With the release of newer AMD Ryzen motherboards, PCIe Gen4 SSDs followed suit and gradually started to hit the market. It was only a matter of time before Samsung made its first appearance in this category, which they’ve done today. The Samsung 980 PRO PCIe 4.0 NVMe SSD, is a client SSD that features the company’s V-NAND 3bit MLC technology and a newly-developed, in-house Elpis SSD controller. The company’s first PCIe 4.0 drive is designed for high-end PCs, workstations, and game consoles, and is available in capacities ranging from 250GB to 2TB (though the largest model does not have a release date as of the publication of this review).
With the release of newer AMD Ryzen motherboards, PCIe Gen4 SSDs followed suit and gradually started to hit the market. It was only a matter of time before Samsung made its first appearance in this category, which they’ve done today. The Samsung 980 PRO PCIe 4.0 NVMe SSD, is a client SSD that features the company’s V-NAND 3bit MLC technology and a newly-developed, in-house Elpis SSD controller. The company’s first PCIe 4.0 drive is designed for high-end PCs, workstations, and game consoles, and is available in capacities ranging from 250GB to 2TB (though the largest model does not have a release date as of the publication of this review).
Like the few others we’ve reviewed, the new PCIe Gen4 x4 NVMe 1.3 interface is quoted to deliver some very impressive numbers. Samsung indicates that the 980 Pro can reach up to an unprecedented 7GB/s in sequential read and 5GB/s in sequential write. Random reads and writes have the potential to hit the million IOPS mark in throughput (at Q32T16).
Though this quoted performance from Samsung is very exciting, users will need a compatible system to reach these numbers. Moreover, both the Xbox Series X and PS5 will feature PCIe 4.0 compatibility for those who want the most out of their next-gen console. Hardcore gamers will certainly be looking for more options in the near future (specifically the PS5, which indicates support for 3rd-party NVMe PC drives). That said, consoles use custom hardware and components, so it’s really hard to anticipate how non-propriety drives will perform in these next-gen consoles.
There are a few important and unique features of the Samsung 980 Pro that are worth mentioning. First is that the new drive uses the company’s sixth-generation V-NAND, which Samsung states as having a 40% increase in cells over the previous 9x-layer single-stack structure. This is due to its electrically conductive mold stack of more than 100 layers. Its vertically piercing cylindrical holes (from top to bottom) creates uniform 3D charge trap flash (CTF) cells. In addition, the 6th gen NAND uses a “speed-optimized” circuit design, which translates to noticeably faster data transfer speeds compared to the 5th generation (i.e., less than 45μs for reads and less than 450μs for writes). This allows for 10% or more improvement in performance and a 15% reduction in power consumption.
Backed by a 5-year warranty, the Samsung SSD 980 Pro is currently available in 1TB ($229.99), 500GB ($149.99), and 250GB ($89.99) capacities. We will be looking at the 1TB model in this review.
