can increase and the efficiency of the battery can become degraded. This internal resistance can cause cutoff voltage thresholds and cutoff current thresholds to prematurely stop a phase of battery charging, as these cutoff values can be based on low-cycle count batteries. New cutoff values can, instead, be based on battery impedance. Use of an adjusted cutoff current threshold during a constant voltage cycle can increase the capacity of high-cycle count batteries. Use of an adjusted cutoff voltage threshold in step charging can increase the charging speed of high-cycle count batteries. These increases in efficiency by using adjusted cutoff values can increase as the battery is further high-cycle count, in comparison with low-cycle count cutoff values used with high-cycle count batteries.

Abstract: A method and apparatus for adjusting the charge for a battery under a power sharing arrangement is disclosed. In one embodiment, the method comprises determining if power output capacity of an alternating current (AC) adapter is less than or greater than a system power requirement for a system that receives power from the AC adapter and a battery, determining a charge current for charging the battery from the AC adapter, based on a voltage range of the battery, the current charge being less than excess current available from the AC adapter in view of determining that the power output capacity of the AC adapter is greater than the system power requirement, and controlling a battery charger to charge the battery with the charge current by specifying the charge current to the battery charger if the power output capacity of the AC adapter is greater than the system power requirement.

Abstract: A battery pack is provided that may include a first battery cell, a second battery cell and a first spring. The first spring to couple to the first battery cell and to the second battery cell.

Abstract: Systems and methods may place a battery in a first constant voltage charging mode and monitoring a diminishing current of the battery while the battery is in the first constant voltage charging mode. Additionally, the battery may be placed in a constant current charging mode when the diminishing current falls to a first predetermined threshold. In one example, a rising voltage of the battery is monitored while the battery is in the constant current charging mode and the battery is placed in a second constant voltage charging mode at an end of the charge cycle in response to the rising voltage reaching a second predetermined threshold. Moreover, a charge current corresponding to the constant current charging mode may be adjusted based on a charge capacity of the battery.