Samsung SSD 850 EVO mSATA Review
By Olin Coles
Full Disclosure: The product sample used in this article has been provided by Samsung.
Solid State Drive technology has been revolutionary in that it delivers a very noticeable performance boost that surpasses upgrades to other components. As a result, companies who offer SSDs typically spend small fortunes marketing them to the consumer public. Samsung goes a different route, and relies on proven performance to sale units. This was especially true for the Samsung SSD 840 EVO, which generated its own interest by producing impressive transfer speeds.
Powered by their own 32-layer 3D V-NAND technology, the Samsung SSD 850 EVO replaces the 840 EVO solid state drive and delivers up to twice the density and write speed of traditional 20nm planar NAND flash components. In this article, Benchmark Reviews tests the 250GB Samsung SSD 850 EVO mSATA drive against the fastest solid state drives available.
The Samsung SSD 850 EVO mSATA offers up to 95,000 IOPS random reads and a 540/520 MBps sequential read/write speed – both made possible by Samsung 3D V-NAND technology and 850 EVO’s MGX controllers. According to Samsung, with the 850 EVO solid state drive in RAPID mode (Real-time Accelerated Processing of I/O Data) users may achieve 200% better write performance speeds than possible with 840 EVO. Samsung Magician software allows users to further enhance performance by processing data on a system level using free PC memory (DRAM) as a storage cache. The 850 EVO series provides an industry-leading five-year product warranty, and top-level Total Bytes Written (TBW). Samsung’s 32-layer 3D V-NAND Flash has more than double the endurance compared with conventional 2D planar type NAND flash.
Back in 2013, Samsung was hard at work producing 24-layer 3D V-NAND products for their 840 PRO designed for power users. Samsung was credited with providing “unrivaled performance” in the SATA 6Gb/s interface with the 840 PRO, and now Samsung introduces the SSD 850 PRO with 3D V-NAND components. By changing to a 32-layer cylindrical cell structure that can be stacked vertically, the end result is a smaller footprint with higher density. These improvement have bled over to the new Samsung SSD 850 EVO series.
Samsung RAPID (Real-time Accelerated Processing of I/O Data) mode technology was introduced in the 840 EVO, and then 840 PRO last year. Samsung provides Magician software with SSD 850 EVO mSATA, which uses a DRAM usage algorithm optimized for maximum memory available for RAPID mode. This algorithm, introduced in Magician 4.4, will utilize up to 25% of system memory for RAPID mode. With Magician 4.5 users get dramatic improvements to Windows start up and application loading times.
Samsung SSD 850 EVO mSATA Specifications
- SEQUENTIAL READ SPEED: Up to 540 MB/sec Sequential Read
- SEQUENTIAL WRITE SPEED: Up to 520 MB/sec Sequential Write
- RANDOM READ SPEED: (4KB, QD32): Up to 95,000 IOPS Random Read
- RANDOM WRITE SPEED: (4KB, QD32): Up to 88,000 IOPS Random Write
- MEMORY SPEED: Samsung 32 layer 3D V-NAND with Samsung 512 MB Low Power DDR3 SDRAM
- CONTROLLER: Samsung MGX Controller
Solid State vs Hard Disk
Despite decades of design improvements, the hard disk drive (HDD) remains the slowest component of any personal computer system. Consider that modern desktop processors typically have a 1 ns response time (nanosecond = one billionth of one second), while system memory responds between 30-90 ns. Traditional hard disk technology utilizes spinning media, and even the fastest mechanical storage products still exhibit a 9 ms (9,000,000 ns) initial response time (millisecond = one thousandth of one second). In more relevant terms, the processor sends the command, but must wait for system memory to fetch data from the storage drive. This is why any computer system is only as fast as the slowest component in the data chain, which is usually the hard drive.
In a perfect world all of the components would operate at the same speed: system memory signals as quickly as the central processor, and the storage drive fetches data as fast as memory. With present-day technology this is an impossible task, so enthusiasts try to close the speed gaps between components as much as possible. Although system memory is up to 90x (9000%) slower than most processors, consider that the hard drive is an additional 1000x (100,000%) slower than memory. Essentially, these three components are as different in speed as crawling (HDD) is to walking (RAM) is to running (CPU).
Solid State Drive technology bridges the largest gap in these response times. The difference a SSD makes to operational response times and program speeds is dramatic, and takes the storage drive from a slow ‘crawling’ speed to a much faster ‘walking’ speed. Solid State Drive technology improves initial response times by more than 450x (45,000%) for applications and Operating System software, when compared to their mechanical HDD counterparts. The biggest mistake PC hardware enthusiasts make with regard to SSD technology is grading them based on bandwidth speed alone. File transfer speeds are important, but only so long as the operational I/O performance can sustain that bandwidth under load.
Bandwidth Speed vs Operational Performance
As we’ve explained in our SSD Benchmark Tests: SATA IDE vs AHCI Mode guide, Solid State Drive performance revolves around two dynamics: bandwidth speed (MB/s) and operational performance I/O per second (IOPS). These two metrics work together, but one may be more important than the other. Consider this analogy: bandwidth determines how much cargo a ship can transport in one voyage, and operational IOPS performance is how fast that ship moves. By understanding this and applying it to SSD storage, there is a clear importance set on each variable depending on the task at hand.
For casual users, especially those with laptop or desktop computers that have been upgraded to use an SSD, the naturally quick response time is enough to automatically improve the user experience. Bandwidth speed is important, but only to the extent that operational performance meets the minimum needs of the system. If an SSD has a very high bandwidth speed but a low operational performance, it will take longer to load applications and boot the computer into Windows than if the SSD offered a higher IOPS performance.