Power Management - The Corsair Force MP510 SSD (960GB) Review: A High-End Contender

Posted by Jenniffer Sheldon on Sunday, March 24, 2024

Power Management Features

Real-world client storage workloads leave SSDs idle most of the time, so the active power measurements presented earlier in this review only account for a small part of what determines a drive's suitability for battery-powered use. Especially under light use, the power efficiency of a SSD is determined mostly be how well it can save power when idle.

For many NVMe SSDs, the closely related matter of thermal management can also be important. M.2 SSDs can concentrate a lot of power in a very small space. They may also be used in locations with high ambient temperatures and poor cooling, such as tucked under a GPU on a desktop motherboard, or in a poorly-ventilated notebook.

Corsair Force MP510
NVMe Power and Thermal Management Features
ControllerPhison PS5012-E12
FirmwareECFM11.0
NVMe
Version
FeatureStatus
1.0Number of operational (active) power states2
1.1Number of non-operational (idle) power states3
Autonomous Power State Transition (APST)Supported
1.2Warning Temperature70 °C
Critical Temperature90 °C
1.3Host Controlled Thermal ManagementSupported
 Non-Operational Power State Permissive ModeNot Supported

The Corsair Force MP510 implements all the usual NVMe power management features and has a comfortably high thermal throttling point. The drive's declared maximum power levels for the active power states look alarmingly high, but our testing didn't push the MP510 anywhere near the claimed 10.73W peak. The idle power states advertise low idle power with quick transition latencies, and our testing of power state 3 shows that the drive isn't exaggerating at all.

Corsair Force MP510
NVMe Power States
ControllerPhison PS5012-E12
FirmwareECFM11.0
Power
State
Maximum
Power
Active/IdleEntry
Latency
Exit
Latency
PS 010.73 WActive--
PS 17.69 WActive--
PS 26.18 WActive--
PS 349 mWIdle2 ms2 ms
PS 41.8 mWIdle25 ms25 ms

Note that the above tables reflect only the information provided by the drive to the OS. The power and latency numbers are often very conservative estimates, but they are what the OS uses to determine which idle states to use and how long to wait before dropping to a deeper idle state.

Idle Power Measurement

SATA SSDs are tested with SATA link power management disabled to measure their active idle power draw, and with it enabled for the deeper idle power consumption score and the idle wake-up latency test. Our testbed, like any ordinary desktop system, cannot trigger the deepest DevSleep idle state.

Idle power management for NVMe SSDs is far more complicated than for SATA SSDs. NVMe SSDs can support several different idle power states, and through the Autonomous Power State Transition (APST) feature the operating system can set a drive's policy for when to drop down to a lower power state. There is typically a tradeoff in that lower-power states take longer to enter and wake up from, so the choice about what power states to use may differ for desktop and notebooks.

We report two idle power measurements. Active idle is representative of a typical desktop, where none of the advanced PCIe link or NVMe power saving features are enabled and the drive is immediately ready to process new commands. The idle power consumption metric is measured with PCIe Active State Power Management L1.2 state enabled and NVMe APST enabled if supported.

Active Idle Power Consumption (No LPM)Idle Power Consumption

The Corsair Force MP510 has the best active idle power consumption we've seen from a high-end NVMe SSD, and with APST enabled it is second only to Silicon Motion's latest generation of NVMe controllers in deep sleep power savings on our desktop testbed.

Idle Wake-Up Latency

This is complemented by a nice quick wakeup from sleep, so aggressive power management settings won't hurt system responsiveness.

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