SSD (solid-state drive) is a nonvolatile storage media that stores persistent data on flash memory. It has two essential parts - a NAND flash memory and a flash controller optimized to deliver high read-write performance in sequential and random data fetching.
SSDs don’t have any moving parts, so no breaking, spinning up or down, as with ragged hard-disk drives with their rotating, magnetic media. SSD offers a distinct performance advantage. In the past, the pricing of SSDs had been way higher than HDDs. Still, with the improvements in manufacturing technology and chip capacity, prices are continuously dropping, which makes it worth every buck.
SSDs offer high transfer speeds, low latency even with random data access, more durability but not for hierarchical storage use, and expectedly no sound of moving parts. The stark performance boost can be seen in day-to-day usages, like swift system boot and shutdown speeds, application launch is more robust, and the system feels smoother without lagging.
For perceived and real performance gains, storage was the last bottleneck, which was eliminated with the advent of SSD and then the high-performance NVMe SSD storage solutions. The NAND flash SSDs radically improved input-output performance, and access times dropped from 6-12 milliseconds to less than 1 ms.
However, less than 1ms access times and breakneck I/O weren’t anywhere near the actual capacity of what flash drives could do. The issue was the old hardware and software built over five decades ago for HDDs instead of the blazing-fast SSDs.
Several types of SSDs compete in terms of performance and form factor, but the efficacy and robustness of flash memory have far been achieved.
SATA (Serial ATA) technology was introduced in 2003, replacing the older PATA (Parallel ATA) as the computer storage connection interface standard. It was ushered in as a universal connector entailing a power cord and a SATA data cable, breakneck throughput in read-write speeds.
Currently, SATA is the market incumbent, mainly used for connecting an SSD to the computer system. SATA uses the AHCI command protocol and supports the IDE, primarily built for older and sluggish spinning disk drives and not for sturdy flash-based storage.
Even today, when we consider storage space, hard drives have a clear advantage over SSDs as they cost less per gigabyte and hold data for longer.
SATA interface was established at the time of spinning hard disk drives, and companies made no compatibility changes. SATA SSDs can use the existing infrastructure to replace aged hard drives with a new SATA disk drive. Still, the recent advancement in the shape of NVMe doesn’t fit the SATA ports and needs an M.2 port, which is rather difficult to find in prevalent consumer personal computers or laptops.
The theoretical speed of SATA 3.0 is 750MB/s, while due to physical overheads and encoding during the transfer itself, the effective transfer rate you’ll get with the newest SATA model is around 600MB/s, which is relatively fast for a limiting SATA interface.
The difference between SATA and PCIe SSDs is significant in terms of cost per gigabyte, but SATA drives will give you more storage for your money, and we know when it comes to storage, we think of space, not speed mostly. SATA SSD can give you a terabyte or two for the same price as 250GB or 500GB of high-performance NVMe drive, though the speed difference isn’t noticeable for regular users.
_____________________________
Related: SSD vs HDD for Video Editing
_____________________________
Non-Volatile Memory Express (NVMe) is the latest industry-standard software interface for PCIe SSDs. It is an optimized “scalable host controller interface designed to address the needs of Data Center, Enterprise, and Client systems that utilize PCI Express (PCIe) based Solid-State drives.” NVMe is a layer between the device driver and the PCIe device, standardizing the rules emphasizing scalability, low latency, and security.
The standard was developed to allow modern SSDs to operate at speeds flash memory is capable of, a sharp advantage with faster read-write. The NVMe SSD enables the flash memory to run directly through the PCI Express (PCIe) serial bus interface as it offers high bandwidth due to being directly attached to the CPU rather than functioning through the limiting SATA speeds. As SSDs superseded the slower HHDs as primary storage, a fast interface was required to achieve optimal use of the quicker speed capabilities.
In other words, it’s a technological depiction of the bus, the memory component (SSD) uses to communicate with the computer, and not exactly a new type of memory. A communications interface and driver that outlines a command set and feature set of PCIe-based SSD. It comes in two form factors, M.2 or PCIe expansion card, and a 2.5-inch U.2 connector, but with both form factors, it directly connects electrically to the motherboard via the PCIe rather than SATA connection.
The NVMe supports up to 64K commands per queue, but the protocol requires only thirteen commands to deliver high performance. The interface is designed for high scalability and NVM independence to enable next-generation technologies to deliver 4KB I/O in 10μs or less, about one-thousandth of the latency of a high-power 7200 RPM SATA drive.
NVMe is an improvement over the last interfaces like Serial ATA (SATA) and Serial Attached SCSI (SAS), which were developed for the shabby Hard Disk Drives (HDDs) and were being used till now even when replaced with SSDs because the memory technology was rapidly evolving. Still, the communication interface was not given proper attention. HDDs are still used as they provide large capacity and cheap storage, while flash memory has previously been only employed in mobile devices like tablets and smartphones, but now are more quickly coming to the primary computer market because of blazing-fast speeds and comparatively cheaper than before.
