A system-on-chip is connected to a first memory device and a second memory device. The system-on-chip comprises a memory controller configured to control an interleaving access operation on the first and second memory devices. A modem processor is configured to provide an address for accessing the first or second memory devices. A linear address remapping logic is configured to remap an address received from the modem processor and to provide the remapped address to the memory controller. The memory controller performs a linear access operation on the first or second memory device in response to receiving the remapped address.

Power consumption can be reduced by selective memory chip hibernation. For example, a computing device can allocate first data associated with a first processing operation of a user device to a first chip of a dynamic random access memory (DRAM) of the user device. The computing device can allocate second data associated with a second processing operation of the user device to a second chip of the DRAM of the user device. The computing device can determine the first processing operation has been inactive for a predetermined period of time and migrate the first data from the first chip of the DRAM to a storage device of the user device. The computing device can hibernate the first chip of the DRAM while maintaining power to the second chip of the DRAM for continuing to perform the second processing operation.

Various embodiments are generally directed to techniques for memory access by a computer in a reduced power state, such as during video playback or connected standby. Some embodiments are particularly directed to disabling one or more memory channels during a reduced power state by mapping memory usages during the reduced power state to one of a plurality of memory channels. In one embodiment, for example, one or more low-power mode blocks in a set of functional blocks of a computer may be identified. In some such embodiments, the computer may include a processor, a memory, and first and second memory channels to communicatively couple the processor with the second memory. In many embodiments, usage of the one or more low-power mode blocks in the set of functional blocks may be mapped to a first address range associated with the first memory channel.

Disclosed is a user system which includes a first device and a second device, which share a shared voltage, and a power management integrated circuit (PMIC) generating the shared voltage. An operation method of the user system includes performing a first operation of the first device, determining whether a second operation of the second device is to be performed while the first device performs the first operation, based on an operation profile, and when it is determined that the second operation of the second device is to be performed while the first device performs the first operation, changing a power mode of the PMIC from a first power mode to a second power mode, before the second device performs the second operation. The PMIC generates the shared voltage based on the first power mode or the second power mode.

A data storage device and method for low-latency power state transitions by having power islanding in a host memory buffer are provided. In one embodiment, a data storage device is provided comprising a volatile memory, a non-volatile memory, and a controller. The controller is configured to receive information from a host about which area, if any, in a host memory buffer will be powered on during a low-power state; and in response to the information indicating that a first area of the host memory buffer will be powered on during the low-power state, flush data from a second area of the host memory buffer that will not be powered on during the low-power state to the first area of the host memory buffer prior to entering the low-power state. Other embodiments are provided.

Responsive to a power-on of a memory device, an elapsed power-off time is identified based on a difference between a time at which the power-on occurred and a time at which a previous power-off of the memory device occurred. Responsive to a determination that the elapsed power-off time satisfies the elapsed time threshold criterion, a request to perform a first write operation on a memory unit of the memory device since power on is received, a performance parameter associated with the memory unit of the memory device is changed to a first parameter value that corresponds to a reduced performance level, and the write operation is performed on the memory unit of the memory device in accordance with the first parameter value that corresponds to the reduced performance level. Responsive to completion of the write operation, the performance parameter is changed to a value that corresponds to a normal performance level.

A memory system includes: a first nonvolatile memory; a second volatile memory; a controller; a power control circuit configured to perform control such that a first voltage is applied to the first memory, the second memory, and the controller based on first power supplied from an external power supply; and a power storage device configured to supply second power to the power control circuit while the first power from the external power supply is interrupted. While the first power supplied from outside is interrupted, the power control circuit applies a second voltage based on the second power supplied from the power storage device to the first memory, the second memory, and the controller. The power control circuit stops the application of the second voltage to the second memory after the data is read from the second memory and before the data is written into the first memory.

Methods, systems, and devices for power control for boot-up of memory systems are described. A memory system may be configured to boot-up using two different power modes: a lower-power mode, and a higher-power mode. The memory system may perform a series of evaluations to determine whether the memory system is to switch to the lower-power mode during boot-up operations, or stay in the higher-power mode. For example, the memory system may check one or more of: a history of previous boot-up failures, a voltage of an associated power management integrated circuit, a history of asynchronous power loss at the device, a power-mode configuration of the host device, or a history of host-initiated power-down commands. In some examples, by switching to the lower-power mode, the memory system may avoid repeatedly failing multiple boot-up cycles and may instead successfully boot-up the memory system.

A storage controller includes a plurality of pipeline stages configured to process data. A system clock signal is received that has a system frequency and at least one performance metric is determined for one or more pipeline stages of the plurality of pipeline stages. A first clock signal is generated having a first frequency for operation of a first pipeline stage of the plurality of pipeline stages. Based at least in part on the at least one determined performance metric, a second clock signal is generated having a second frequency for operation of a second pipeline stage of the plurality of pipeline stages. The second frequency is less than the system frequency and may also differ from the first frequency.

A memory system includes a nonvolatile memory and a controller that includes an encoder configured to encode a first group of data including a plurality of first data, each first data having a plurality of bits. The encoder is configured to perform a first encoding process of generating a second group of data including a plurality of second data from the plurality of first data in the first group, and a second encoding process of generating a third group of data including a plurality of third data from the plurality of second data in the second group. A logical value of “1” is less likely to be the value in an n-th bit position of the plurality of third data in the third group than the value in any of the bit positions of the plurality of second data in the second group.