A flip-flop circuit includes a clock generator configured to generate first and second clock signals having different phases relative to each other, and a master-slave latch circuit including master and slave latches. The master latch includes a scan path configured to output a scan path signal in response to a scan enable signal and a scan input signal, and a data path configured to output a first latch signal in response to a data signal and the scan path signal. A feedback path is provided, which includes a tri-state inverter responsive to the first and second clock signals. The tri-state inverter has an input terminal connected to an output terminal of the data path and an output terminal connected to a node of the scan path.

An apparatus includes one or more control circuits configured to connect to a plurality of non-volatile memory cells arranged along word lines. The one or more control circuits are configured to receive a plurality of encoded portions of data to be programmed in non-volatile memory cells of a target word line, each encoded portion of data encoded according to an Error Correction Code (ECC) encoding scheme, and arrange the plurality of encoded portions of data in a plurality of rows of data latches corresponding to a plurality of logical pages such that each encoded portion of data is distributed across two or more rows of data latches. The one or more control circuits are also configured to program the distributed encoded portions of data from the plurality of rows of data latches into non-volatile memory cells along a target word line.

A memory is provided that is configured to practice both a conventional normal read operation and also a burst mode read operation. During the normal read operation, the memory pre-charges the bit lines in a group of multiplexed columns. Each column has a sense amplifier that latches a bit decision for the column during the normal read operation. If a subsequent read operation addresses the same group of multiplexed columns, the memory invokes the burst-mode read operation during which the bit lines are not pre-charged.

A column control circuit may include a column control signal generation circuit and a column access block signal generation circuit. The column control signal generation circuit is configured to activate an input/output strobe signal when a column access block signal is deactivated. The column control signal generation circuit is configured to deactivate the input/output strobe signal when the column access block signal is activated. The column access block signal generation circuit is configured to activate the column access block signal when gap-less read commands may be inputted. The column access block signal generation circuit may deactivate the column access block signal during a period corresponding to an N-th read command among the gap-less read commands. N is an integer that is no less than 2.

A memory device including a memory array operatively coupled to an array data bus and a deserializer circuit operatively coupled with the array data bus. The deserializer circuit includes a first ring counter including a first set of flip-flops to sequentially output a set of rising edge clock signals based on a reference clock input and a second ring counter portion including a second set of flip-flop circuits to sequentially output a set of falling edge clock signals based on the reference clock input. A rising data circuit portion of the deserializer circuit includes a set of flip-flops that each receive a rising data portion from a respective latch circuit in response to a rising edge clock signal. A falling data circuit portion of the deserializer circuit includes a set of flip-flops that each receive a falling data portion from a respective latch circuit in response to a falling edge clock signal. The third set of flip-flops outputs the set of rising data portions and the fourth set of flip-flop circuits outputs the set of falling data portions to generate a synchronized data stream to output to the array data bus in response to a common clock signal.

A memory device comprises a memory cell array and a control circuit. The control circuit applies a pass voltage to each of a selected and unselected word line from a first to second time point whenever a program loop is performed once. Then, the control circuit applies a program voltage to the selected word line and the pass voltage to the unselected word line from the second to third time point, performs a bit line precharge operation from a fourth time point ahead of the first time point to the second time point when a first program loop is performed, and performs the bit line precharge operation from the fourth time point to a fifth time point, which is the same as or ahead of the first time point, when the other program loops are performed.

Memory array circuits including word line circuits providing word line signal stability are disclosed. In a memory access operation, the states of word line signals on word lines in the memory rows of the memory array may be based on the states of word line latches during a first clock state of a latch clock signal. The word line latches receive address decode signals generated from a decoded memory address. An inverted delay clock circuit generates a clock pulse from the latch clock signal. The word line latches store the address decode signals during the clock pulse and generate word line signals based on the stored address decode signals. The memory address is received from an address bus. Pass-through address capture latches maximize time available to a decoder for decoding the memory address and word line latches reduce fluctuations in the address signal being propagated to the word line signals.

A circuit for signal transmission, memory, and method for signal transmission are provided. The circuit includes: a signal processing circuit, configured to receive an input first signal, obtain a second signal by processing the first signal in a preset processing manner, and take the second signal as an output signal of the signal processing circuit; and a selection circuit, configured to receive the input first signal, the second signal and a control signal, and take the first signal or the second signal as an output signal of the selection circuit according to the control signal.

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.

Examples of the present disclosure provide apparatuses and methods for error code calculation. The apparatus can include an array of memory cells that are coupled to sense lines. The apparatus can include a controller configured to control a sensing circuitry, that is coupled to the sense lines, to perform a number of operations without transferring data via an input/output (I/O) lines. The sensing circuitry can be controlled to calculate an error code for data stored in the array of memory cells and compare the error code with an initial error code for the data to determine whether the data has been modified.