Usage Application | Client PCs | |||||
Interface | PCIe Gen 4.0 x4, NVMe 1.3c | |||||
Hardware Information | Capacity | 250GB | 500GB | 1TB | 2TB | |
Controller | Samsung Elpis Controller | |||||
NAND Flash Memory | Samsung V-NAND 3bit MLC | |||||
DRAM Cache Memory | 512MB LPDDR4 | 1GB LPDDR4 | 2GB LPDDR4 | |||
Dimension | Max 80.15 x Max 22.15 x Max 2.38 (mm) | |||||
Form Factor | M.2 (2280) | |||||
Performance (Up to.) | Sequential Read | 6,400 MB/s | 6,900 MB/s | 7,000 MB/s | TBD | |
Sequential Write | 2,700 MB/s | 5,000 MB/s | 5,000 MB/s | TBD | ||
QD 1 Thread 1 | Ran. Read | 22K IOPS | 22K IOPS | 22K IOPS | TBD | |
Ran. Write | 60K IOPS | 60K IOPS | 60K IOPS | TBD | ||
QD 32 Thread 16 | Ran. Read | 500K IOPS | 800K IOPS | 1,000K IOPS | TBD | |
Ran. Write | 600K IOPS | 1,000K IOPS | 1,000K IOPS | TBD | ||
Power Consumption (Up to) | Idle (ASPT on) | 35mW | TBD | |||
Active (Avg.) | Read | 5.0 W | 5.9 W | 6.2 W | TBD | |
Write | 3.9 W | 5.4 W | 5.7 W | TBD | ||
L1.2 mode | 5 mW | TBD | ||||
Reliability | Temp. | Operating | 0°C to 70°C (Measured by S.M.A.R.T. Temperature Proper airflow recommended) | |||
Non-Operating | -40°C to 85°C | |||||
Humidity | 5% to 95% non-condensing | |||||
Shock | Non-Operating | 1,500G(Gravity), duration: 0.5ms, 3 axis | ||||
Vibration | Non-Operating | 20~2,000Hz, 20G | ||||
MTBF | 1.5 million hours | |||||
Warranty | TBW | 150TB | 300TB | 600TB | 1,200TB | |
Testbed
As we migrate into testing newer NVME Gen4 SSDs, it required a platform shift in our lab to support the newer interface. Lenovo has been out in the front of the pack with PCIe Gen4 support, including up to the front-mount U.2 bays, while others still only offer edge-card support. In our Gen4 reviews, we leverage the Lenovo ThinkSystem SR635 server, equipped with an AMD 7742 CPU and 512GB of 3200Mhz DDR4 memory. NVMe is tested natively through an M.2 to PCIe adapter card in the edge-card slot, while U.2 drives are loaded in the front. The methodology used better reflects end-user workflow with the consistency, scalability, and flexibility testing within a virtualized server offers. A large focus is put on drive latency across the entire load range of the drive, not just at the smallest QD1 (Queue-Depth 1) levels. We do this because many of the common consumer benchmarks don’t adequately capture end-user workload profiles.
SQL Server Performance
Each SQL Server VM is configured with two vDisks: 100GB volume for boot and a 500GB volume for the database and log files. From a system resource perspective, we configured each VM with 16 vCPUs, 64GB of DRAM, and leveraged the LSI Logic SAS SCSI controller. While our Sysbench workloads tested previously saturated the platform in both storage I/O and capacity, the SQL test is looking for latency performance.
This test uses SQL Server 2014 running on Windows Server 2012 R2 guest VMs and is stressed by Quest’s Benchmark Factory for Databases. StorageReview’s Microsoft SQL Server OLTP testing protocol employs the current draft of the Transaction Processing Performance Council’s Benchmark C (TPC-C), an online transaction-processing benchmark that simulates the activities found in complex application environments. The TPC-C benchmark comes closer than synthetic performance benchmarks to gauging the performance strengths and bottlenecks of storage infrastructure in database environments. Each instance of our SQL Server VM for this review uses a 333GB (1,500 scale) SQL Server database and measures the transactional performance and latency under a load of 15,000 virtual users.
SQL Server Testing Configuration (per VM)
For our SQL Server transactional benchmark, the Samsung 980 Pro posted 3,160.3 TPS.
Moving on to latency, the Samsung 980 Pro drive posted just 3.0ms, which placed it at the top of the leader board alongside its predecessor, the 970 Pro.
When it comes to benchmarking storage devices, application testing is best, and synthetic testing comes in second place. While not a perfect representation of actual workloads, synthetic tests do help to baseline storage devices with a repeatability factor that makes it easy to do apples-to-apples comparison between competing solutions. These workloads offer a range of different testing profiles ranging from “four corners” tests, common database transfer size tests, to trace captures from different VDI environments. All of these tests leverage the common vdBench workload generator, with a scripting engine to automate and capture results over a large compute testing cluster. This allows us to repeat the same workloads across a wide range of storage devices, including flash arrays and individual storage devices. Our testing process for these benchmarks fills the entire drive surface with data, then partitions a drive section equal to 5% of the drive capacity to simulate how the drive might respond to application workloads. This is different from full entropy tests which use 100% of the drive and take them into a steady state. As a result, these figures will reflect higher-sustained write speeds. Additionally, as VDBench operates with synchronous I/O in Linux versus asynchronous I/O, some of the performance data will differ between the data we collect and what is published in spec sheets. The important part to consumer though is that test data is comparable from the same test conditions, be it VDBench versus VDBench, IOMeter vs IOMeter, or FIO vs FIO.
