Methods and apparatus for precise power cycle management in data storage devices are provided. One such apparatus is a data storage device that includes a non-volatile memory (NVM) and a processor coupled to the NVM. In such case, the processor is configured to determine a first peak power for a first power phase, operate the DSD at a first DSD power consumption that is less than the first peak power for the first power phase, determine a second peak power for a second power phase based on a residual power equal to a difference between a preselected average power threshold and the first DSD power consumption, and operate the DSD at a second DSD power consumption that is less than the second peak power for the second power phase.

A position-measuring device includes a graduation carrier having a measuring graduation, position measurement electronics, a data memory and a power supply. The data memory includes a first memory which is a volatile memory for storing additional data, a second memory which is a writable non-volatile memory, and a memory controller for controlling transfer and storage of additional data from the first into the second memory. The power supply includes an input stage, a first output stage for the position measurement electronics, a second output stage for the data memory, and a voltage monitor which will turn off the first output stage of the power supply in response to a drop below a minimum value and signal the drop to the memory controller by a backup signal. In response to the backup signal, the memory controller will transfer additional data from the first memory into the second memory.

A position-measuring device includes a graduation carrier having a measuring graduation, position measurement electronics, a data memory and a power supply. The data memory includes a first memory which is a volatile memory for storing additional data, a second memory which is a writable non-volatile memory, and a memory controller for controlling transfer and storage of additional data from the first into the second memory. The power supply includes an input stage, a first output stage for the position measurement electronics, a second output stage for the data memory, and a voltage monitor which will turn off the first output stage of the power supply in response to a drop below a minimum value and signal the drop to the memory controller by a backup signal. In response to the backup signal, the memory controller will transfer additional data from the first memory into the second memory.

Systems and methods, according to the present disclosure, determines a duration of the current queue of commands in the controller, executes all full commands capable of being executed prior to the beginning of a low power cycle. Commands that are not executed may be re-fetched when the device enters a power mode. In an alternate embodiment, a portion of a command that is executable prior to the beginning of a low power cycle is executed, with the un-executed portion of the command being stored on the device, in an “always on” or AON memory. This un-executed portion is fetched and executed when the device enters the power mode.

Methods, systems, and devices for dynamic power control are described. In some examples, a memory device may be configured to adjust a first duration for transitioning power modes. For example, the memory device may be configured to operate in a first power mode, a second power mode, and a third power mode. When operating in a second power mode, the memory device may be configured to increase or decrease the first duration for transitioning to a third power mode based on a second duration between received commands. If no commands are received during the first duration, the memory device may transition from the second power mode to the third power mode.

Methods, systems, and devices for dynamic power control are described. In some examples, a memory device may be configured to adjust a first duration for transitioning power modes. For example, the memory device may be configured to operate in a first power mode, a second power mode, and a third power mode. When operating in a second power mode, the memory device may be configured to increase or decrease the first duration for transitioning to a third power mode based on a second duration between received commands. If no commands are received during the first duration, the memory device may transition from the second power mode to the third power mode.

Logical memory is divided into two regions. Data in the first region is always retained. The first region of memory is designated online (or powered on) and is not offlined during standby or low power mode. The second region is the rest of the memory which can be potentially placed in non-self-refresh mode during standby by offlining the memory region. Content in the second region can be moved to the first region or can be flushed to another memory managed by the operating system. When the first region does not have enough space to accommodate data from the second region, the operating system can increase the logical size of the first region. Retaining the content of the first region by putting that region in self-refresh and saving power in the second region by not putting it in self-refresh is performed by an improved Partial Array Self Refresh scheme.

Systems and methods for injecting a toggling signal in a command pipeline configured to receive a multiple command types for the memory device. Toggling circuitry is configured to inject the toggling signal into at least a portion of the command pipeline when the memory device is in a power saving mode and the command pipeline is clear of valid commands. The toggling is blocked from causing writes by disabling a data strobe when a command that is invalid in the power saving mode is asserted during the power saving mode.

A peripheral component interconnect express (PCIe) interface device is provided to include: a root complex configured to support a PCIe port, a memory connected to an input/output structure through the root complex, a switch connected to the root complex through a link and configured to transmit a transaction, and an end point connected to the switch through the link to transmit and receive a packet. The PCIe interface device may perform a link power management by changing a state of the link in response to a detection of an idle state of the link.

A control apparatus to control a solid state drive having a thermal throttling function includes a controller. The controller performs control to activate the thermal throttling function of the solid state drive at a first temperature from startup of the control apparatus to startup completion. The controller also performs control to activate the thermal throttling function of the solid state drive at a second temperature that is lower than the first temperature after the startup completion of the control apparatus.