A method of generating a multi-level signal having one of three or more voltage levels that are different from each other, the method including: performing a first voltage setting operation in which first and second voltage intervals are adjusted to be different from each other, wherein the first voltage interval represents a difference between a first pair of adjacent voltage levels and the second voltage interval represents a difference between a second pair of adjacent voltage levels; performing a second voltage setting operation in which a voltage swing width is adjusted, the voltage swing width representing a difference between a lowest and a highest voltage level among the three or more voltage levels; and generating an output data signal that is the multi-level signal based on input data including two or more bits, a result of the first voltage setting operation and a result of the second voltage setting operation.

A memory device, a host device and a method of operating the memory device are provided. The memory device includes a data signal generator configured to provide a data signal to a transmission driver, the transmission driver configured to output a multi-level signal having any one of first to third signal levels based on the data signal, a command decoder configured to receive a feedback signal from outside of the memory device and decode the feedback signal, a data signal controller configured to adjust the data signal based on a decoding result of the command decoder, and a drive strength controller configured to adjust at least one of the first to third signal levels based on the decoding result of the command decoder.

Methods, systems, and devices for multiplexing distinct signals on a single pin of a memory device are described. Techniques are described herein to multiplex data using a modulation scheme having at least three levels. The modulated data may be communicated to multiple memory dies over a shared bus. Each of the dies may include a same or different type of memory cell and, in some examples, a multi-level signaling scheme may be pulse amplitude modulation (PAM). Each unique symbol of the modulated signal may be configured to represent a plurality of bits of data.

A data transmission method for transmitting a data signal using four data signal levels during a unit interval and transmitting a data bus inversion (DBI) signal using two DBI signal levels during the unit interval, the method including: receiving n (n is a natural number) data, each of the n data including a first bit and a second bit; counting the number of data in which the first bit and the second bit have the same value among the n data; in response to the counting result being less than or equal to a predetermined number, transmitting the n data using the four data signal levels, together with a DBI signal having a first DBI signal level; and in response to the counting result being greater than the predetermined number, transmitting data, which is obtained by changing a value of either of the first bit and the second bit of the n data, using the four data signal levels, together with a DBI signal having a second DBI signal level different from the first DBI signal level.

Methods, systems, and devices for multiplexing distinct signals on a single pin of a memory device are described. Techniques are described herein to multiplex data using a modulation scheme having at least three levels. The modulated data may be communicated to multiple memory dies over a shared bus. Each of the dies may include a same or different type of memory cell and, in some examples, a multi-level signaling scheme may be pulse amplitude modulation (PAM). Each unique symbol of the modulated signal may be configured to represent a plurality of bits of data.

A memory device includes a memory cell array and a data input and output circuit configured to output a data signal (DQ signal) including data read from the memory cell array and a data strobe signal (DQS signal) including a toggle pattern associated with an operating condition of the memory device based on n-level pulse amplitude modulation (PAMn), wherein n is an integer greater than or equal to 4.

A memory device includes: a memory cell array; a data selector configured to receive data from the memory cell array, and to output the received data as first sub-data and second sub-data; a cyclic redundancy check (CRC) generator configured to generate first CRC values corresponding to the first sub-data, and to generate second CRC values corresponding to the second sub-data; a CRC selector configured to determine an order of the first CRC values and the second CRC values, and to output one of the first CRC values and one of the second CRC values according to the determined order; and a transmitter configured to receive the first CRC values and the second CRC values according to the determined order, and to transmit CRC values of the data by a multilevel signaling method.

A multi-level signal receiver includes a data sampler circuit and a reference voltage generator circuit. The data sampler includes (M−1) sense amplifiers which compare a multi-level signal having one of M voltage levels different from each other with (M−1) reference voltages. The data sampler generates a target data signal including N bits, M is an integer greater than two and N is an integer greater than one. The reference voltage generator generates the (M−1) reference voltages, At least two sense amplifiers of the (M−1) sense amplifiers have different sensing characteristics.

A multi-level signal transmitter includes a voltage selection circuit, which is configured to select one amongst a plurality of driving voltages, which have different voltage levels, in response to input data including at least two bits of data therein. A driver circuit is also provided, which is configured to generate an output data signal as a multi-level signal, in response to the selected one of the plurality of driving voltages. This selected signal is provided as a body bias voltage to at least one transistor within the driver circuit. This driver circuit may include a totem-pole arrangement of first and second MOS transistors having respective first and second body bias regions therein, and at least one of the first and second body bias regions may be responsive to the selected one of the plurality of driving voltages.

A method of operating a memory device including receiving a multilevel signal having M levels transmitted by an external controller through a clock receiving pin, where M is a natural number greater than 2, and decoding the multilevel signal to restore at least one of Data Bus Inversion (DBI) data, Data Mask (DM) data, Cyclic Redundancy Check (CRC) data, or Error Correction Code (ECC) data may be provided. The multilevel signal is a clock signal transmitted by the external controller, and is a signal swinging based on an intermediate reference signal that is an intermediate value between a minimum level and a maximum level among the M levels.