Drives In Detail, Part 2: Intel P4510, Optane P4800X, Memblaze PBlaze5

When Intel launched the DC P4510 earlier this year, our initial review focused on using it to test out Intel's Virtual RAID on CPU (VROC) feature. Now, we're focusing on individual drive performance and adding in power efficiency testing that wasn't practical for multi-drive RAID configurations.

Intel SSD DC P4510

When Intel launched the DC P4510 earlier this year, our initial review focused on using it to test out Intel's Virtual RAID on CPU (VROC) feature. Now, we're focusing on individual drive performance and adding in power efficiency testing that wasn't practical for multi-drive RAID configurations.

Since the P4510 launched, Intel has announced a new naming scheme for their enterprise SSDs. Their long-term plan is to push a combination of QLC drives for capacity and Optane drives for performance, but TLC drives like the P4510 aren't going away anytime soon and the P4510 is still a current-generation product.

The Intel P4510 is the middle tier of their enterprise NVMe drives with 64-layer 3D NAND. Below it sits the D5-P4320 QLC NAND SSD, and above it is the DC P4610. The Px700 product tier is empty this generation, with the P4610 pitched as the replacement for both the P4600 and the first-generation P3700. With the P4500 and P4600, Intel introduced their second-generation enterprise NVMe controller and paired it with their first-generation (32-layer) 3D NAND. The P4510 is an update to use the current 64-layer 3D TLC.

Intel SSD DC P4510 Specifications
Capacity1 TB2 TB4 TB8 TB
Form Factor2.5" 15mm U.2
InterfacePCIe 3.1 x4 NVMe 1.2
MemoryIntel 512Gb 64-layer 3D TLC
Sequential Read2850 MB/s3200 MB/s3000 MB/s3200 MB/s
Sequential Write1100 MB/s2000 MB/s2900 MB/s3000 MB/s
Random Read469k IOPS624k IOPS625.5k IOPS620k IOPS
Random Write72k IOPS79k IOPS113.5k IOPS139.5k IOPS
Maximum PowerActive10 W10 W14 W16 W
Idle5 W5 W5 W5 W
Write Endurance1.1 DWPD0.7 DWPD0.9 DWPD1.0 DWPD
Warranty5 years

With the P4510, we're finally starting to see performance specs that look comparable to high-end consumer SSDs, but unlike consumer drives the P4510 can be expected to maintain this performance indefinitely. The write endurance rating varies a bit with capacity, from a low of 0.7 DWPD up to 1.1 DWPD. Overall, this puts it in the same endurance class as the Samsung 983 ZET, but the P4510 is in a slightly higher class for performance and power consumption.

The P4510 uses a 15mm 2.5" U.2 form factor. Inside are two stacked PCBs, connected by a semi-flexible joint. The 12-channel controller and most of the DRAM are at the bottom of the drive, with thermal pads dissipating heat to the case's heatsink surface. The back side of the primary PCB has room for more DRAM (to enable the 8TB model) and a bit more NAND. But most of the NAND is on the secondary PCB, with 10 packages on each side. Due to the extra thickness of the 15mm form factor, a single large power loss protection capacitor is used instead of an array of smaller caps. The NAND and DRAM on the inner faces of the two PCBs do not get any airflow or thermal pads bridging them to the case. This lack of cooling is one of the major motivators of Intel's Ruler form factor, now standardized as EDSFF.

Intel Optane SSD DC P4800X

Intel's Optane SSD DC P4800X is the flagship model not just of Intel's SSD family, but the entire SSD market. Built around 3D XPoint memory instead of NAND flash, the Optane SSD sets the standard for low latency and high endurance. We first tested the 375GB model through remote access before the P4800X was ready for widespread release, then later reviewed the 750GB model hands-on. More recently, Intel has introduced a 1.5TB model and doubled the write endurance rating of new models to 60 DWPD.

