Abstract: The present invention relates to a topical composition and method of use, specifically an oil-in-water emulsion, comprised of sweet almond oil, lavender oil, rose oil, cinnamon bark oil, and coriander seed oil in a physiologically acceptable topical carrier. The composition is applied to a circumcised human penis to enhance sensitivity, preferably twice daily for a time period of at least about two weeks. Thereafter a maintenance dose can be applied once a day to maintain a desired level of sensitivity.

Abstract: A battery enclosure is provided that externally shorts the enclosed battery, or batteries, immediately prior to the battery being punctured. As a result, the battery's state-of-charge is decreased, leading to a less severe reaction when the battery case is punctured.

Abstract: A method is provided for achieving a constant driving range in an electric vehicle over a multi-year period (e.g., 5, 8, 10 years), where the preset driving range corresponds to a percentage of the driving range that is achievable with the initial battery pack capacity. Prior to each charge cycle, the method first determines the current battery pack capacity and then determines a set of optimized charging parameters based on the current battery pack capacity and the preset driving range. Charging is then performed in accordance with the set of optimized charging parameters.

Abstract: A charging system is provided for use with the battery pack of an electric vehicle, where both the charge level and the charging rate may be specified over a range of available levels and rates, respectively. A system controller coupled to the charging system determines the optimal charging level and the optimal charging rate, where optimization is based on maximizing battery lifetime while insuring that there is sufficient power for the vehicle to travel the user's intended distance and that the charging process will be completed prior to the user's intended departure time.

Abstract: A system and a corresponding method are provided for interconnecting the batteries in a battery pack in a manner that is designed to simplify the connection process, thereby improving throughput. The system uses two different types of interconnects; wire and ribbon interconnects. The wire interconnects are attached to each battery's large contact area terminal nub while the ribbon interconnects are attached to the crimped edge region of each battery's case.

Abstract: A battery enclosure is provided that externally shorts the enclosed battery, or batteries, immediately prior to the battery being punctured. As a result, the battery's state-of-charge is decreased, leading to a less severe reaction when the battery case is punctured.

Abstract: A method is provided that aids the driver of an electric vehicle (EV) in optimizing their car's driving range by allowing the driver to request range optimization help from the EV's control system. In response to the request, the system provides the driver with one or more recommendations as to how to increase vehicle range, recommendations such as lowering top speed, altering the temperature settings of the car's HVAC system, etc. Additionally, the system provides the driver with real time driving range feedback, thereby helping the driver to evaluate the various recommendations and determine which approach is best suited to the current conditions.

Abstract: A method is provided that aids the driver of an electric vehicle (EV) in optimizing their car's driving range. In response to the charge level of the car's battery pack falling below a preset value, the system provides the driver with one or more recommendations as to how to increase vehicle range, recommendations such as lowering top speed, altering the temperature settings of the car's HVAC system, etc. Additionally, the system provides the driver with real time driving range feedback, thereby helping the driver to evaluate the various recommendations and determine which approach is best suited to the current conditions.

Abstract: A method is provided that aids the driver of an electric vehicle (EV) in optimizing their car's driving range by allowing the driver to request range optimization help from the EV's control system. In response to the request, the system provides the driver with one or more recommendations as to how to increase vehicle range, recommendations such as lowering top speed, altering the temperature settings of the car's HVAC system, etc. Additionally, the system provides the driver with real time driving range feedback, thereby helping the driver to evaluate the various recommendations and determine which approach is best suited to the current conditions.

Abstract: A method is provided that aids the driver of an electric vehicle (EV) in optimizing their car's driving range by allowing the driver to request range optimization help from the EV's control system. In response to the request, the system provides the driver with one or more recommendations as to how to increase vehicle range, recommendations such as lowering top speed, altering the temperature settings of the car's HVAC system, etc. The recommendations provided by the system take into account current conditions (e.g., posted speed limits, ambient temperature, etc.), thereby insuring that the recommendations made by the system are reasonable. In addition, the system provides the driver with real time driving range feedback, thereby helping the driver to evaluate the various recommendations.

Abstract: A method is provided that aids the driver of an electric vehicle (EV) in optimizing their car's driving range. In response to the car's current driving range falling below a preset value, the system provides the driver with one or more recommendations as to how to increase range, recommendations such as lowering top speed, altering the temperature settings of the car's HVAC system, etc. Additionally, the system provides the driver with real time driving range feedback, thereby helping the driver to evaluate the various recommendations and determine which approach is best suited to the current conditions.

