Intel Ghost Canyon NUC9i9QNX Review: NUC 9 Extreme Realizes the SFF Dreamby Ganesh T S on April 16, 2020 8:05 AM EST
Small form-factor PCs and gaming systems have emerged as bright spots in the mature PC market over the last decade or so. Intel's NUC form-factor introduction was the turning point in the small form-factor (SFF) market. Over several generation of products, the NUC family has expanded to address different market segments. But even with those developments, DIY enthusiasts have traditionally given the NUCs a cold shoulder by pointing to the lack of flexibility and limitations such as the inability to use a discrete GPU. So to to address the requirements of the performance enthusiasts, Intel introduced the Skull Canyon NUC in 2016 and followed it up with 2018's Hades Canyon NUC.
Following that same strategy of developing enthusiast-tier NUCs, at CES 2020, Intel officially announced the Ghost Canyon NUC series of products (NUC 9 Extreme Kits), which are based on the Intel NUC 9 Extreme Compute Elements. Among other notable changes, the series adds the ability for end-users to add a standard PCIe video card to the system system. The products have been made available to OEMs and ecosystem-enablers since late 2019, and they are finally reaching retail availability this month.
With their latest NUC finally available at retail, Intel has sent us an engineering sample of the top-end Ghost Canyon NUC, the NUC9i9QNX. Intel has equipped the NUC with matching build components to create a premium SFF gaming / workstation system. Read on for a review of the NUC9i9QNX and an analysis of the Intel Compute Element and its associated ecosystem.
Introduction and Product Impressions
The Ghost Canyon NUC9i9QNX is Intel's current top-end NUC with a NUC 9 Extreme Compute Element (NUC9i9QNB) housed in a 238mm x 216mm x 96mm chassis. NUCs have traditionally been associated with the ultra-compact form factor (100mm x 100mm boards in a 0.63-litre or 0.42-litre volume chassis). The Skull Canyon and Hades Canyon products with their higher TDP processors had to be accommodated in 0.69L and 1.2L chassis, but the Ghost Canyon NUC kits with their support for PCIe video cards takes it to a whole new level with a 4.94L chassis.
Though make no mistake: while biggest than the smallest NUCs, this is still well within the realm of SFF PCs. In fact, the smallest SFF PC with support for PCIe video cards that we happen to be aware of is the ZOTAC ZBOX MAGNUS series, with a 5.8L chassis. The Ghost Canyon NUC chassis includes a built-in power supply while the ZOTAC mini-PC uses an external adapter, which if counted would add further to its volume. As a result, the Ghost Canyon NUCs take the title of the smallest ever PC lineup to support user-replaceable discrete GPUs by a comfortable margin.
Intel's NUC lineup has traditionally included board and kit variants, allowing its partners to provide value additions (such as a passive chassis or additional I/O ports in the end system). Kits (other than the ones that come with a pre-installed OS) require the end-user to add storage, DRAM, and install an OS to complete the system. Some kits support a 2.5" drive in their chassis configuration, while others are M.2-only from a storage perspective. The Ghost Canyon series of products also follows a similar philosophy, while greatly increasing the flexibility for the end-user. Towards that, a Ghost Canyon is system comprised of multiple parts, which can be picked and chosen by OEMs / end-users to create a system for specific use-cases:
- The Compute Element
- Baseboard (or backplane)
- DRAM (up to 2x DDR4-2666 SODIMMs)
- Non-volatile storage (HDD or SSD)
- Discrete GPU (optional)
An off-the-shelf Ghost Canyon NUC9i9QNX kit leaves only the DRAM, non-volatile storage, and discrete GPU to the choice of the end-user. Prior to the platform analysis and overview of our review configuration, let's take a look at the pre-decided components in the above list.
The Compute Element
The Compute Element is the board component used in the previous NUC generations. The NUC9i9QNX we are reviewing today comes with the NUC9i9QNB (NUC 9 Extreme Compute Element). The Compute Element comes with a soldered processor - the Core i9-9980HK. This belongs to the Coffee Lake Refresh-H family, and has a 8C/16T configuration with a 45W TDP. It can turbo up to 5 GHz. And, as we've previously covered in our look at Intel's Compute Element prototype, the NUC 9 Compute Element re-imagines the traditional motherboard in a discrete PCIe x16 card form-factor.
