A system for limiting or diminishing current to unpowered Serializer/Deserializer (SerDes) circuitry is provided. The system comprises receiver input termination circuitry and a cold spare circuitry. The receiver input circuitry comprises a termination resistor and an N-type metal oxide silicon field effect transistor (MOSFET). The cold spare circuitry comprises a first MOSFET and a second MOSFET. When the system is powered on, an input current flows to the receiver input termination circuit to be discharged by the N-type MOSFET which is electrically connected to a ground. When the system is powered off, the input current flows to the cold spare circuitry to discharge the input current. Discharging electrons between the first MOSFET and the second MOSFET depends on the polarity of an accumulated voltage.

A circuit structure and a method for supressing single event transients (SETs) or glitches in digital electronic circuits are provided. The circuit includes a first input which receives an output of a digital electronic circuit and a second input which receives a redundant or duplicated output of the digital electronic circuit. The circuit includes only four two-input gates of two different kinds selected from AND, OR, NAND and NOR gates. The four two-input gates being arranged so that a final circuit output is impervious to a change in a logic level of only the first input or only the second input, and the final circuit output is equivalent to the logic level of the first and second inputs when the logic level of the first and second inputs match.

The present technology relates to a semiconductor device which enables yield to be enhanced. A volatile logic circuit has a storage node, and stores inputted information. A plurality of non-volatile elements are connected to the storage node of the volatile logic circuit through the same connection gate, and control lines for control for these non-volatile elements are connected to the respective non-volatile elements, every non-volatile element. A plurality of non-volatile elements are connected to the volatile logic circuit through the same connection gate in such a way, thereby enabling the yield to be enhanced. The present technology can be applied to a semiconductor device.

Disclosed examples include interface circuits to transfer data between a first register in a fast clock domain and a second register in a slow clock domain, including a resettable synchronizer to provide a synchronized start signal synchronized to a slow clock signal to initiate a write from the first register to the second register according to a write request signal, a pulse generator circuit to provide a write enable pulse signal according to the synchronized start signal, a write control circuit to selectively connect an output of the first register to an input of the second register to write data from the first register to the second register according to the write enable pulse signal, and a dual flip-flop to provide a reset signal synchronized to a fast clock signal according to the write request signal to clear any prior pending write request and begin a new write operation.

Disclosed examples include interface circuits to transfer data between a first register in a fast clock domain and a second register in a slow clock domain, including a resettable synchronizer to provide a synchronized start signal synchronized to a slow clock signal to initiate a write from the first register to the second register according to a write request signal, a pulse generator circuit to provide a write enable pulse signal according to the synchronized start signal, a write control circuit to selectively connect an output of the first register to an input of the second register to write data from the first register to the second register according to the write enable pulse signal, and a dual flip-flop to provide a reset signal synchronized to a fast clock signal according to the write request signal to clear any prior pending write request and begin a new write operation.

A tristate output buffer includes a first branch with a first buffer, and a second branch with a second buffer. The first buffer includes a supply port, a ground port, an output port, two switchable semiconductor elements of a first type, and two switchable semiconductor elements of a second type. Switching behavior of the switchable semiconductor elements of the first type differs from switching behavior of the switchable semiconductor elements of the second type. The two switchable semiconductor elements of the first type are connected in series and are between the supply port and the output port such that they can be put in a conductive state independent of each other. The two switchable semiconductor elements of the second type are connected in series and are between the ground port and the output port such that they can be put in a conductive state independent of each other.

A fingerprint information detection circuit comprises an amplification unit, a source follower unit, a reset unit, and a feedback unit. The amplification unit is coupled to the source follower unit. The reset unit is coupled to both the feedback unit and the amplification unit. The feedback unit and the amplification unit are coupled. The reset unit includes a first transistor and a reset transistor, wherein source and drain electrodes of the first transistor are coupled, wherein one of source and drain electrodes of the reset transistor is coupled to the source and drain electrodes of the first transistor.

According to one embodiment, a terminal control substrate includes a base plate mounted on a terminal device, a first module fixed to the base plate, an external connection terminal fixed to the base plate and to which a component including a second module being a substitute for the first module is attachable, a controller configured to perform control in the terminal device by using the first module or the second module, and a switching unit configured to switch a connection destination of the controller to any one of the first module and the external connection terminal to which the second module is attached.

An integrated circuit includes rows of circuits. A first region of the integrated circuit includes a first portion of each of the rows of circuits, and a second region of the integrated circuit includes a second portion of each of the rows of circuits. The integrated circuit shifts functions for a first subset of the rows of circuits to a second subset of the rows of circuits in the first region based on a first defect in a first one of the rows of circuits in the first region. The integrated circuit shifts functions for a third subset of the rows of circuits to a fourth subset of the rows of circuits in the second region based on a second defect in a second one of the rows of circuits in the second region.

The disclosed voting circuit includes a pull-up circuit connected to an output node and to a positive supply voltage. A pull-down circuit is connected to the output node and to ground, and the output node is coupled to receive true output of a first bi-stable circuit. The pull-up circuit pulls the output node to the positive supply voltage in response to complementary output signals from second and third bi-stable circuits being in a first state, and the pull-down circuit pulls the output node to ground in response to complementary output signals from second and third bi-stable circuits being in a second state that is opposite the first state.