Abstract: A method is provided that gives real time feedback to the driver of an electric vehicle (EV) regarding the car's driving range, thereby allowing the driver to easily regulate battery usage, and thus driving range, by adjusting their driving style (e.g., top speed, acceleration/deceleration rates, etc.) as well as the settings of the car's various electrically powered auxiliary systems (e.g., HVAC, internal and external lights, entertainment system, etc.).

Abstract: A method is provided that aids the driver of an electric vehicle (EV) in optimizing their car's driving range. In response to the car's current driving range falling below that required to travel to a destination entered into the EV's control system, for example via the car's navigation system, the system provides the driver with one or more recommendations as to how to increase range, recommendations such as lowering top speed, altering the temperature settings of the car's HVAC system, etc. Additionally, the system provides the driver with real time driving range feedback, thereby helping the driver to evaluate the various recommendations and determine which approach is best suited to the current conditions.

Abstract: A method is provided that aids the driver of an electric vehicle (EV) in optimizing their car's driving range. In response to the car's current driving range falling below that required to travel to a destination entered into the EV's control system, for example via the car's navigation system, the system provides the driver with one or more recommendations as to how to increase range, recommendations such as lowering top speed, altering the temperature settings of the car's HVAC system, etc. Additionally, the system provides the driver with real time driving range feedback, thereby helping the driver to evaluate the various recommendations and determine which approach is best suited to the current conditions.

Abstract: A method is provided that aids the driver of an electric vehicle (EV) in optimizing their car's driving range. In response to the car's current driving range falling below a preset value, the system provides the driver with one or more recommendations as to how to increase range, recommendations such as lowering top speed, altering the temperature settings of the car's HVAC system, etc. Additionally, the system provides the driver with real time driving range feedback, thereby helping the driver to evaluate the various recommendations and determine which approach is best suited to the current conditions.

Abstract: A rechargeable battery pack is discontinuously charged in multiple discrete charging intervals. Reductions in battery pack voltage that occur during non-charging intervals, each transpiring between a respective pair of the discrete charging intervals, are measured. Multiple resistance values that characterize the internal resistance (DC resistance) of the battery pack are generated based on the reductions in battery pack voltage that occur during the non-charging intervals.

Abstract: A method is provided for achieving a constant driving range in an electric vehicle over a multi-year period (e.g., 5, 8, 10 years), where the preset driving range corresponds to a percentage of the driving range that is achievable with the initial battery pack capacity. Prior to each charge cycle, the method first determines the current battery pack capacity and then determines a set of optimized charging parameters based on the current battery pack capacity and the preset driving range. Charging is then performed in accordance with the set of optimized charging parameters.

Abstract: A battery is rendered to a consistent discharged state in a two-phase battery discharge operation. In a first of the two discharge phases, a constant discharge current is drawn from the battery until a threshold battery voltage is reached. In the second of the two discharge phases, executed after the threshold battery voltage is reached during the first-phase, a time-varying discharge current is drawn from the battery at a constant battery voltage until a threshold discharge current is reached.

Abstract: A method is provided for optimizing the charging protocol used when charging the battery pack of an electric vehicle, where optimization is based, in part, on the user's intended departure time and intended travel distance. Based on the user's travel information the process determines (i) an optimal charge level that maximizes the battery pack's lifetime while assuring that there is sufficient energy for the vehicle to travel the intended distance and (ii) an optimal charging rate that maximizes the battery pack's lifetime while assuring that the battery pack is charged to the optimal charge level prior to the intended time of departure. Safety margins may be added to the user's travel information, thus insuring that the car is charged and ready for use if the user decides to leave earlier than expected, or if the travel takes a larger charge than expected.

Abstract: A method is provided for optimizing the charging protocol used when charging the battery pack of an electric vehicle, where optimization is based, in part, on the user's intended departure time and intended travel distance. Based on the user's travel information the process determines (i) an optimal charge level that maximizes the battery pack's lifetime while assuring that there is sufficient energy for the vehicle to travel the intended distance and (ii) an optimal charging rate that maximizes the battery pack's lifetime while assuring that the battery pack is charged to the optimal charge level prior to the intended time of departure. Safety margins may be added to the user's travel information, thus insuring that the car is charged and ready for use if the user decides to leave earlier than expected, or if the travel takes a larger charge than expected.