Intel Optane SSD DC P4800X Specifications
Capacity375 GB750 GB1.5 TB
Form FactorPCIe HHHL or 2.5" 15mm U.2
InterfacePCIe 3.0 x4 NVMe
ControllerIntel SLL3D
Memory128Gb 20nm Intel 3D XPoint
Typical Latency (R/W)<10µs
Random Read (4 kB) IOPS (QD16)550,000
Random Read 99.999% Latency (QD1)60µs
Random Read 99.999% Latency (QD16)150µs
Random Write (4 kB) IOPS (QD16)500,000
Random Write 99.999% Latency (QD1)100µs
Random Write 99.999% Latency (QD16)200µs
Mixed 70/30 (4kB) Random IOPS (QD16)500,000
Sequential Read (64kB)2400 MB/s
Sequential Write (64kB)2000 MB/s
Active PowerRead8 W10 W18 W
Write13 W15 W
Idle Power5 W6 W7 W
Endurance30 DWPD60 DWPD
Warranty5 years

Memblaze PBlaze5

Memblaze is not one of the biggest names in the SSD market, but they supplied two of the most powerful SSDs in this review. Memblaze is one of many companies that offer high-end enterprise SSDs but don't manufacture their own memory or controllers. Instead, Memblaze uses the most powerful SSD controllers available on the open market: the Flashtec NVMe product family that originated with IDT and was used in one of the first PCIe SSDs, and has changed hands several times since then in corporate acquisitions, to PMC-Sierra, Microsemi and now Microchip. Major players like Intel and Samsung have their own controller ASICs that can compete in this product segment, but most other companies either go for the Flashtec controllers or a big Xilinx FPGA. Familiar controller vendors like Marvell and Silicon Motion have been eying this market segment, but so far they are only offering solutions that more or less pair up two of their smaller 8-channel controllers, rather than monolithic 16 or 32-channel controller designs.

The PBlaze5 900 series SSDs use the Flashtec NVMe2016 controller that provides 16 channels for NAND and up to 8 PCIe lanes for the host interface. The PBlaze D900 is the U.2 version and supports operating with either a PCIe 3.0 x4 host interface or in dual-port x2+x2 mode when used in a system with PCIe fabric switches that support redundant multipath connections. For our testing, the D900 has a direct PCIe x4 connection to one of the test system's CPUs.

Memblaze PBlaze5 Series Specifications
 PBlaze5 D900PBlaze5 C900
Form Factor2.5" 15mm U.2HHHL AIC
InterfacePCIe 3.0 x4PCIe 3.0 x8
ControllerMicrosemi Flashtec PM8607 NVMe2016
ProtocolNVMe 1.2a
NANDMicron 384Gb 32L 3D TLC
Capacities (TB)2 TB3.2 TB4 TB8 TB2 TB3.2 TB4 TB8 TB
Sequential Read (GB/s)3.55.36.05.95.5
Sequential Write (GB/s)2.23.23.43.52.23.23.83.8
Random Read (4 kB) IOPS825k835k823k1005k1010k1001k
Random Write (4 kB) IOPS255k280k347k328k235k288k335k348k
Latency Read (4kB)94 µs93 µs
Latency Write16 µs15 µs
PowerIdle7 W
Operating25 W
Endurance3 DWPD
WarrantyFive years

The PBlaze5 C900 is a half-height half-length add-in card with a PCIe x8 connection, giving it the possibility of providing more than 4GB/s—our 4TB sample is rated for 5.9GB/s sequential reads, and slightly over 1M random read IOPS.

The PBlaze5 900-series uses Micron's 32-layer 3D TLC NAND. The somewhat awkward 384Gb per-die capacity lends itself well to building a drive with large overprovisioning: these 4TB drives have 6TiB of NAND onboard, plenty to enable a 3 DWPD endurance rating and support very high performance despite the older and slower 3D NAND. Memblaze has also introduced newer PBlaze5 models that move to Micron's 64L TLC, but due to less extreme overprovisioning ratios the drive performance ratings aren't significantly higher.

All this performance comes at the cost of power consumption of up to 25W. The C900's add-in card form factor can easily dissipate this much with its large heatsink, but even with the bottleneck of a narrower PCIe x4 link the D900 is still very power-hungry. Memblaze uses a 2.5" 15mm U.2 case design that allows for some airflow through the drive between the two PCBs, though a typical hot-swap backplane won't provide a very clear path for this flow.

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