A memory device includes a memory cell array and a transmitter, wherein the transmitter includes a pulse amplitude modulation (PAM) encoder configured to generate a PAM-n first input signal (where n is an integer greater than or equal to 4) from data read from the memory cell array; a pre-driver configured to generate a second input signal based on the first input signal and based on a calibration code signal, and output the second input signal using a first power voltage; and a driver configured to output a PAM-n DQ signal using a second power voltage lower than the first power voltage in response to the second input signal.

A voltage calibration scan is initiated. A first value of a data state metric measured for a sample block of a memory device based on associated with a first bin of blocks designated as a current is received. The first value is designated as a minimum value. A second value of the data state metric for the sample block is measured based on a set of read voltage offsets associated with a second bin of blocks having an index value higher than the current bin. In response to determining that the second value exceeds the first value, the first bin is maintained as the current bin and the voltage calibration scan is stopped.

In a chip-to-chip signaling system includes at least one signaling link coupled between first and second ICs, the first IC has an interface coupled to the signaling link and timed by a first interface timing signal. The second IC has an interface coupled to the signaling link and timed by a second interface timing signal that is mesochronous with respect to the first interface timing signal. The second IC further has phase adjustment circuitry that adjusts a phase of the second interface timing signal using a digital counter implemented with Josephson-junction circuit elements.

Methods, systems, and apparatuses related to memory operation with common clock signals are provided. A memory device or system that includes one or more memory devices may be operable with a common clock signal without a delay from switching on-die termination on or off. For example, a memory device may comprise first impedance adjustment circuitry configured to provide a first impedance to a received clock signal having a clock impedance and second impedance adjustment circuitry configured to provide a second impedance to the received clock signal. The first impedance and the second impedance may be configured to provide a combined impedance about equal to the clock impedance when the first impedance adjustment circuitry and the second impedance adjustment circuitry are connected to the received clock signal in parallel.

Aspects of the embodiments are directed to systems and methods for performing link training using stored and retrieved equalization parameters obtained from a previous equalization procedure. As part of a link training sequence, links interconnecting an upstream port with a downstream port and with any intervening retimers, can undergo an equalization procedure. The equalization parameter values from each system component, including the upstream port, downstream port, and retimer(s) can be stored in a nonvolatile memory. During a subsequent link training process, the equalization parameter values stored in the nonvolatile memory can be written to registers associated with the upstream port, downstream port, and retimer(s) to be used to operate the interconnecting links. The equalization parameter values can be used instead of performing a new equalization procedure or can be used as a starting point to reduce latency associated with equalization procedures.

Devices and techniques are disclosed herein to extend a range of an effective delay of a delay circuit having a configurable delay limited to a first range of delay values with respect to a first edge of a clock signal. A selection circuit can selectively apply the configurable delay to a subsequent, second edge of the clock signal to extend the range of the effective delay of the delay circuit beyond the first range of delay values.

A memory device includes: first power pins in a first power area and configured to receive a first power voltage; data pins configured to transmit or receive data signals, the data pins being arranged in a first region and in a second region each including the first power area; control pins configured to transmit or receive control signals in the first region and in the second region; second power pins in a second power area between the first region and the second region and configured to receive a second power voltage different from the first power voltage; and ground pins in the second power area and configured to receive a ground voltage.

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.

A semiconductor memory system includes a first semiconductor memory die and a second semiconductor memory die. The first semiconductor memory die includes a primary data interface to receive an input data stream during write operations and to deserialize the input data stream into a first plurality of data streams, and also includes a secondary data interface, coupled to the primary data interface, to transmit the first plurality of data streams. The second semiconductor memory die includes a secondary data interface, coupled to the secondary data interface of the first semiconductor memory die, to receive the first plurality of data streams.

Systems and methods are provided that provide protection from undesired latching that may be caused by indeterminate interamble periods in an input/output data strobe (DQS) signal. Interamble compensation circuitry selectively filters out interamble states of the DQS signal to reduce provision of interamble signals to downstream components that use the DQS signal to identify data latching times.