Abstract: A theft deterring system includes a power tool with a motor connectable to a power source, a switch connected to the motor, a controller controlling to the switch for controlling an amount of power provided to the motor, and a state circuit having a memory for storing a state value. The controller activates the switch to provide power to the motor when the state value stored in the memory equals a desired value. The system may also include a tag programmer for changing the stored value.

Abstract: A theft deterring system includes a power tool with a motor connectable to a power source, a switch connected to the motor, a controller controlling to the switch for controlling an amount of power provided to the motor, and a state circuit having a memory for storing a state value. The controller activates the switch to provide power to the motor when the state value stored in the memory equals a desired value. The system may also include a tag programmer for changing the stored value.

Abstract: A theft deterring system includes a power tool with a motor connectable to a power source, a switch connected to the motor, a controller controlling to the switch for controlling an amount of power provided to the motor, and a state circuit having a memory for storing a state value. The controller activates the switch to provide power to the motor when the state value stored in the memory equals a desired value. The system may also include a tag programmer for changing the stored value.

Abstract: A battery pack charger system includes one or more charging ports for charging one or more removable battery packs. A set of indicators may be arranged on a housing, with a subset of the set of indicators being associated with each charging port. Each subset of indicators may output an indication of a state of charge of a battery pack received in an associated charging port of the charger system. A first indication may indicate that the battery pack is charging. A second indication may indicate that the battery pack has achieved a preset level of charge. A third indication may indicate that the battery pack has achieved a substantially full level of charge.

Abstract: A theft deterring system includes a power tool with a motor connectable to a power source, a switch connected to the motor, a controller controlling to the switch for controlling an amount of power provided to the motor, and a state circuit having a memory for storing a state value. The controller activates the switch to provide power to the motor when the state value stored in the memory equals a desired value. The system may also include a tag programmer for changing the stored value.

Abstract: A theft deterring system includes a power tool with a motor connectable to a power source, a switch connected to the motor, a controller controlling to the switch for controlling an amount of power provided to the motor, and a state circuit having a memory for storing a state value. The controller activates the switch to provide power to the motor when the state value stored in the memory equals a desired value. The system may also include a tag programmer for changing the stored value.

Abstract: A battery pack charger system includes one or more charging ports for charging one or more removable battery packs. A set of indicators may be arranged on a housing, with a subset of the set of indicators being associated with each charging port. Each subset of indicators may output an indication of a state of charge of a battery pack received in an associated charging port of the charger system. A first indication may indicate that the battery pack is charging. A second indication may indicate that the battery pack has achieved a preset level of charge. A third indication may indicate that the battery pack has achieved a substantially full level of charge.

Abstract: A method of charging a battery pack is provided. The method includes: electronically connecting a battery pack to a charger; detecting information regarding the battery pack; determining an appropriate charging regime based on the detected information; and applying the charging regime to the battery pack. A battery charger may also provided. The battery charger includes: a first terminal for connecting to a battery pack; a second terminal for connecting to a battery pack, a microprocessor operatively connected to the terminals and configured to receive a signal from at least one terminal regarding a battery pack connected to the terminal and control the charger to select and apply a charging regime to the battery pack according to the signal.

Abstract: A control module is included in a battery charger that is adapted to charge a plurality of battery packs of different types or a power tool that is adapted to be powered by at least one of the battery packs. The control module includes a remote sensing module that communicates remotely with one of the battery packs. The control module also includes a battery pack connection module that determines that the one of the battery packs is in electrical communication with at least one of the battery charger and the power tool. The control module also includes a battery pack identification (ID) module that determines a first type of the battery pack based on remote sensing module signals. The control module also includes a charge control module that determines at least one of a charge setting and a discharge setting for the battery pack based on the first type.

Abstract: A method is provided for distinguishing between batteries having different chemistry compositions. The method includes: supplying electrical energy to the battery for charging thereof; monitoring a voltage characteristic of the battery periodically during charging, wherein the voltage characteristic varies over time with the state of charge of the battery; and identifying the chemistry composition of the battery based on the voltage characteristic of the battery.

Abstract: A rechargeable battery pack comprises a battery having a high voltage side and a low voltage side, a positive terminal accessible external of the battery pack and connected to the high voltage side of the battery, a negative terminal accessible external of the battery pack and connected to the low voltage side of the battery, a control terminal accessible external of the battery pack, a switching element electrically connected between the control terminal and the high voltage side of the battery, and a control module operable to control the switching element so that the control terminal is selectively coupled to the high voltage side of the battery.

Abstract: A method is provided for distinguishing between batteries having different chemistry compositions. The method includes: supplying electrical energy to the battery for charging thereof; monitoring a voltage characteristic of the battery periodically during charging, wherein the voltage characteristic varies over time with the state of charge of the battery; and identifying the chemistry composition of the battery based on the voltage characteristic of the battery.

Abstract: A control module is included in a battery charger that is adapted to charge a plurality of battery packs of different types or a power tool that is adapted to be powered by at least one of the battery packs. The control module includes a remote sensing module that communicates remotely with one of the battery packs. The control module also includes a battery pack connection module that determines that the one of the battery packs is in electrical communication with at least one of the battery charger and the power tool. The control module also includes a battery pack identification (ID) module that determines a first type of the battery pack based on remote sensing module signals. The control module also includes a charge control module that determines at least one of a charge setting and a discharge setting for the battery pack based on the first type.