Given that you have used all those other forms of improving SSD wear that we have discussed so far, but you still don’t find that this is enough, what do you do next? Well a few SSD controllers go one step further and manage some of the inner workings of the NAND flash chip itself.
If that sounds like a significant undertaking to you, then you clearly understand why so very few controllers take this approach. The information used to perform this function is not generally available – it takes a special relationship with the NAND flash supplier – and you can’t develop this relationship unless the NAND supplier Continue reading “How Controllers Maximize SSD Life – Internal NAND Management”
One way that SSD controllers maximize the life of an SSD is to use feedback on the life of flash blocks to determine how wear has impacted them. Although this used to be very uncommon, it is now being incorporated into a number of controllers.
Here’s what this is all about: Everybody knows that endurance specifications tell how much life there is in a block, right? For SLC it is typically 100,000 erase/write cycles, and for MLC it can be as high as 10,000 cycles (for older processes) but goes down to 5,000 or even 3,000 for newer processes. TLC endurance can be in the hundreds of cycles. Now the question is: “What happens after that?”
In most cases individual bits start to Continue reading “How Controllers Maximize SSD Life – Feedback on Block Wear”
Over provisioning is one of the most common ways that SSD designers can help assure that an SSD has a longer life than the flash’s endurance rating would support. If an SSD contains more flash than is presented at its interface, the controller can manage wear across a larger number of blocks while at the same time accelerating disk performance by moving slow operations like block erases out of the way of the SSD’s key functions.
Many people like to compare wear leveling to rotating a car’s tires. In this vein, think of over provisioning as having a bunch of spare Continue reading “How Controllers Maximize SSD Life – Over Provisioning”
Write amplification plays a critical role in maximizing an SSD’s usable life. The lower the write amplification, the longer the SSD will last. SSD architects pay special attention to this aspect of controller design.
Unlike the other factors described in this series this is not a technique that extends flash life beyond the 10,000 erase/write cycles that one would normally expect to result in a failure, but it is very important to SSD longevity.
Write Amplification is sufficiently complex that I won’t try to define it in this post, but Continue reading “How Controllers Maximize SSD Life – Reduced Write Amplification”
There are more advanced means than simple error correction to help remove bit errors in NAND flash and those will be the subject of this post. The general term for this approach is “DSP” although it seems to have very little to do with the kind of DSP algorithm used to perform filtering or build modem chips.
While ECC corrects errors without knowing how they got there, DSP helps to correct any of the more predictable errors that are caused by internal error mechanisms that are inherent to the design of the chip. A prime example of such an error would be adjacent cell disturb.
Here’s a brief explanation of Continue reading “How Controllers Maximize SSD Life – Other Error Management”
Error correction (ECC) can have a very big impact on the longevity of an SSD, although few understand how such a standard item can make much difference to an SSD’s life. The SSD Guy will try to explain it in relatively simple terms here.
All NAND flash requires ECC to correct random bit errors (“soft” errors.) This is because the inside of a NAND chip is very noisy and the signal levels of bits passed through a NAND string are very weak. One of the ways that NAND has been able to become the cheapest of all memories is by requiring error correction external to the chip.
This same error correction also helps to correct bit errors due to wear. Wear can cause bits to become stuck in one state or the other (a “hard” error), and it can increase the frequency of soft errors.
Although it is not widely Continue reading “How Controllers Maximize SSD Life – Improved ECC”
Since NAND flash is weakened by erase/write cycles then it would make sense to try to reduce those cycles to prolong the life of an SSD right? That’s what external data buffers are designed to do.
There are many ways to use RAM (either a RAM internal to the SSD controller chip or a discrete DRAM chip on the SSD’s printed circuit card) to stage data in a way that will reduce erase/write cycles.
One is to perform a function called “Write Coalescing.” This involves Continue reading “How Controllers Maximize SSD Life – External Data Buffering”
In this post we will explore how the right wear leveling algorithm can help a controller maximize the life of an SSD.
Wear leveling is a fact of life with NAND flash – blocks start to suffer bit failures after a certain number of erase/write cycles (usually specified from the thousands to the hundreds of thousands) and it is only natural that software will attempt to over-write some blocks more than others. In order to prevent this from causing failures, all of today’s SSD, USB flash drive, and flash card controllers incorporate some sort of wear leveling.
This is a simple re-mapping of the contents of the flash chips. A more graphical explanation is Continue reading “How Controllers Maximize SSD Life – Better Wear Leveling”
How do controllers maximize the life of an SSD? After all, MLC flash has a lifetime of only 10,000 erase/write cycles or fewer and that is a very small number compared to the write traffic an SSD is expected to see in a high-workload environment, especially in the enterprise. Still, MLC is becoming the norm in the enterprise.
How do they do that?
This is where SSD architects really earn their pay. There are eight basic techniques that The SSD Guy knows of to extend SSD life beyond Continue reading “How Controllers Maximize SSD Life”
SMART Storage Systems has introduced a new enterprise-class SSD that the company says: “increases the endurance of cMLC Flash to a level that makes SLC drives obsolete.” That’s a pretty hefty claim!
The new Optimus Ultra+ SSD is specified at 100K read IOPS and 60K write IOPS, through its 6Gb/s SAS interface. With capacities ranging from 100-800GB, this SSD supports up to 50 full drive writes per day over its 5-year lifespan, double that of the company’s Optimus Ultra which was introduced in February. That’s quite something for an MLC-based SSD.
SMART has tapped into its Guardian technology to reap SLC benefits from MLC flash through both enhanced external and internal algorithms. Like all other SSD makers and SSD controller makers SMART has focused a lot of attention on error correction, DSP, and other means of correcting errors externally to the flash. The company has also partnered with Continue reading “SMART Optimus Ultra+ SSD: SLC Performance Using MLC Flash”