The Intel NUC 9 Extreme Compute Element (NUC9i9QNB)
The Compute Element comes with a cooling shroud containing a single fan and two M.2 heat-sinks with thermal pads pre-attached. These align with the two M.2 slots (1x M.2 2280, and 1x M.2 22110) in the Compute Element to the left of the processor. On the right, we have the two SODIMM slots that can operate at speeds of up to DDR-2666 for DIMMs up to 16GB, while 32GB DIMMs are rated for up to DDR-2400. The gallery below provides additional photographs of the Compute Element and the cooling shroud.
The NUC9i9QNB comes with two Thunderbolt 3 ports, two gigabit Ethernet ports, a HDMI 2.0a display output, and four USB 3.1 Gen 2 Type-A ports in the rear. Headers include front panel audio and I/O connectors, a CEC connection, a SATA connector (FPC style with power), 2x USB 2.0 headers, and 2x USB 3.1 Gen 2 Type-C headers internally. The Compute Element has its own power connection to the PSU.
Intel's backplane/baseboard design for the NUC 9 Compute Elements is comprised of two PCIe x16 slots and a sole PCIe x4 slot, as well as a PCIe x4-backed M.2 22110 slot. One of the x16 slots is dedicated to the Compute Element. The other x16 slot operates in x16 mode as long as the PCIe x4 slot and the M.2 slot remain unoccupied. If either slot is occupied, then x16 slot operates in x8 mode. Essentially, the x16 attachment to the Compute Element can electrically operate as x16 or (x8 + x4 + x4). Further down in the platform analysis section, we will see that these 16 lanes come directly from the processor (and not the CM246 PCH). The baseboard has an explicit power connection to the PSU for supplying power to the PCIe slots.
Baseboard for the NUC 9 Extreme Compute Element in the NUC9i9QNX (Photo Credit: KoolShare.cn Forums)
The baseboard photograph reveals two ASMedia ASM1480 mux/de-mux chips to enable the splitting of the PCIe lanes. Note that these are true muxes and not PCIe switches, so physical lanes are being reallocated when additional cards are connected, and the GPU is hard limited to x8 bandwidth (~8GB/sec) in that case. And while unlikely, thanks to Intel's bifurcation rules, it should be noted that anything that tries to split the x16 slot (e.g. a M.2 riser with multiple M.2 slots) would disable the PCIe x4 slot as well (though the M.2 slot remains usable).
On that note, for the purposes of our review sample, Intel equipped the system with a 380GB Optane SSD 905p, connected to the M.2 slot in the baseboard, as well as an ASUS Dual GeForce RTX 2070 MINI 8GB GDDR6 card in the x16 slot. Due to the baseboard architecture, the card operates in x8 mode in the supplied review configuration.
The NUC9i9QNX chassis has been designed with the intent of retaining the ease of installation that the NUCs are famous for. The dimensions have also been kept as small as possible while providing the ability to install a dual-slot PCIe card (up to 202mm in length and 131mm in height) in the baseboard along with the Compute Element.
The top panel of the chassis slides off after the two screws in the rear are loosened. This panel also includes two 80mm x 15mm fans below the perforated top portion. The 12V supply for the fans are delivered through a snap-on connector, as shown in the above gallery. The perforated side panels can be removed by sliding up after the removal of the top panel. On the side opposite to the Compute Element slot, the top bar on the chassis can be taken out (to aid in the installation of a PCIe card) by removing two screws.
The I/O ports in the rear panel are directly off the Compute Element. However, the front I/O ports require the routing of on-board headers in an appropriate manner. The front panel of the NUC9i9QNX has a power button and an audio jack (connected to the front panel audio header on the board), a SDXC slot, and two USB 3.1 Gen 2 Type-A ports. The last three are enabled by a daughterboard containing a Genesys Logic GL3227 USB 3.1 Gen 2 hub chip and a Genesys Logic GL3590 SDXC to USB bridge chip. The hub chip in the daughterboard is perhaps unavoidable due to the inability of the headers to be individually routed to distinct ports in the front panel (given the volume constraints of the small chassis).
