Seagate this week reiterated that the company is on track to launch two crucially important technologies later this calendar year. Firstly, the company plans to start ramping up its 16 TB hard drives featuring heat-assisted magnetic recording (HAMR) technology in 1H 2019. Secondly, the manufacturer intends to launch its first 14 TB HDDs featuring two actuators, up to 500 MB/s sequential read speed, and up to 160 IOPS later this year. Also, the company has stated that it is already testing its next iteration of HAMR that will enable hard drives with capacities up to 24 TB.

Table of Contents

Seagate's Datacenter and Exascale HDD Plans
AnandTech.com H1 2019 H2 2019* 2020
Capacity 16 TB 14 TB ~20+ TB 16 ~ 20 TB
Recording Technology HAMR PMR HAMR
Performance Over 250 MB/s
~80 IOPS
5 IOPS/TB
~480 MB/s
~160 IOPS
~11 IOPS/TB
?
~80 IOPS
4 IOPS/TB
?
Actuators Single Actuator Dual Actuator Single Actuator Dual Actuator*
Notes: *Not confirmed formally

 

Need for Storage

The market of hard drives is shrinking in terms of unit sales, but continues to thrive in terms of total capacity shipped as well as revenue. There may be some exceptions (e.g., Q4 CY2018), but the general trend is here. Unit shipments drop because modern laptops cannot accommodate a large 2.5-inch mechanical hard drive, whereas desktops can suffice with just one high-capacity Barracuda Pro-like storage device. What actually drives revenues in modern times are enterprise and exascale cloud datacenter-oriented HDDs that are used to enable services like Azure, Facebook, Gmail, iCloud, Netflix, Prime, and this is just to name a few.

Needless to say, that hard drives aimed at Apple, Facebook, Google, Netflix, Microsoft, and others are the first models to accommodate the latest technologies developed by Seagate (and other manufacturers), which is why it makes sense to pay a close attention to the company’s plans for datacenter HDDs in a bid to understand where the technology is going in general. Some of technologies found in such drives will eventually migrate to consumer HDDs.

HAMR: Nearly Here

HAMR (Heat Assisted Magnetic Recording) is something that Seagate has been working on for over a decade and this year it will finally hit mass production. Among other things, the HAMR technology posed two major challenges that Seagate had to solve. The first one is media itself that can handle a 450°C local heat (made using a laser with an 810 nm wavelength and a 20 mW power) without degrading over time. The second one is a writer with a near-field optical transducer (NFT) that heats the media and which also has to work without flaws for up to a decade or longer. Seagate has developed appropriate media and its writers can handle up to 4 PB per head data transfers, which is more than sufficient for modern enterprise/datacenter HDDs (that are rated for a 550 TB workload a year). In fact, the company says that not only its internally developed media and heads for HAMR HDDs meet datacenter requirements, but so do components designed externally as well.

Seagate officially started to ship its fully functional single-actuator Exos 16 TB HAMR-enabled helium-filled HDDs to select global hyperscale and OEM partners in early December for demonstration purposes. These drives are drop in compatible with existing server infrastructure and power consumption per unit does not exceed 12 Watts. In fact, it is in line with power consumption with other helium-filled HDDs since NFTs do not consume a lot of power at all.

Earlier this week Dave Mosley, CEO of Seagate, said that the company’s HAMR drives will be launched commercially in the first half of this year and will ramp after its partners validate them.

24 TB HDDs En Route

While Seagate is gearing up to launch its Exos 16 TB HDDs officially in the coming weeks or months, the company promises that its HAMR technology will enable it to release hard drives featuring ~18 TB ~ 20 TB or even higher capacities sometime next year. Furthermore, Seagate has already tested tech that will be used for 24 TB HDDs.

Late last year the company said that it had successfully demonstrated platters featuring a 2.381 Tb/in2 (Terabits per square inch) areal density in spinstand testing, which basically means a drive without an enclosure on a test bed. This areal density enables Seagate to make 3.5-inch platters with a 3 TB capacity. Eight of such disks can be used to build a 24 TB HDD. When it comes to longer-term future, Seagate once said that it had developed media with up to 10 Tb/in2 areal density in the lab.

Dual Actuator HDDs Ready for Prime Time

Another of Seagate’s technology that made headlines last year was the company’s Multi-Actuator Technology (MAT) designed to improve sequential and random read and random write performance of hard drives. On a high level, MAT improves MB/s and IOPS performance of HDDs, but a deeper look quickly reveals that this tech is crucial for the upcoming generations of datacenter hard drives in general and not only because of pure performance numbers.

It is well known that operators of exascale datacenters keep power consumption of servers and individual components in check because they can supply a relatively finite amount of power and remove a limited amount of thermal energy. It is also known that the majority of cloud datacenters use SSDs for frequently accessed data and nearline (near online) HDDs to store data that is accessed a bit less regularly. SSDs enable operators of the said datacenters to provide certain services instantly, but even when they need to access data from hard drives, there is a strict standard when it comes to time they need to access their data within their datacenter.

