At FMS 2019, Phison shared the specs for its next generation of client SSD controllers. The PS5018-E18 high-end controller will be made using a FinFET process technology and promises to boost sequential read and write performance of drives to 7 GB/s. The PS5019-E19T mainstream controller will be a quick follow-up to the E13T that is currently in production but has not yet shipped in retail products.

With its PS5016-E16 chip, Phison was the first to introduce client SSD controllers with a PCIe 4.0 x4 interface and is currently enjoying its unique position on the market. The PS5016-E16 is essentially an update of the PS5012-E12 — still featuring two Arm Cortex-R5 cores, eight NAND channels rated at 800 MT/s and made using TSMC’s 28 nm process technology, but now featuring a PCIe 4.0 x4 PHY and enhanced error correction capabilities. In the coming months, Phison's entry-level NVMe controller will get a similar successor: the new PS5019-E19T will be based on the PS5013-E13T (one Arm Cortex-R5 core, four NAND channels, 28nm technology), but featuring a new PCIe 4.0 x4 PHY and thus enabling cost-effective yet fast SSDs.

Phison’s next-generation PS5018-E18 high-end client SSD controller with a PCIe 4.0 x4 interface will be significantly different from the current E16. The chip gains a third Arm Cortex-R5 core, NVMe 1.4 compliance, improved hardware security algorithms, and will be made using TSMC’s 12 FFC fabrication process.

The most important improvement in the new controllers is support for faster NAND interface speeds of up to 1200 MT/s. This is necessary to get full performance out of 96L and newer 3D NAND. For the high-end E18 this allows the controller to actually deliver twice the throughput of any PCIe 3.0 x4 drive, where the E16 can only use a fraction of the extra bandwidth provided by the PCIe 4.0 upgrade. The faster NAND interface also allows the E19T to hit sequential speeds that are slightly faster than a PCIe 3.0 x4 link can handle, despite the E19T having only four NAND channels instead of the eight channels used by high-end NVMe controllers.

Peak power consumption for both the E19T and E18 will be higher than for their respective predecessors, but that's because they are so much faster; the newer controllers will actually be more efficient.

Phison's booth at FMS included live demos of the E13T, E19T and E16 controllers, but the E18 controller was not in attendance. The low-end E19T controller will be sampling by the end of the year and is likely to show up in retail drives by the end of Q1 2020. This means that the E13T is likely to be very short-lived in the retail market. The high-end E18 will be arriving a bit later, sampling in Q1 2020 and hitting the shelves in Q3, a year after the E16 it replaces.

Phison NVMe SSD Controller Comparsion
  E8/E8T E13T E19T E12 E16 E18
Market Segment Mainstream Consumer High-End Consumer
40 nm 28nm 28 nm 28 nm 12 nm FFC
CPU Cores 2x Cortex R5 1x Cortex R5 1x Cortex R5 2x Cortex R5 3x Cortex R5
Error Correction StrongECC 4th Gen LDPC 3rd Gen LDPC 4th Gen LDPC
E8T: No
Host Interface PCIe 3.0 x2 PCIe 3.0 x4 PCIe 4.0 x4 PCIe 3.0 x4 PCIe 4.0 x4
NVMe Version NVMe 1.2 NVMe 1.3 NVMe 1.4 NVMe 1.3 NVMe 1.4
NAND Channels, Interface Speed 4 ch,
533 MT/s
4 ch,
800 MT/s
4 ch,
1200 MT/s
8 ch,
667 MT/s
8 ch,
800 MT/s
8 ch,
1200 MT/s
Max Capacity 2 TB 2 TB 2 TB 16 TB 16 TB 16 TB
Sequential Read 1.6 GB/s 2.5 GB/s 3.75 GB/s 3.4 GB/s 5.0 GB/s 7.0 GB/s
Sequential Write 1.3 GB/s 2.1 GB/s 3.75 GB/s 3.2 GB/s 4.4 GB/s 7.0 GB/s
4KB Random Read IOPS E8: 240k
E8T: 120k
350k 440k 700k 750k 1M IOPS
4KB Random Write IOPS E8: 220k
E8T: 130k
450k 500k 600k 750k 1M IOPS
Controller Power 1.8 W 1.2 W 1.6 W 2.1 W 2.6 W 3.0 W
Sampling Q2 2017 Q2 2019 Q4 2019 Q2 2018 Q1 2019 Q1 2020
Retail SSD
Q4 2017 Q4 2019 Q1 2020 Q4 2018 Q3 2019 Q3 2020

