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.

Methods, apparatuses, and systems related to an apparatus are described. The apparatus may include (1) a read state circuit configured to control the schedule/timing associated with parallel pipelines, and (2) a timing control circuit configured to coordinate output of data from the parallel pipelines.

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 controller includes a first receiver configured to compare a read reference voltage with a piece of data received through a first data line and output a first piece of data; a first duty adjuster configured to adjust a duty of the first piece of data; a second receiver configured to compare the read reference voltage with a piece of data received through a second data line and output a second piece of data; a second duty adjuster configured to adjust a duty of the second piece of data; and a training circuit configured to perform a training operation on pieces of data received through a plurality of data lines, to obtain a target read reference voltage for each piece of data and correct a duty of each piece of data based on a level of the target read reference voltage for each piece of data.

A method of operating a memory device includes receiving a duty training request, performing first training for a write path in a first period, storing a result value of the first training, performing second training for a write path in a second period, storing a result value of the second training, transmitting the result value of the first training to an external device, and receiving a duty cycle adjuster (DCA) code value corresponding to the first training result value from the external device.

A memory module is operable in a memory system with a memory controller. The memory module comprises a module control device to receive command signals and a system clock from the memory controller and to output a module clock, module C/A signals and data buffer control signals. The module C/A signals are provided to memory devices organized in one or more ranks, while the data buffer control signals, together with the module clock, are provided to a plurality of buffer circuits corresponding to respective groups of memory devices and are used to control data paths in the buffer circuits. The plurality of buffer circuits include clock regeneration circuits to regenerate clock signals with programmable delays from the module clock. The regenerated clock signals are provided to respective groups of memory devices so as to locally sync the buffer circuits with respective groups of memory devices.

A memory system includes a host circuit and a memory circuit. The host circuit controls a bandwidth of a command-address signal based on data driving cycle information. The memory circuit performs an input/output operation based on the command-address signal.

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.

Methods, apparatuses, and systems related to an apparatus are described. The apparatus may include (1) a read state circuit configured to control the schedule/timing associated with parallel pipelines, and (2) a timing control circuit configured to coordinate output of data from the parallel pipelines.

Embodiments provide a semiconductor device, and a data processing circuit and method. A chip select signal and a plurality of command signals are received through an input terminal of the data processing circuit, and a sampling signal is obtained by a receiver based on a clock signal. The chip select signal and the plurality of command signals are sampled by a latch based on the sampling signal to obtain an internal select signal and an internal command signal. The command decoder decodes the internal select signal and the internal command signal to obtain a data manipulation command.