QD1 Random Read Performance

Drive throughput with a queue depth of one is usually not advertised, but almost every latency or consistency metric reported on a spec sheet is measured at QD1 and usually for 4kB transfers. When the drive only has one command to work on at a time, there's nothing to get in the way of it offering its best-case access latency. Performance at such light loads is absolutely not what most of these drives are made for, but they have to make it through the easy tests before we move on to the more realistic challenges.

4kB Random Read QD1

The Micron 5100 MAX has about 20% worse QD1 random read performance than the Kingston drives. This is primarily due to the underlying NAND: the 5100 MAX uses first-generation Intel/Micron 3D TLC, which was consistently slower than their newer 64L 3D NAND. But even the 64L Intel NAND used by Kingston's drives is still slower than Samsung's drives.

4kB Random Read QD1 (Power Efficiency)
Power Efficiency in kIOPS/W Average Power in W

The Kingston DC450R uses a bit less power than the other two Kingston drives and thus ends up with the best efficiency rating among the three, but they're all considerably more power-hungry than the Samsung SATA drives. The Micron 5100 MAX uses only slightly more power than the Samsung SATA drives, but its lower performance leaves it with a similar efficiency score to the Kingston drives.

4kB Random Read QD1 QoS

The Micron 5100 MAX stands out from the newer drives for having much worse tail latency scores, despite being a very high-end model. It's occasionally taking well over a millisecond to return data, which is surprisingly poor QoS for such a light workload. The Kingston DC450R fares similarly to the DC500s, with tail latencies that are only slightly higher than the average latency.

The Kingston DC450R and Micron 5100 MAX both show roughly constant IOPS for random reads up to 4kB in size, in line with the other Kingston drives rather than showing the peak at 4kB that the Samsung 883 gives. Beyond 128kB, the DC450R shows a more severe faltering in performance than most of the other SATA drives, while the Micron 5100 MAX simply shows performance that grows relatively slowly with transfer size.

QD1 Random Write Performance

4kB Random Write QD1

There's not much variation between the SATA drives for QD1 random write performance. All of these drives are capable of accepting a write command into their cache fairly quickly, and fully disguise the latency of actually writing to the flash.

4kB Random Write QD1 (Power Efficiency)
Power Efficiency in kIOPS/W Average Power in W

The Kingston DC450R's power draw during the QD1 random write test is quite high, second only to the DR500R—these drives are clearly busier in the background than the DC500M that has more spare area to work with. Those two drives end up with the worst efficiency scores by far for this test. The Micron 5100 MAX averages only 2W compared to over 5.5W, so it has a great efficiency score here.

4kB Random Write QD1 QoS

The Micron 5100 MAX and Kingston DC450R both have fairly typical latency scores for this test. Neither suffers from the stand-out tail latency problem the entry-level Samsung 860 DCT has.

The Kingston DC450R didn't wasn't narrowly tuned for 4kB operations when it came to random reads, but for random writes it's definitely optimized for that one specific block size, and to a greater degree than the DC500R. The Micron drive also gives peak random write IOPS for 4kB block sizes, but handles everything from 512 bytes up to 8kB fairly well.

QD1 Sequential Read Performance

128kB Sequential Read QD1

The Kingston DC450R continues the pattern set by the DC500 series of fairly low sequential read performance at QD1. The Micron 5100 MAX is only a bit slower than the Samsung drives on this test.

128kB Sequential Read QD1 (Power Efficiency)
Power Efficiency in MB/s/W Average Power in W

The Kingston DC450R and Micron 5100 MAX both use about the same amount of power on this test, about 20% more than the Samsung drives. That leaves the Kingston drive with barely more than half the performance per Watt of Samsung's SATA drives, while the Micron has about three-quarters.

The Micron 5100 MAX provides full sequential read speed with block sizes of 128kB or larger, similar to the Samsung drives. The Kingston DC450R inherits the same behavior as the DC500 series, with sequential read performance that is still catching up as the block size grows up to a full 1MB.

QD1 Sequential Write Performance

128kB Sequential Write QD1

128kB Sequential Write QD1 (Power Efficiency)
Power Efficiency in MB/s/W Average Power in W

These SATA drives all have about the same QD1 sequential write performance. The important differences show up when we look at the power meter. The Kingston DC450R is far and away the most power-hungry of the SATA drives, giving it a much worse efficiency score than even the DC500s. The Micron 5100 MAX offers almost twice the performance per Watt on this test, but the Samsung SATA drives still clearly lead the pack for efficiency.

The Micron 5100 MAX shows remarkably poor sequential write performance for block sizes smaller than 4kB, but there's not much real-world relevance to that weakness. At larger block sizes of 128kB and up, all of these SATA drives are able to get reasonably close to the limits of their host interface—though the Kingston DC450R is still a little bit slower than the others.

Introduction Peak Throughput and Steady State
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