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  • Dragonstongue - Friday, August 9, 2019 - link

    shame they not upped the speed of "good ol sata" to allow regular SSD to not be as bottlenecked.

    instead everyone and their gramma is chasing "got to get nvme even faster even if it costs much more and higher fail rate"

    sata like usb like 4 pin molex are "old but good" somewhere along the line AMD or someone else has to step in and go "wait a minute" and up sata from "sata 6+ speed" to actually beyond sata 6mb (to actually allow sata to go beyond the 550 odd mb speed "cap" specifically if they allowed bi-directional i.e 550x2 (read and write same time, like raid 0 + 1 without actually doing RAID
  • MajGenRelativity - Friday, August 9, 2019 - link

    They upped the speed of good old SATA. It's called SATA Express. It didn't do so well in the market.
  • PixyMisa - Friday, August 9, 2019 - link

    Except that's not SATA, it's PCIe over the worst designed connector since... I don't suppose anyone else here has experience with the memory card design on the IBM RS/6000 J30? You couldn't upgrade the memory without breaking the motherboard. They had to redesign the whole thing.
  • willis936 - Saturday, August 10, 2019 - link

    What is the issue with the SATAe cable? It seems to be competently designed to me.
  • willis936 - Friday, August 9, 2019 - link

    I mean SAS exists if you want higher performance with the niceties you list. SATA is used for the same reason it has always been used: it is cheap. Spec development of SATA has been very conservative for over a decade because the industry collectively agreed they were happy with SATA being what it is for all time. NVMe involves more expensive hardware for its higher performance. It is likely similar performance SATA would be Much more expensive than its NVMe dual. Nothing I have seen has implied NVMe over PCIe is in any way less stable than SATA. Its a better solution for SSD communications by every metric. If you want a $10 DRAMless SSD or to support a legacy system, get a SATA drive. Otherwise, get an NVMe.
  • PixyMisa - Friday, August 9, 2019 - link

    USB-C is the answer. Up to 20Gbps now, with power and signal over one cable.
  • Skeptical123 - Friday, August 9, 2019 - link

    For complicated reasons on how the spec functions using any USB type connection would not be desirable. Also one cable is not really an advantage especial when it's not locking. For anything more than a few watts it's often simpler to have a separate cable for power anyway. Also USB-C cables are fairly hard to produce relative to other cables and are designed for frequent plug cycles. Whereas devices like these are generally rated for maybe a few hundred plug cycles while only maybe seeing a few total in the devices life time. As such the device can get away with using more friction to lock it down so fans and hard drives spinning in the chassis or there nearby racks won't nock a cable loose everyone and a while
  • Santoval - Saturday, August 10, 2019 - link

    Soon 40 Gbps as well (the USB 4 variant, which is basically a toned down TB 3).
  • Lucky Stripes 99 - Sunday, August 11, 2019 - link

    You seem to say that "USB-C is the answer" in all of these threads. Except that the U.2/SFF-8639 is much faster since it is PCIe based. It also uses a connector designed for internal case use.

    USB 3.2 is 20 Gbps peak. USB 4.0 is 40 Gbps peak. A PCIe 4.0 4-lane U.2 port would be over 60 Gbps.
  • DanNeely - Friday, August 9, 2019 - link

    The SATA driver stack itself was a potential bottleneck for faster SSDs; changing it would require so many changes that it would effectively be a new product anyway so they went clean slate and created NVME.

    It's remotely possible that SATA will get a speed bump to 1.2g to match top end SAS; but if it happens it will be to support faster HDDs for NAS uses. The SATA SSD is an engineering dead end that mostly still exists for legacy support reasons.

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