A physically unclonable function (PUF) includes a bit cell that includes a latch and a switch to selectively couple the latch to a supply voltage node. A first transmission gate couples a first bit line to a first internal node of the latch and a second transmission gate couples a second bit line to a second internal node of the latch. A digital to analog converter (DAC) circuit is selectively coupled to the first internal node through the first bit line and the first transmission gate and to the second internal node through the second bit line and the second transmission gate, to thereby precharge the latch before the first bit cell is read. The latch regenerates responsive to the switch being closed to connect the latch to the supply voltage node. The first and second bit lines are used to read the regenerated value of the latch.

This document describes apparatuses and techniques for multi-rail power transition. In various aspects, a power rail controller transitions a memory circuit (e.g., of a memory die) from a first power rail to a second power rail. The power rail controller then changes a voltage of the first power rail from a first voltage to a second voltage. The power rail controller may also adjust termination impedance or a clock frequency of the memory circuit before transitioning the memory circuit to the second power rail. The power rail controller then transitions the memory circuit from the second power rail to the first power rail to enable operation of the memory circuit at the second voltage. By so doing, the power rail controller may improve the reliability of memory operations when transitioning operation of the memory circuit from the first voltage to the second voltage.

An integrated circuit device may include a programmable fabric die having programmable logic fabric and configuration memory that may configure the programmable logic fabric. The integrated circuit device may also include a base die that may provide fabric support circuitry, including memory and/or communication interfaces. The first die and the second die may be coupled using a multi-purpose interface that may allow communication between the first die and the second die. The multi-purpose interface may allow concurrent access to the base die by the programmable logic fabric and the configuration memory by using multiple channels over the multi-purpose interface.

A bit line is pre-charged based on a clock signal internal to a bit line pre-charge circuit when a bit line pre-charge window is within a margin of a predetermined pre-charge window. A bit line is pre-charged based on a clock signal external to the bit line pre-charge circuit when the bit line pre-charge window is outside the margin of the predetermined pre-charge window.

Methods, systems, and apparatuses related to memory operation with on-die termination (ODT) are provided. A memory device may be configured to provide ODT at a first portion (e.g., rank) during communications at a second portion (e.g., rank). For example, a memory device may receive a first command instructing a first portion to perform a first communication. The device may transmit, from the first portion, a signal instructing a second portion to enter an ODT mode. The device may perform, with the first portion, the first communication with a host while the second portion is in the ODT mode. The signal may be provided at an ODT I/O terminal of the first portion coupled to an ODT I/O terminal of the second portion.

One or more memory systems, architectural structures, and/or methods of storing information in memory devices is disclosed to improve the data bandwidth and or to reduce the load on the communication links. The system may include one or more memory devices, one or more memory control circuits and one or more data buffer circuits. The memory system, architectural structure and/or method improves the ability of the communications links to transfer data downstream to the data buffer circuits. The memory control circuit receives a store command and a store data tag (Host tag) from a Host and sends the store data command and the store data tag to the data buffer circuits. No store data tag or control signal is sent over the communication links between the Host and the data buffer circuits, only data is sent over the communication links between the Host and the data buffer circuits.

Systems, apparatuses, and methods related to a selectively operable memory device are described. An example method corresponding to a selectively operable memory device can include receiving, by a resistance variable memory device, a command to operate the resistance variable memory device in a first mode or a second mode and operating the resistance variable memory device in the first mode or the second mode based, at least in part, on the received command to perform, in the first mode, a read operation or a write operation, or both, or, in the second mode, a compute operation. The method can further include performing, using a processing unit resident on the resistance variable memory device, the compute operation, the testing operation, or both based, at least in part, on a determination that the resistance variable memory device is operating in the second mode.

Methods, systems, and devices for timing signal delay compensation in a memory device are described. In some memory devices, operations for accessing memory cells may be performed with timing that is asynchronous relative to an input signal. To support asynchronous timing, a memory device may include delay components that support generating a timing signal having aspects that are delayed relative to an input signal. In accordance with examples as disclosed herein, a memory device may include delay components having a variable and configurable impedance, where the configurable impedance may be based at least in part on a configuration signal generated at the memory device. A configuration signal may be generated based on fabrication characteristics of the memory device, or based on operating conditions of the memory device, or various combinations thereof.

A semiconductor system may include a first semiconductor device and a second semiconductor device. The first semiconductor device compares a received signal with an original signal to generate a driving force control signal. The first semiconductor device also drives the original signal using a driving force in accordance with the driving force control signal to output an external transmission signal. The second semiconductor device receives the external transmission signal to generate a positive signal and a negative signal. The second semiconductor device also generates a restoration signal in response to the positive signal and the negative signal. The second semiconductor device additionally outputs the restoration signal as the external transmission signal to the first semiconductor device.

A memory device as provided may apply a pulse amplitude modulation method to data (DQ) signal transmission/reception and may scale a DQ signal according to an operating frequency condition, so as to improve data transmission performance and effectively improve power consumption. The memory device includes a memory cell array, and a data input/output circuit configured to scale a DQ signal that includes data read from the memory cell array and output the scaled DQ signal. The data input/output circuit is configured to scale the DQ signal based on an n-level pulse amplitude modulation (PAMn) (where n is 4 or a greater integer) with a DQ parameter that corresponds an operating frequency condition and output the DQ signal. Other aspects include memory controllers that communicate with the memory devices, and memory systems that include the memory devices and memory controllers.