Methods, systems, and devices for activate commands for memory preparation are described. A memory device may receive an activate command for a row of a memory bank in the memory device. The activate command may include an indicator that indicates a type of an access operation associated with the activate command. The memory device may perform, based on the type of the access operation, an operation to prepare the memory device for the access operation. The memory device may then receive an access command for the access operation after performing the operation to prepare the memory device for the access operation.

A memory circuit includes an array of memory cells arranged with first word lines connected to a first sub-array storing less significant bits of data and second word lines connected to a second sub-array storing more significant bits of data. A row decoder circuit coupled to the first and second word lines generates word line signals. A word line gating circuit is configured to selectively gate passage of the word line signals to the second word lines for the second sub-array in response to assertion of a maximum value signal. A data modification circuit performs a mathematical operation on data read from the array of memory cells, and asserts the maximum value signal if the mathematical operation performed on the less significant bits of data from the first sub-array produces a maximum data value.

A signal modulation apparatus, a memory storage apparatus, and a signal modulation method are disclosed. The signal modulation apparatus includes an observation circuit, a signal modulation circuit, and a phase control circuit. The signal modulation circuit is configured to generate a second signal according to a first signal and a reference clock signal. A frequency of the first signal is different from a frequency of the second signal. The phase control circuit is configured to obtain an observation information via the observation circuit. The observation information reflects a process variation of at least one electronic component in the signal modulation apparatus. The phase control circuit is further configured to control an offset between the first signal and the reference clock signal according to the observation information.

A data receiving device of a memory device comprises a first pre-amplifier configured to receive previous data, a first reference voltage, and input data, and to output differential signals by comparing the input data with the first reference voltage in response to a clock, when the first pre-amplifier is selected in response to the previous data, a second pre-amplifier configured to receive inverted previous data, a second reference voltage, different from the first reference voltage, and the input data, and outputting a common signal in response to the clock, when the second pre-amplifier is unselected in response to the previous data; and an amplifier configured to receive the differential signals and the common signal, and to latch the input data by amplifying the differential signals.

A memory controller component of a memory system stores memory access requests within a transaction queue until serviced so that, over time, the transaction queue alternates between occupied and empty states. The memory controller transitions the memory system to a low power mode in response to detecting the transaction queue is has remained in the empty state for a predetermined time. In the transition to the low power mode, the memory controller disables oscillation of one or more timing signals required to time data signaling operations within synchronous communication circuits of one or more attached memory devices and also disables one or more power consuming circuits within the synchronous communication circuits of the one or more memory devices.

Apparatuses and methods including memory commands for semiconductor memories are described. A controller provides a memory system with memory commands to access memory. The commands are decoded to provide internal signals and commands for performing operations, such as operations to access the memory array. The memory commands provided for accessing memory may include timing command and access commands. Examples of access commands include a read command and a write command. Timing commands may be used to control the timing of various operations, for example, for a corresponding access command. The timing commands may include opcodes that set various modes of operation during an associated access operation for an access command.

An electronic device includes: a system-on-chip (SoC) including a processor, a near-memory controller controlled by the processor, and a far-memory controller controlled by the processor; a near-memory device including a first memory channel configured to communicate with the near-memory controller and operate in a first mode of a plurality of modes, and a second memory channel configured to communicate with the near-memory controller and operate in a second mode different from the first mode from among the plurality of modes; and a far-memory device configured to communicate with the far-memory controller. The first memory channel is further configured to, based on a command from the near-memory controller, change an operation mode from the first mode to the second mode.

Methods, apparatuses, and systems related to coordinating a set of timing-critical operations across parallel processing pipelines are described. The coordination may include selectively using (1) circuitry associated with a corresponding pipeline to generate enable signals associated with the timing critical operations when a separation between the operations corresponds to a number of pipelines or (2) circuitry associated with a non-corresponding or another pipeline when the separation is not a factor of the number of pipelines.

A dual-rail memory includes, in part, a memory array that operates using a first supply voltage, and a periphery circuit that operates using a second supply voltage. The periphery circuit includes, in part, a clock generation circuit and a comparator. The dual-rail memory also includes a level shifter that varies the voltage level of a number of signals of the memory between the first and second supply voltages. The clock generation circuit is adapted, among other operations, to generate a read clock signal in response to a read request signal. The level shifter is adapted to supply a reference wordline read signal in response to the read clock signal. The comparator is adapted to select a delay between the read clock signal and the reference wordline read signal in response to a difference between the first and second supply voltages.

A nonvolatile memory device includes a first memory chip and a second memory chip connected to a controller through the same channel. The first memory chip generates a first signal from a first internal clock signal based on a clock signal received from the controller. The second memory chip generates a second signal from a second internal clock signal based on the clock signal, and performs a phase calibration operation on the second signal on the basis of a phase of the first signal by delaying the second internal clock signal based on a phase difference between the first and second signals.