In general, today’s 3.5-inch HDDs offer random performance of 6 – 10 IOPS per terabyte, which is sufficient for contemporary datacenters and is enough to ensure their quality-of-service requirements. Meanwhile, as hard drives gain capacity, their random performance per terabyte drops and once it drops below 5 IOPS per TB (which is believed to be the lowest target for many modern datacenters), such HDDs will no longer meet service level agreement and therefore QoS requirements. Consequently, operators who do not meet their IOPS per TB requirements (whether these are 4, 5, or 7 IOPS per TB) need to either reduce the amount of capacity they use per drive (i.e., buy smaller drives, or pay for capacity they cannot use), or demand drives that offer a higher I/O performance. This was explained Jason Feist, Seagate’s Director of Technology Strategy and Product Planning who is responsible for the company’s datacenter product roadmap.

At present, Seagate can tune hard drives to deliver I/O that its customers require by implementing command queuing and latency-bounded I/O (LBIO) in firmware (i.e., lower performance), but at some point, these methods will cease to work efficiently. In particular Seagate says that at ~16 TB and beyond more and more customers (but not all of them) will need HDDs that could physically feature a higher I/O performance.

To improve I/O performance of next-generation hard drives, both Seagate and Western Digital plan to install two (or more) sets of actuators into a single HDD. The actuators are to be outfitted with their own arms/heads as well as magnets to position them, but will use one pivot. Therefore, the actuators will work autonomously, basically producing parallelism within a single HDD. As hard drives gain ability to read or write with more than one head at any given time, their random read/write performance will scale with the number of actuators. Sequential read/write performance of HDDs will also increase all the way to 480 MB/s (in case of the first-gen MAT-enabled HDDs), but as it will depend on numerous factors, it is hard to make predictions about throughput of next-gen hard drives.

The extra components needed for two independent actuator assemblies (and a considerably more sophisticated HDD controller) will make such HDDs a bit costlier to manufacture when compared to today’s models. This is a reason why going forward Seagate will have at least two lineups of HDDs for hyperscale workloads: one guaranteeing optimal IOPS per TB with multiple actuators and another guaranteeing minimum IOPS per TB and aimed at customers who can manage required performance levels.

First Multi-Actuator HDD: 14 TB, ~480 MB/s

Seagate’s first-generation MAT-enabled HDDs, dubbed Mach2, use two actuators operating on a single pivot point (along with 8 platters and 16 heads). These drives are set to feature a 14 TB capacity, 480 ~ 500 MB/s sequential read/write performance, as well as up to 160 IOPS. What is not completely clear is how much power will these HDDs consume, as the only thing that Seagate says is that they will consume significantly less than two HDDs. The key thing here is that the drives will still be drop-in compatible with 3.5-inch bays, which is the most important thing for operators of exascale datacenters.

Seagate says that it had supplied prototypes of its Mach2 HDDs to its partners and such drives had been used for “live production traffic” for months now. Their volume ramp will begin later this calendar year, yet Seagate does not elaborate.

Final Thoughts

With plans to launch two crucially important technologies in 2019, this year will be fundamentally important for Seagate. The company is ahead of its rivals with its HAMR and multi-actuator technologies, but now it needs to execute and deliver appropriate HDDs to interested parties. Next year will also be important for Seagate as it will have to bring together its HAMR and multi-actuator technologies and offer rather unique drives to its customers.

As noted above, many technologies originally developed for enterprise and exascale datacenter hard drives usually migrate to HDDs aimed at high-end desktops, workstations, and NAS. Obviously, both HAMR and MAT make a great sense for all of the aforementioned applications, but it remains to be seen which of the technologies will be used for “civil” PCs and storage devices first.

Related Reading

Source: Seagate

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  • DanNeely - Friday, February 8, 2019 - link

    Probably about the same time as 32TB desktop drives. Laptop platters are about half the area of desktop ones; and normal 2.5" drives only have room for 2 platters. That means 2TB 2.5" platters or 4TB 3.5" ones. The latter would make a 32TB 8 platter helium filled drive. So probably not anytime soon.

    If an He filled 2.5" 9.5mm drive could squeeze a 3rd platter in (not sure if this is feasible or not), they'd only need 1.3TB platters; which'd correspond to a 2.67tb/22 tb overall drive.

    OTOH the 24TB capacity point for a desktop drive corresponds to a 3tb 2.5" laptop drive. Assuming the price isn't insane we might see that in the near future.
  • rahvin - Friday, February 8, 2019 - link

    I don't think you can get more than 2 platters in 9mm. They can't thin the platters any more or they'll blow to pieces when you spin them up. You've also got a minimum spacing to all the heads to operate. Unless they can shrink the motor dramatically you can't get that third platter in without going to 12-14mm.
  • madmilk - Monday, February 11, 2019 - link

    There have been a few 3-platter 9.5mm drives, like the 1.5TB HGST 5K1500 and the 2TB Samsung M9T. 9.5mm drives seem to be getting less common though. Seagate at least seems to have replaced their whole Barracuda 2.5" lineup with 7mm and 15mm drives.
  • Sivar - Friday, February 8, 2019 - link

    "First Multi-Actuator HDD: 14 TB, ~480 MB/s"
    These are not the first multi-actuator hard drives, not even the first mainstream multi-actuator Seagate mainstream drives. Those were the Seagate Barracuda 2HP series (ST-12450W).

    Before that, Imprimis produced them for supercomputers starting in 1987.

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