A method of designing a circuit is provided. The method includes: providing a circuit; selecting a first NMOS fin field-effect transistor (FinFET) in the circuit; and replacing the first NMOS FinFET having a first fin number with a second NMOS FinFET having a second fin number and a third NMOS FinFET having a third fin number, wherein the sum of the second fin number and the third fin number is equal to the first fin number.

The present disclosure relates to integrated circuits, and more particularly, to a wordline system architecture supporting an erase operation and current-voltage (I-V) characterization and methods of manufacture and operation. In particular, the present disclosure relates to a structure including: a twin cell circuit which is connected to a wordline of a memory array; a sourceline driver which is connected to a sourceline of the memory array for providing a cell level current-voltage (I-V) access of the twin cell circuit; and an integrated analog multiplexor which is connected to the twin cell circuit.

First and second sensing circuits are coupled to first and second data lines, respectively, and sense levels of current leakage or a memory cell state on the first and second data lines. First and second keeper circuits are coupled to the first and second data lines, respectively, and drive the first and second data lines by a voltage supply through biased transistors. First and second leakage latches are coupled to receive and latch state of signals output from the first and second sensing circuits, respectively. A control circuit is coupled to the first leakage latch, second leakage latch, and outputs of the first and second sensing circuits. The control circuit is configured to select either the signal output from the first sensing circuit or the signal output from the second sensing circuit in response to states of the first and second leakage latches.

First and second sensing circuits are coupled to first and second data lines, respectively, and sense levels of current leakage or a memory cell state on the first and second data lines. First and second keeper circuits are coupled to the first and second data lines, respectively, and drive the first and second data lines by a voltage supply through biased transistors. First and second leakage latches are coupled to receive and latch state of signals output from the first and second sensing circuits, respectively. A control circuit is coupled to the first leakage latch, second leakage latch, and outputs of the first and second sensing circuits. The control circuit is configured to select either the signal output from the first sensing circuit or the signal output from the second sensing circuit in response to states of the first and second leakage latches.

Methods for reading a memory are provided. In response to a first address signal, a first signal is obtained according to first data of the memory and a second signal is obtained according to second data of the memory by a decoding circuit. Binary representation of the first signal is complementary to that of the second signal. A first sensing signal is provided according to a reference signal and the first signal and a second sensing signal is provided according to the reference signal and the second signal by a sensing circuit. An output corresponding to the first sensing signal or the second sensing signal is output in response to a control signal, by an output buffer.

Methods for reading a memory are provided. In response to a first address signal, a first signal is obtained according to first data of the memory and a second signal is obtained according to second data of the memory by a decoding circuit. Binary representation of the first signal is complementary to that of the second signal. A first sensing signal is provided according to a reference signal and the first signal and a second sensing signal is provided according to the reference signal and the second signal by a sensing circuit. An output corresponding to the first sensing signal or the second sensing signal is output in response to a control signal, by an output buffer.

A semiconductor device including a FIFO circuit in which a data capacity can be increased while minimizing an increase in a circuit scale is provided. The semiconductor device includes a single-port type storage unit (11) which stores data, a flip-flop (12) which temporarily stores write data (FIFO input) or read data (FIFO output) of the storage unit (11), and a control unit (14, 40) which controls a write timing of a data signal, which is stored in the flip-flop (12), to the storage unit (11) or a read timing of the data signal from the storage unit to avoid an overlap between a write operation and a read operation in the storage unit (11).

A circuit includes a plurality of registers, each register including SRAM cells, a read port configured to receive a read address, a write port configured to receive a write address, a selection circuit, a latch circuit, and a decoder coupled in series between the read and write ports and the plurality of registers, and a control circuit. Responsive to a clock signal and read and write enable signals, the control circuit causes the selection circuit, the latch circuit, and the decoder to select a first register of the plurality of registers in a read operation based on the read address, and select a second register of the plurality of registers in a write operation based on the write address.

A circuit includes a plurality of registers, each register including SRAM cells, a read port configured to receive a read address, a write port configured to receive a write address, a selection circuit, a latch circuit, and a decoder coupled in series between the read and write ports and the plurality of registers, and a control circuit. Responsive to a clock signal and read and write enable signals, the control circuit causes the selection circuit, the latch circuit, and the decoder to select a first register of the plurality of registers in a read operation based on the read address, and select a second register of the plurality of registers in a write operation based on the write address.

A memory circuit includes a plurality of word lines, a word line driver coupled to the plurality of word lines, and a booster circuit coupled to the plurality of word lines. The word line driver is configured to output a first word line signal on a first word line of the plurality of word lines, and the booster circuit includes a first node configured to carry a first power supply voltage and is configured to couple the first word line of the plurality of word lines to the first node responsive to a pulse signal and the first word line signal.