Abstract: A control system includes a background unit, a control module, a power supply module, and a battery. The background unit includes a procedure subunit, an operation subunit, and a transceiving subunit. The control module includes an information read-write unit and a processing unit. The processing unit includes a detecting subunit, a control subunit, and a switch subunit. The transceiving subunit sends an operating request to the detecting subunit. The detecting subunit detects a dump energy value of the battery and determines whether the dump energy value is less than a predetermined charge level value. When the dump energy value is greater than the predetermined charge level value, the switch subunit is switched on, and the information read-write unit sends powering information to the transceiving subunit, and the operating subunit operates the procedure subunit. The disclosure further offers a control method.

Abstract: Some disclosed interband tunneling diodes comprise a plurality of substantially coherently strained layers including layers selected from a group consisting of silicon, germanium, and alloys of silicon and germanium, wherein at least one of said substantially coherently strained layers is tensile strained. Some disclosed resonant interband tunneling diodes comprise a plurality of substantially coherently strained layers including layers selected from a group consisting of silicon, germanium, and alloys of silicon and germanium, wherein at least one of said substantially coherently strained layers defines a barrier to non-resonant tunnel current. Some disclosed interband tunneling diodes comprise a plurality of substantially coherently strained layers, wherein at least one of said substantially coherently strained layers is tensile strained.

Abstract: Some disclosed interband tunneling diodes comprise a plurality of substantially coherently strained layers including layers selected from a group consisting of silicon, germanium, and alloys of silicon and germanium, wherein at least one of said substantially coherently strained layers is tensile strained. Some disclosed resonant interband tunneling diodes comprise a plurality of substantially coherently strained layers including layers selected from a group consisting of silicon, germanium, and alloys of silicon and germanium, wherein at least one of said substantially coherently strained layers defines a barrier to non-resonant tunnel current. Some disclosed interband tunneling diodes comprise a plurality of substantially coherently strained layers, wherein at least one of said substantially coherently strained layers is tensile strained.

Abstract: A Si-based diode (10, 10?, 100) is formed by epitaxially depositing a Si-based diode structure on a silicon substrate. The Si-based diode structure includes a Si-based pn junction (16, 16?, 18, 18?, 30, 32, 160, 161) having a backward diode current-voltage characteristic in which the forward tunneling current is substantially smaller than the backward tunneling current at comparable voltage levels. In some embodiments, the Si-based pn junction includes at least one non-silicon or silicon alloy layer such as at least one SiGe layer (16, 16?, 160, 161). In some embodiments, at least one delta doping (30, 32) is disposed on the silicon substrate in or near the pn junction, that together with the Si-based pn junction define an electrical junction having the backward diode current-voltage characteristic. A large area detector array may include a plurality of such Si-based diodes (10, 10?, 100).

Abstract: A silicon-based interband tunneling diode (10, 110) includes a degenerate p-type doping (22, 130) of acceptors, a degenerate n-type doping (32, 118) of donors disposed on a first side of the degenerate p-type doping (22, 130), and a barrier silicon-germanium layer (20, 136) disposed on a second side of the degenerate p-type doping (22, 130) opposite the first side. The barrier silicon-germanium layer (20, 136) suppresses diffusion of acceptors away from a p/n junction defined by the degenerate p-type and n-type dopings (22, 32, 118, 130).

Abstract: A Si-based diode (10, 10?, 100) is formed by epitaxially depositing a Si-based diode structure on a silicon substrate. The Si-based diode structure includes a Si-based pn junction (16, 16?, 18, 18?, 30, 32, 160, 161) having a backward diode current-voltage characteristic in which the forward tunneling current is substantially smaller than the backward tunneling current at comparable voltage levels. In some embodiments, the Si-based pn junction includes at least one non-silicon or silicon alloy layer such as at least one SiGe layer (16, 16?, 160, 161). In some embodiments, at least one delta doping (30, 32) is disposed on the silicon substrate in or near the pn junction, that together with the Si-based pn junction define an electrical junction having the backward diode current-voltage characteristic. A large area detector array may include a plurality of such Si-based diodes (10, 10?, 100).