A memory system includes a memory controller and a semiconductor storage device including a power supply pad, first, second, third, and fourth signal pads to which first, second, third, and fourth signals are respectively input, a memory cell array, a data register, and a control circuit executing an operation to output data stored in the data register through the fourth signal pad. The memory controller performs a mode setting operation by toggling the third signal input, after at least the first or second signal has been switched at a first timing after supplying power to the power supply pad, perform an initial setting operation by transmitting a power-on read command at a second timing after the first timing, and transmit a data-out command, at a third timing after the second timing. The semiconductor storage device receives the power-on read and data-out commands via the first and second signal pads.

An IC includes a first set of core logic configured to convert data between a single stream and a double stream, and a first data I/O block on a first side of the first set of core logic. The first data I/O block interfaces with the first set of core logic and a DRAM. The IC further includes a second set of core logic configured to process CA information, and a first CA I/O subblock on a second side of the first set of core logic. The first CA I/O subblock interfaces with the second set of core logic and the DRAM. The IC further includes a first set of power switches adjacent at least one side of the first CA I/O subblock. The first set of power switches is coupled to the first set of core logic and the second set of core logic.

In an embodiment, a memory system may include at least two types of DRAM, which differ in at least one characteristic. For example, one DRAM type may be a high density DRAM, while another DRAM type may have lower density but may also have lower latency and higher bandwidth than the first DRAM type. DRAM of the first type may be on one or more first integrated circuits and DRAM of the second type may be on one or more second integrated circuits. In an embodiment, the first and second integrated circuits may be coupled together in a stack. The second integrated circuit may include a physical layer circuit to couple to other circuitry (e.g., an integrated circuit having a memory controller, such as a system on a chip (SOC)), and the physical layer circuit may be shared by the DRAM in the first integrated circuits.

Apparatuses and methods can be related to configuring interface protocols for memory. An interface protocol can define the commands received by a memory device utilizing pins of an interface of a memory device. An interface protocol used by a memory device can be implemented utilizing a decoder of signals provided through the pins of the memory device. The decoder utilized by a memory device can be selected by setting a mode register of the memory device.

Apparatuses, systems, and methods for faster memory access regions. A memory array may have a first bank which has a greater access speed than a second bank. For example the first bank may have a reduced read latency compared to the second bank. The first bank may have structural differences, such as reduced word line and/or reduced global input output (GIO) line length. In some embodiments, the first and second bank may have separate bank pad data buses, and data terminals. In some embodiments, they may share the bank pads data bus, and data terminals. In some embodiments, when an access command is received for the first (faster) bank while an access command to the second (slower) bank is still processing, the access to the faster bank may interrupt the access to the slower bank.

Apparatus and methods are disclosed, including memory devices and systems. Example memory devices, systems and methods include a buffer interface to translate high speed data interactions on a host interface side into slower, wider data interactions on a DRAM interface side. The slower, and wider DRAM interface may be configured to substantially match the capacity of the narrower, higher speed host interface. In some examples, the buffer interface may be configured to provide multiple sub-channel interfaces each coupled to one or more regions within the memory structure and configured to facilitate data recovery in the event of a failure of some portion of the memory structure. Selected example memory devices, systems and methods include an individual DRAM die, or one or more stacks of DRAM dies coupled to a buffer die.

A memory device, and a method of operating the same, includes a plurality of pages, a peripheral circuit, and control logic. The peripheral circuit is configured to receive a command, an address, and data from an external controller to program a page selected from among the plurality of pages, and to generate internal input data depending on an input mode for the command, the address, and the data. The control logic is configured to determine whether internal input data is to be generated based on the data depending on the input mode and to control the peripheral circuit so that a program operation of programming the internal input data is performed.

Methods, systems, and devices for pin mapping for memory devices are described. An apparatus may include a memory array, a plurality of pins, a selector, and a mapping component. The memory array may include a plurality of data lines coupled with a plurality of memory cells. The mapping component may be configured to map a set of data lines to a first set of pins when the selector reflects a first state and to a second set of pins when the selector reflects a second state. The first and second set of pins may have a same quantity of pins. The second set of pins may include pins that are otherwise unused in the second state. The mapping component may be configured to selectively couple unused pins to a fixed potential.

A memory system includes a dynamic random access memory (DRAM) device, a second memory device, and a memory controller circuit. The memory controller circuit is coupled to the DRAM device by a first data channel configured to transfer first data between the memory controller circuit and the DRAM device on behalf of a host, and is also coupled to the DRAM device by a second data channel configured to transfer second data between the memory controller circuit and the DRAM device on behalf of the second memory device while the first data is being transferred across the first data bus.

Memory devices, systems and methods include a buffer interface to translate high speed data interactions on a host interface side into slower, wider data interactions on a DRAM interface side. The slower, and wider DRAM interface may be configured to substantially match the capacity of the narrower, higher speed host interface. In some configurations, the buffer interface may be configured to provide multiple sub-channel interfaces each coupled to one or more regions within the memory structure and configured to facilitate data recovery in the event of a failure of some portion of the memory structure. Selected memory devices, systems and methods include an individual DRAM die, or one or more stacks of DRAM dies coupled to a buffer die.