Secure, remotely controlled, internally powered padlock

The invention claimed is: 1 . An improved, remotely controlled, internally powered electronic padlock comprising: a shackle with an engagement feature; and a housing within which the shackle is translationally and rotationally mounted, the housing including a switch that generates a signal when a state of the switch is changed, an electric motor with a motor shaft to which a translation device is mounted, a moveable member with an engagement feature complementary to the shackle engagement feature that is translated, by activation of the electric motor, in a first direction to release the shackle, placing the padlock in an unlocked state, and is translated in a second direction to lock the shackle by engaging the moveable-member engagement feature with the shackle engagement feature, placing the padlock in an unlocked state, the moveable member changing the state of the switch when the padlock is in a locked state and the shackle is mechanically compromised and rotated, network-communications functionality that receives commands from a remote controller and transmits responses to the remote controller, an internal electrical-energy source, and a microprocessor, powered by the internal energy source, that receives the signal generated by the switch when the padlock is in a locked state and the shackle is mechanically compromised and rotated and, in response to receiving the signal, activates an alarm, and periodically activates network-communications functionality to communicate with the remote controller. 2 . The improved, remotely controlled, internally powered electronic padlock of claim 1 wherein the shackle is a cylindrical rod formed into a U shape, with a first shackle arm and a second shackle arm, the first shackle arm having a first engagement feature and the second shackle arm having a second engagement feature, the first engagement feature of the first shackle arm and the engagement feature of the second shackle arm together composing the shackle engagement feature. 3 . The improved, remotely controlled, internally powered electronic padlock of claim 2 wherein the moveable member is a latch plate; and wherein the moveable-member engagement feature includes a first latch-plate engagement feature complementary to the first engagement feature of the first shackle arm, and a second latch-plate engagement feature complementary to the second engagement feature of the second shackle arm. 4 . The improved, remotely controlled, internally powered electronic padlock of claim 3 wherein the first engagement feature of the first shackle arm is a notch in the first shackle arm and the second engagement feature of the second shackle arm is a notch in the second shackle arm. 5 . The improved, remotely controlled, internally powered electronic padlock of claim 4 wherein the first latch-plate engagement feature complementary to the first engagement feature of the first shackle arm is an edge of a first shackle-accommodating aperture in the latch plate through which the first shackle arm extends, the edge of the first shackle-accommodating aperture entering the notch in the first shackle arm when the shackle is pushed into the housing to place the padlock in the locked state; and wherein the second latch-plate engagement feature complementary to the second engagement feature of the second shackle arm is an edge of a second shackle- accommodating aperture in the latch plate through which the second shackle arm extends, the edge of the second shackle-accommodating aperture entering the notch in the second shackle arm when the shackle is pushed into the housing to place the padlock in the locked state. 6 . The improved, remotely controlled, internally powered electronic padlock of claim 3 further including a latch-plate spring that is compressed when the latch plate is translated in the first direction by activation of the electric motor, releasing the shackle and placing the padlock in the unlocked state, and which provides a force to translate the latch plate in the second direction when the electric motor is activated to release the latch plate, placing the padlock in a ready state, and when the shackle is subsequently pushed into the housing to a locked position in which the first latch-plate engagement feature engages the first engagement feature of the first shackle arm and the second latch-plate engagement feature engages the second engagement feature of the second shackle arm, placing the padlock in the locked state. 7 . The improved, remotely controlled, internally powered electronic padlock of claim 6 wherein the translation device is a cam that extends through a cam aperture of the latch plate; and wherein when the padlock is in the ready state and the cam is in a lock rotational position, the cam is not engaged with the latch plate, when the padlock is in the locked state, the cam is in a lock rotational position and is engaged with an edge of the cam aperture, when the padlock is in the locked state and the electric motor is activated, the cam is rotated to an unlock rotational state, applying a force to the latch plate that translates the latch plate in the first direction, compresses the latch-plate spring, and disengages the first latch-plate engagement feature from the first engagement feature of the first shackle arm and the second latch-plate engagement feature from the second engagement feature of the second shackle arm, placing the padlock in the unlocked state, and when the padlock is in the unlocked state and the electric motor is activated, the cam is rotated to a lock rotational position, releasing the latch plate and placing the padlock in the ready state. 8 . The improved, remotely controlled, internally powered electronic padlock of claim 1 further comprising: a shackle spring that is compressed when the shackle is pushed into a locking position and that decompresses, when the padlock is placed in an unlocked state, to push the shackle into an unlocked position. 9 . The improved, remotely controlled, internally powered electronic padlock of claim 1 wherein when the moveable member has been translated in the second direction to engage the moveable-member engagement feature with the shackle engagement feature, the moveable member does not overlie the switch and, therefore, the switch is in a first state and the padlock is in the locked state, when the moveable member has been translated in the first direction to release the shackle, the moveable member overlies the switch and, therefore, the switch is in a second state and the padlock is in the unlocked state, and when the padlock is in the unlocked state and the electric motor is activated, the moveable member is released, but is prevented from translating to engage the moveable- member engagement feature with the shackle engagement feature until the shackle is pushed toward the housing, and, therefore, the switch remains in the second state and the padlock is in a ready state. 10 . The improved, remotely controlled, internally powered electronic padlock of claim 9 wherein, when the padlock in in the locked state, the shackle is cut, and one of the portions of the cut shackle is rotated, the moveable member is translated by the rotation of one of the portions of the cut shackle in the first direction, changing the position of the switch from the first state to the second state and causing the switch to generate a signal that is transmitted to the microprocessor, which, in turn, generates an alarm. 11 . The improved, remotely controlled, internally powered electronic padlock of claim 1 wherein the microprocessor alternates from a sleeping state, during which network-controller