Though disk benchmarks are not an accurate indicator of memory performance, they offer a baseline for what’s probable with a particular drive and system. You can see a clear difference in performance when you use NVMe, with a read/write throughput far higher than the hard drives and slower SATA SSDs also lagging somewhat behind. As prices continue to drop for the latest NVMe SSDs, they are becoming commonplace for normal personal computer users.
NVMe permits drives to use PCI Express connection, which brings many advantages over the SATA SSD interface, feasible for many application and usage scenarios. NVMe doesn’t need the intervening HBA and can connect to more PCIe lanes. A SAS lane runs 12GB per second, which contracts to just about 1GB per second after overheads. A SATA lane also props half of that, while a PCIe lane runs at 1GB per second, and a standard NVMe SSD can be attached to four such lanes, supporting up to 4GB per second. So, a SATA SSD runs at 0.5GB per second and an NVMe SSD at around 3GB per second, which is six times higher throughput.
In the past 2 years, NVM Express, Inc. released the NVMe® 2.0c family of specifications. The new restructured specifications allow for faster and simpler development of NVME solutions. With that said, the solutions can support the diverse NVMe device environment.
New independent command sets are developed because of the specifications that come along with NVMe® 2.0c. This includes command sets like Zoned Namespaces (ZNS) and Key Value (KV).
The library of specifications of NVMe 2.0 consists of multiple documents, including the NVMe Base specification, Command Set specifications, Transport specifications, and the NVMe Management Interface specification. These changes facilitate the emerging NVMe ecosystem, including enterprise and client SSDs, removable cards, and computer accelerators.
Let’s dig deeper into the key features of NVMe 2.0 under Command Set Specifications:
NVMe has multiple information buses, which makes the data rate much faster than SATA. NVMe is unaffected by ATA interface constrictions as it sits right on the top of the PCI Express, directly connected to the CPU. That results in 4 times faster Input/Output Operations Per Second (IOPS), rivaling the fastest SAS option. The seek time for data is ten times faster.
NVMe can deliver a sustained read-write speed of 2000MB per second, way faster than the SATA SSD III, which is limited to 600MB per second. Here, the bottleneck is NAND technology, which is rapidly advancing, which means we’ll likely see higher speeds soon with NVMe.
NVMe enables drives to benefit from the same “pool” of lanes directly connecting to the CPU. That offers a scalable performance by going beyond the conventional four lanes found in most PCIe SSDs and utilizing them for added performance. PCIe sockets transfer more than 25 times more data than their SATA equivalent.
NVMe drives consume a paltry amount of power in standby mode. Some NVMe companies have adopted the L1.2 low-power-consumption standby mode, meaning the power consumption will be under 2 mW. A drastic 97 percent reduction from the 50mW used by an L1 state, widely used today. In addition to low power consumption in idle, other power states are available for enterprise-grade users to benefit from to save power.
The new NVMe 2.0 specification maintains backward compatibility from the previous NVMe generation. Regardless of the form factor, NVMe directly communicates with the system CPU and works with all major operating systems.
NVMe SSDs reinforce the industry-standard security solutions, such as the Opal SSC and Enterprise SSC by the Trusted Computing Group, by supporting the security container commands akin to the security container commands found in the SCSI.
The new update of NVMe is much more secure than its previous releases. NVMe 2.0 uses 32/64 bit CRC, meaning data and information protection is expanded to 32 to 64-bit, allowing more robust protection for large-scale data systems.
Another security feature, command group control, prevents unintended changes after the system is provisioned and protects the system from unintentional or malicious changes. This security feature uses a new lockdown command that puts a drive in a state where reads and writes are allowed, but various admin commands are locked out to avoid re-configuration of the other features.
Every good thing has its downsides, and the case is the same here with NVMe storage, which gives rise to performance issues and results in added cost and inconvenience. A few of the common mistakes and errors that can be avoided are:
Storage technology has advanced drastically over the past decade. Before the advent of SSDs, hard drives were the only storage type accessible and were pretty slow, but the systems at that time were also not that efficient and needed faster storage. When SSDs came, they entirely changed the scenario for storage media with their blazing speeds and convenient form factor.
Considering the potential exemplary performance of NAND-based SSDs, it was clear that the new bus and protocol would eventually be replacing the dilapidated HHDs or, for that matter, the SATA SSDs. Still, as the early SSDs were relatively slow and massive, using the existing SATA storage infrastructure was deemed more feasible.
In looking at NVMe vs SDD, NVMe is very fast and comes at a price. SDD is still a valid option if you don't need the higher speeds for your video teams. Learn more about SSD vs NVMe
ProMAX is launching the first NVMe NAS Shared Storage server design for video teams. We've got you covered for your NVMe and SSD storage. Connect with us today by clicking CONTACT US to determine which solution is best for your team.