A data storage device is disclosed comprising a storage medium, an input configured to receive a supply voltage from a voltage source, and control circuitry powered by the supply voltage. The control circuitry is configured to adjust a load of the data storage device, detect a load voltage at the adjusted load, detect a load current at the adjusted load, process the detected load voltage and the detected load current to detect a current limit of the voltage source, and configure the data storage device in response to the detected current limit of the voltage source.

A semiconductor device includes a substrate; an insulating layer positioned above the substrate, wherein the insulating layer has two ends; a first doped region formed in the substrate and positioned at one end of the two ends of the insulating layer; a second doped region formed in the substrate and positioned at the other end of the two ends of the insulating layer, wherein the second doped region is opposite to the first doped region; a control terminal positioned above the insulating layer; a first fuse head positioned above the control terminal and electrically coupled to the first doped region; a second fuse head positioned above the first fuse head; and a fuse area positioned between the first fuse head and the second fuse head.

A voltage detecting apparatus includes: a voltage detecting unit configured to detect a voltage of a battery supplying power to a load; a discharge circuit configured to discharge the battery; a protection circuit disposed between the voltage detecting unit and the battery and between the discharge circuit and the battery; and a determination unit configured to estimate an internal resistance of the protection circuit on the basis of a first voltage detected by the voltage detecting unit when the discharge circuit is in a non-operating state and a second voltage detected by the voltage detecting unit when the discharge circuit is in an operating state and determine a half-cut state of the protection circuit on the basis of a result of the estimation.

A voltage detecting apparatus includes: a voltage detecting unit configured to detect a voltage of a battery supplying power to a load; a discharge circuit configured to discharge the battery; a protection circuit disposed between the voltage detecting unit and the battery and between the discharge circuit and the battery; and a determination unit configured to estimate an internal resistance of the protection circuit on the basis of a first voltage detected by the voltage detecting unit when the discharge circuit is in a non-operating state and a second voltage detected by the voltage detecting unit when the discharge circuit is in an operating state and determine a half-cut state of the protection circuit on the basis of a result of the estimation.

A circuit protection device including a primary fuse, and a positive temperature coefficient (PTC) device and a secondary fuse electrically connected in series with one another and in parallel with the primary fuse, the secondary fuse formed of a quantity of solder disposed on a dielectric surface, wherein the dielectric surface exhibits a de-wetting characteristic relative to the solder such that, when the solder is melted, the solder draws away from the dielectric surface to create a galvanic opening.

Apparatus and method for controlling a pyro-fuse. A pyro-fuse control system includes a current sensing circuit and a diagnostic circuit. The current sensing circuit is configured to determine whether the current flowing in conductor exceeds a threshold current. The diagnostic circuit is coupled to the current sensing circuit. The diagnostic circuit is configured to determine whether an indication of current exceeding the threshold current generated by the current sensing circuit is caused by current flowing the conductor and is not caused by a fault in the current sensing circuit.

A fuse monitoring device for monitoring a fuse supported by a fuse block, the fuse monitoring device including a housing. The housing includes a holder attachment mechanism configured to connect the fuse monitoring device to a fuse block. The housing also includes a mounting attachment mechanism configured to connect the fuse monitoring device to a mounting structure and at least one sensor configured to be operably connected to a fuse and configured to measure fuse data associated with the fuse. The monitoring device further includes at least one processor communicatively coupled to the at least one sensor.

A fuse monitoring device for monitoring a fuse supported by a fuse block, the fuse monitoring device including a housing. The housing includes a holder attachment mechanism configured to connect the fuse monitoring device to a fuse block. The housing also includes a mounting attachment mechanism configured to connect the fuse monitoring device to a mounting structure and at least one sensor configured to be operably connected to a fuse and configured to measure fuse data associated with the fuse. The monitoring device further includes at least one processor communicatively coupled to the at least one sensor.

A voltage switching device, an integrated circuit device, and a voltage switching method are provided. The voltage switching device includes a reference voltage generator generating a first reference voltage and a second reference voltage, a fuse system coupled to a circuit device, and a switch circuit coupled to the reference voltage generator, the fuse system, and the circuit device. The fuse system generates a first enable signal and a second enable signal according to an input signal from a circuit device. The switch circuit transmits the first reference voltage or the second reference voltage to the circuit device according to the first enable signal and the second enable signal from the fuse system.

A voltage switching device, an integrated circuit device, and a voltage switching method are provided. The voltage switching device includes a reference voltage generator generating a first reference voltage and a second reference voltage, a fuse system coupled to a circuit device, and a switch circuit coupled to the reference voltage generator, the fuse system, and the circuit device. The fuse system generates a first enable signal and a second enable signal according to an input signal from a circuit device. The switch circuit transmits the first reference voltage or the second reference voltage to the circuit device according to the first enable signal and the second enable signal from the fuse system.