There are provided a memory device for supporting a command bus training (CBT) mode and a method of operating the same. The memory device is configured to enter a CBT mode or exit from the CBT mode in response to a logic level of a first data signal, which is not included in second data signals, which are in one-to-one correspondence with command/address signals, which are used to output a CBT pattern in the CBT mode. The memory device is further configured to change a reference voltage value in accordance with a second reference voltage setting code received by terminals associated with the second data signals, to terminate the command/address signals or a pair of data clock signals to a resistance value corresponding to an on-die termination (ODT) code setting stored in a mode register, and to turn off ODT of data signals in the CBT mode.

A memory device includes: a memory bank including a plurality of memory cells; and a memory interface circuit configured to store data in the plurality of memory cells based on a command/address signal and a data signal, wherein the memory interface circuit includes: first, second, third and fourth pads configured to receive first, second, third and fourth clock signals, respectively; a first buffer circuit configured to sample the command/address signal in response to an activation time of the first and third clock signals which have opposite phases from each other; and a second buffer circuit configured to sample the data signal in response to the activation time of the first clock signal, an activation time of the second clock signal, the activation time of the third clock signal and an activation time of the fourth clock signal.

Methods for improving timing in memory devices are disclosed. A method may include sampling a command signal according to a clock signal to obtain standard-timing commands. The method may also include sampling the command signal according to an adjusted clock signal to obtain time-adjusted commands. The method may also include comparing the standard-timing commands and the time-adjusted commands. The method may also include determining an improved timing for the clock signal based on the comparison of the standard-timing commands and the time-adjusted commands. The method may also include adjusting the clock signal based on the improved timing. Associated systems and methods are also disclosed.

In an anti-fuse memory reading circuit with controllable reading time, a reading time control circuit generates a control signal corresponding to reading time. Based on a clock signal, a programmable reading pulse generation circuit generates a reading pulse with a pulse width corresponding to the control signal. Based on the reading pulse and the control signal, the reading amplification circuit selects a pull-up current source corresponding to the reading time, pulls up a voltage on a bit line (BL) of an anti-fuse memory cell, reads data stored in the anti-fuse memory cell starting from a rising edge of the reading pulse, and latches the read data at a falling edge of the reading pulse. The anti-fuse memory reading circuit can generate a reading pulse with a corresponding pulse width and a pull-up current source with a corresponding size based on the required reading time.

A semiconductor device comprises: a first or a second path configured to transmit a first signal which swings between a ground level and a first level, a third path configured to transmit a second signal which swings between the ground level and a second level lower than the first level, a transmitter configured to output received the first signal through the first or second path as the second signal to the third path, and initialize in response to an enable signal, and a receiver configured to output received the second signal through the third path as the first signal through the first or second path, determine level of the second signal through a reference level that is regulated according to a fed-back level of an output terminal thereof, and initialize in response to the enable signal.

A memory module can be programmed to deliver relatively wide, low-latency data in a first access mode, or to sacrifice some latency in return for a narrower data width, a narrower command width, or both, in a second access mode. The narrow, higher-latency mode requires fewer connections and traces. A controller can therefore support more modules, and thus increased system capacity. Programmable modules thus allow computer manufacturers to strike a desired balance between memory latency, capacity, and cost.

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 memory controller interfaces with a dynamic random access memory (DRAM). The memory controller selectively places memory commands in a memory interface queue, and transmits the commands from the memory interface queue to a memory channel connected to at least one dynamic random access memory (DRAM). The transmitted commands are stored in a replay queue. A number of activate commands to a memory region of the DRAM is counted. Based on this count, a refresh control circuit signals that an urgent refresh command should be sent to the memory region. In response to detecting a designated type of error, a recovery sequence initiates to re-transmit memory commands from the replay queue. Designated error conditions can cause the recovery sequence to restart. If an urgent refresh command is pending when such a restart occurs, the recovery sequence is interrupted to allow the urgent refresh command to be sent.

A method can include, in an integrated circuit device: at a unidirectional command-address (CA) bus having no more than four parallel inputs, receiving a sequence of no less than three command value portions; latching each command value portion in synchronism with rising edges of a timing clock; determining an input command from the sequence of no less than three command value portions; executing the input command in the integrated circuit device; and on a bi-directional data bus having no more than six data input/outputs (IOs), outputting and inputting sequences of data values in synchronism with rising and falling edges of the timing clock. Corresponding devices and systems are also disclosed.

A memory controller configured to control a non-volatile memory device includes: a signal generator configured to generate a plurality of control signals comprising a first signal and a second control signal; a core configured to provide a command for an operation of the non-volatile device; and a controller interface circuit configured to interface with the non-volatile memory device, wherein the controller interface circuit comprises a first transmitter connected to a first signal line and a second signal line; and a first receiver connected to the first signal line, and the first control signal and the second control signal are respectively transmitted to the non-volatile memory device through the first signal line and the second signal line.