Profiles:
Comparable for this review:
In 4K random read, the Samsung 980 Pro was the best performer by a wide margin, posting a peak performance of 545,687 IOPS at a latency of 232.5µs before a slight spike at the end.
In 4K write activity, the Samsung 980 Pro was ahead by a mile with a peak performance of 383,099 IOPS and a latency of 329.1µs. The next best drive only reached 144K IOPS and almost 900µs in latency.
With 64K read sequential performance, the Samsung 980 Pro went on to peak at 71,454 IOPS (or 4.47GB/s) with 441.5µs for top spot again among the tested drives.
In 64K sequential writes, we again saw the new Samsung drive with significantly better results compared to the other PCIe Gen4 drives. Here, peak performance hit around the 27K IOPS mark (1.7GB/s) at 583.1µs (before falling off slightly at the end), which was essentially double the speed of the next best drive.
Looking at our VDI Initial Login, the 980 Pro showed a big spike in performance around the 65K IOPS mark, though it evened out at the end with a peak of 82,015 IOPS and a latency of 361.8µs, easily take the top spot.
In our last test, VDI Monday Login, the 980 Pro showed a peak IOPS at 23,814 IOPS and 696.4µs in latency, which moved it back some on the leader board for the first time.
The Samsung SSD 980 Pro is the latest consumer-grade SSD to hit the PCIe Gen 4×4 market, featuring the company’s V-NAND 3bit MLC technology, an all-new Elpis controller, backward-compatibility with PCIe 3.0, and NVMe 1.3 support. The 980 Pro is targeted at gamers and professionals with high-end machines as well as prosumers looking to leverage the latest and greatest in SSD technology.
The new Samsung SSD uses the company’s sixth-generation V-NAND, which Samsung offers a 40% increase in cells over the previous 9x-layer single-stack structure. The SSD also leverages newly enhanced Intelligent TurboWrite 2.0 technology, which greatly increases the drive buffer size. As far as reliability goes, it features endurance up to 1,200TB written (for the 2TB capacity) and an MTBF of 1.5 million hours for all models.
For performance, highlights included: 545,687 IOPS in 4K read, 383,099 IOPS in 4K write, 4.47GB/s in 64K read, and 1.7GB/s in 64K write. In our VDI Clone, we saw 132,962 IOPS in boot, 82,015 IOPS in initial login, and 23,814 IOPS in Monday login.
The Samsung SSD 980 Pro is the best-performing consumer drive we’ve tested to date, it more than doubled the numbers of its competitors in some areas. The largest gain over the competition we’ve tested so far in the Gen4 category is the Pro’s write performance, in both 64K sequential and 4K random. It will be interesting to see how the upcoming PlayStation 5 and the Xbox Series X/S will handle non-propriety PCIe 4.0 drives as well, as gamers are going to want to squash game loads with a drive like this. Of course in the PC world, new AMD systems are rolling out that will let creatives and other professionals take full advantage of the drive.
As far as pricing goes, the Samsung 980 Pro 1TB model goes for roughly $230 (and $150/$90 for the 500GB/250GB models), which is noticeably more than the $176 and $160 price tags for the 1TB Silicon Power US70 and Sabrent Rocket drive, respectively. Though the price gap is noticeable, you definitely get what you pay for in this instance. The 980 Pro is a must-buy premium drive and is certainly worth dishing out the extra ~$50, especially if for enthusiasts who have a system that supports the technology.
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