Overall, despite the plastic framing in the front panel, the metal-based construction in other areas gives the chassis a premium look and sturdy feel. Space management in the absence of a discrete GPU or PCIe cards is simple, but things get really cramped when the chassis is stuffed to the gills (as in the case of our review configuration).
An attractive aspect of the NUC9i9QNX is the built-in 500W 80 PLUS Platinum power supply. Most SFF PCs (including similar powerful ones like the ZOTAC ZBOX MAGNUS series) use bulky external adapters, so the ability to use just a simple power cord with the system is a welcome one from the perspective of a compact installation.
The 500W FSP PSU in the NUC9i9QNX
Intel has used the FSP500-30AS, a new PSU from FSP in a Flex-ATX form-factor. The cables enable up to 150W to be supplied to the add-in card directly. Along with the 75W budget from the PCIe connection, the NUC9i9QNX supports cards that consume up to 225W.
Our review sample of the NUC9i9QNX came with the following components pre-installed:
- 2x Kingston HyperX KHX3200C20S4/8G for 16GB of DRAM
- 1x Intel Optane SSD 905p 380GB (SSDPEL1D380GA) M.2 22110 SSD
- 1x Kingston KC2000 1TB (SKC2000M81000G) M.2 2280 SSD
- ASUS Dual GeForce RTX 2070 MINI 8GB GDDR6
A configuration with a high-end PCIe 3.0 x4 NVMe SSD relegated to being a dedicated secondary drive leaves no doubt that the system represents Intel's vision of a maxed-out premium SFF PC build.
In the next section, we take a look at the full specifications of our review sample, followed by a detailed platform analysis along with some notes on our setup experience.
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timecop1818 - Thursday, April 16, 2020 - linkReally bad selection of pictures. Did you not actually have a unit with you when reviewing? There's no external shots, there's no pics of the board/GPU connected together, there's no pics of rear backplane with ports/whatever, basically no useful info. I clicked through the gallery and I have no idea how big this thing is, or how the GPU fits into the picture, or anything else. Even "setup notes" page shows nothing useful.
DanNeely - Thursday, April 16, 2020 - linkThe chassis gallery on the 1st page shows the fully assembled system with the rear IO ports visible and gives a decent visual idea of how big the system is.
timecop1818 - Thursday, April 16, 2020 - linkOh hey, I see the stuff now. There's separate galleries throughout the article, for some reason I thought there was only one per page, and the 1st page only showed disassembled cpu module so I thought that was it. Thanks for pointing it out.
FireSnake - Thursday, April 16, 2020 - linkBased on this:
they are not getting any money from me!
For a loooong looong time (those includd too).
bug77 - Thursday, April 16, 2020 - linkIt's a good thing you don't get hung up on details like proof and stuff. Guilty until proven innocent, eh? (And yes, I know history doesn't work in their favor.)
DigitalFreak - Thursday, April 16, 2020 - linkIan doesn't seem like the person to throw around baseless accusations.
ganeshts - Thursday, April 16, 2020 - linkThe tweet has been misinterpreted and now taken a completely unintended shape of its own. Ian plans to clarify the usage of the word 'incentive' in the context in an upcoming video / post.
FWIW, if anyone believe AMD doesn't offer incentives to its partners (of a type similar to what Intel does, and what is completely legal), then the person has no idea of how the technology industry / silicon vendors operate.
If anyone thinks the reason for lack of high-performance AMD-based (read, Renoir) 'NUC's is Intel, then I have a bridge to sell. No one is preventing AMD from creating a reference design for a Renoir-based 4x4 board or innovate with Compute Element-like products. OEMs can take the plunge only if the silicon vendors offer them a proof of concept. If a Renoir NUC reference design exists, but OEMs still don't pick it up to offer them in the market, that would be worthy of deeper investigation (that could still throw up legitimate reasons).
Namisecond - Friday, April 17, 2020 - linkEven when reference designs exist, availability of parts can come into play, or even OEM disinterest.
quadrivial - Friday, April 17, 2020 - linkAMD has reference designs and an entire set of embedded Zen 1 chips made explicitly for that purpose. Udoo Bolt was kickstarted by a fairly small company. If they could do it, why not bigger companies?
arashi - Saturday, April 18, 2020 - linkYou must understand that Intel PR and legal has been in touch.