Methods, systems, and devices for masked training and analysis with a memory array are described. A memory device may operate in a first mode in which a maximum transition avoidance (MTA) decoder for a memory array of the memory device is disabled. During the first mode, the memory device may couple an input node of the MTA decoder with a first output node of a first decoder, such as a first pulse amplitude modulation (PAM) decoder. The memory device may operate in a second mode in which the MTA decoder for the memory array is enabled. During the second mode, the memory device may couple the input node of the MTA decoder with a second output node of a second decoder, such as a second PAM decoder.

Methods, systems, and devices for multi-driver signaling are described. An apparatus may include a first voltage source configured to supply a positive voltage and a second voltage source configured to supply a negative voltage. The apparatus may also include a first driver configured to couple a transmission line of a bus with the first voltage source and a second driver configured to couple the transmission line of the bus with the second voltage source. The first driver may be configured to transfer current to the transmission line based on a configurable resistance of the first driver. And the second driver configured to transfer current from the transmission line of the bus based on a configurable resistance of the second driver.

A memory module includes a plurality of memory integrated circuit (IC) packages to store data and a command buffer IC to buffer one or more memory commands destined for the memory IC packages. The command buffer IC includes a first interface circuit and one or more second interface circuits. The first interface circuit receives the one or more memory commands. The one or more second interface circuits output a pre-programmed command sequence to one or more devices separate from the command buffer IC, the pre-programmed command sequence output in response to the one or more memory commands matching a pre-programmed reference command pattern.

Apparatuses and methods for signal line buffer timing control are disclosed. An example apparatus includes a plurality of signal lines including first and second control lines and further including data lines, and further includes first and second signal line buffers. The first signal line buffer includes first driver circuits configured to drive respective data signals on the data lines and to drive first and second control signals on the first and second control lines, respectively. The second signal line buffer includes second driver circuits configured to be activated to receive the data signals. The first and second control signals arrive at the second signal line buffer at different times. The second driver circuits are activated responsive a later one of active first and second control signals and are deactivated responsive to an earlier one of inactive first and second control signals.

A level shifter receives an input signal in a first power domain and generates a corresponding output signal in a second power domain. The transition time of the output signal may be longer during a low-to-high transition than during a high-to-low transition or vice versa. The level shifter may provide two outputs, wherein one of the two outputs has a shorter transition time during a high-to-low transition and the other output has a shorter transition time during a low-to-high transition. By using an inverter on the second output, two non-inverted outputs are generated with different transition times. A ramp selection circuit is used to select between the first output and the inverted second output. The ramp selection circuit selects the output with the shortest transition time.

A data receiving circuit is provided. The data receiving circuit includes a data input circuit, a latch circuit, and an equalizer. The data input circuit is configured to receive an input signal. The latch circuit is connected to the data input circuit and configured to output an output signal in response to the input signal. The equalizer is connected to the latch circuit and configured to provide a first voltage at a first node and a second voltage at a second node at an equalizing stage. The first voltage is different from the second voltage.

An encoder includes an encoding unit configured to receive 2n-bit read data and to generate 2m-bit read data, and an output driver configured to input m-bit first read data of the 2m-bit read data, to transmit voltage and/or current a first number of times corresponding to a number of first bits indicating a first state included in the m-bit first read data or to transmit current corresponding to the number of first bits during an activation period of a clock signal, and to transmit the voltage and/or the current a second number of times corresponding to a number of second bits indicating the first state included in m-bit second read data of the 2m-bit read data or to transmit current corresponding to the number of second bits during a deactivation period of the clock signal, wherein n is at least 2 and m is at least 3.

An input circuit includes: a buffer circuit coupled to a pad, the buffer circuit being driven by a first power voltage; a level shifter circuit coupled to an output terminal of the buffer circuit, the level shifter circuit being driven by a second power voltage; and a voltage stabilization circuit coupled to an input node of the level shifter circuit, the voltage stabilization circuit being driven by the first power voltage and the second power voltage. The voltage stabilization circuit maintains a voltage of the input node of the level shifter circuit equal to or less than a given level sufficient to keep an output signal of the level shifter circuit at a specific logic value, when a voltage level of the second power voltage is rising and a voltage level of the first power voltage is kept at a low level.

Provided are an apparatus, a memory device, and a method for storing a plurality of parameter codes for an operation parameter. The memory device includes a mode register and a control logic circuit. To set a first operating condition and a second operating condition for one operation parameter, the mode register stores a first parameter code for the operation parameter and a second parameter code, which is expressed as an offset value from the first parameter code. The control logic circuit sets the first operating condition as a current operating condition of the memory device by using the first parameter code based on a first control code and sets the second operating condition as the current operating condition of the memory device by using the first parameter code and the second parameter code based on a second control code.

An operating method of a non-volatile memory device comprises: performing a foggy operation applying a first application voltage to a word line and applying a first verification voltage having a same level as or a higher level than a target threshold voltage to the word line, determining whether the foggy operation is completely performed according to whether a number of memory cells each having a threshold voltage higher than the first verification voltage is equal to or greater than a first number, performing a fine operation applying a second application voltage to the word line and applying a second verification voltage having the same level as the target threshold voltage, and determining whether the fine operation is completely performed, according to whether a number of memory cells each having a threshold voltage lower than the second verification voltage is less than or equal to a second number.