Intel NUC11TNBi5 and Akasa Newton TN Fanless Case Review: Silencing the Tiger
by Ganesh T S on July 22, 2022 8:00 AM EST- Posted in
- Systems
- Intel
- Fanless
- HTPC
- NUC
- Passive Cooling
- UCFF
- Tiger Lake
- Akasa
Setup Notes and Platform Analysis
Our review sample of the Intel NUC11TNKi5 came with all necessary components pre-installed, and we carried them over to the Newton TN build - we only had to load up the OS to start our evaluation process. Prior to that, we took some time to look into the BIOS interface. The video below presents the entire gamut of available options for the Tiger Canyon NUC.
Intel's mini-PCs have the most comprehensive and configurable UEFI / BIOS among all the ones that we have evaluated over the last several years. The Tiger Canyon NUC is no exception. The home screen shows the BIOS version, processor details, and installed memory capacity and speed right away - this is of great help in checking whether the installed SODIMMs are operating at the desired speeds. Under the 'Advanced' section, we have options to enable various SATA and M.2 NVMe ports, and disable the disk activity LED if needed. Different USB ports and headers can be selectively enabled or disabled. iSCSI volumes can be mounted in the boot stage, and the network settings can be configured for network boot when needed. The HDMI / DisplayPort audio can be disabled, if necessary. Thunderbolt support is also controllable via the BIOS, as are a bunch of other features.
One of the most useful features in the lineup of Intel NUCs targeting the professional / business use-cases is the display emulation option under 'Advanced > Video'. This is useful for scenarios involving headless operation and digital signage installations, as it allows set up of a virtual display when no display is connected (virtual display emulation), or makes the OS think that a previously connected display is still connected to the display output (persistent display emulation).
The 'Cooling' section provides an overview of current temperatures and fan speeds, and allows fine grained control of the fan operation - including the sensors to which it responds, and the temperatures at which different actions need to trigger. In the 'Performance' section, users can control hyperthreading support, selectively enable or disable cores, and control various performance options like Turbo Boos and SpeedStep. The memory timings can also be finely controlled. Various password options including TCG Opal configuration can be activated from the 'Security' section. Virtualization support and VT-d are also enabled or disabled from this section.
The 'Power' section allows users to optimize the system for balanced performance, or low power operation, or for maximum performance. In the last case, Intel's Dynamic Power Technology can also be configured for energy efficiency. Further customization is possible by allowing for different sustained and burst mode package power limits (PL1 and PL2), as well as the package power time window. Secondary power settings allow for configuration of LED behavior in different sleep states, as well as allowing support for waking up via different peripheral interfaces. PCIe ASPM support is also controllable from this section. The 'Boot' section allows configuration of secure boot, boot priorities, POST screen configuration, etc. A boot override option here is probably the only update we would like in the BIOS - a shortcut to rebooting and pressing F10 repeatedly in order to choose a temporary boot device.
Intel's documentation provides a block diagram for the Tiger Canyon NUC board. It gives insights into the distribution of high-speed I/O lanes.
The PCIe 4.0 x4 lanes servicing the M.2 NVMe SSD and the two Thunderbolt 4 ports are directly off the processor die. A single PCIe 3.0 x1 lane from the Tiger Point-LP PCH is used to connect the Intel I225-LM controller. The AX201 WLAN controller hooks up via the CNVi interface in the PCH. The front USB 3.2 Gen 2 ports are from the processor, while the USB 2.0 and USB 3.2 Gen 2 ports in the rear are from the PCH.
In addition to the comparison between the actively-cooled and passively-cooled versions of the NUC11TNBi5, we also consider some of the other passively cooled PCs reviewed earlier, as well as a few other recent UCFF systems. In the table below, we have an overview of the various systems that we are comparing.
| Comparative PC Configurations | ||
| Aspect | Intel NUC11TNBi5 (Akasa Newton TN) | |
| CPU | Intel Core i5-1135G7 Tiger Lake 4C/8T, 2.4 - 4.2 GHz Intel 10nm SuperFin, 8MB L2, 28W (PL1 = 28W, PL2 = 64W) |
Intel Core i5-1135G7 Tiger Lake 4C/8T, 2.4 - 4.2 GHz Intel 10nm SuperFin, 8MB L2, 28W (PL1 = 28W, PL2 = 64W) |
| GPU | Intel Iris Xe Graphics (80EU @ 1.30 GHz) |
Intel Iris Xe Graphics (80EU @ 1.30 GHz) |
| RAM | Kingston 9905744-035.A00G DDR4-3200 SODIMM 22-22-22-52 @ 3200 MHz 2x16 GB |
Kingston 9905744-035.A00G DDR4-3200 SODIMM 22-22-22-52 @ 3200 MHz 2x16 GB |
| Storage | Samsung 980 PRO MZ-V8P500B/AM (2500 GB; M.2 2280 PCIe 4.0 x4 NVMe;) (1xxL V-NAND Gen 6 3D TLC; Samsung Elpis S4LV003 Controller) |
Samsung 980 PRO MZ-V8P500B/AM (2500 GB; M.2 2280 PCIe 4.0 x4 NVMe;) (1xxL V-NAND Gen 6 3D TLC; Samsung Elpis S4LV003 Controller) |
| Wi-Fi | 1x 2.5 GbE RJ-45 (Intel I225-LM) Intel Wi-Fi 6 AX201 (2x2 802.11ax - 2.4 Gbps) |
1x 2.5 GbE RJ-45 (Intel I225-LM) Intel Wi-Fi 6 AX201 (2x2 802.11ax - 2.4 Gbps) |
| Price (in USD, when built) | (Street Pricing on June 6th, 2022) US $440 + $150 + $130 + $95 = $815 (as configured, no OS) |
(Street Pricing on June 6th, 2022) US $440 + $150 + $130 + $95 = $815 (as configured, no OS) |
The NUC11TNKi5 and the NUC11TNBi5 (Akasa Newton TN) share the same configuration except for the pricing. The ASUS PN51-E1 slots in as a comparison point for what a mid-range Renoir can deliver (since we are comparing against a mid-range TGL-U part). It is a relevant comparison point for the NUC11TNKi5 from a price viewpoint, given they are both actively cooled. The ASUS PN50 and ASRock Industrial 4X4 BOX-4800U make up the high-end actively-cooled Renoir systems.
We also have results from a recent re-benchmarking session of the ASRock Industriall NUC BOX-1165G7. It uses the latest BIOS (P1.40), but modifies the default options to better reflect usage in a home / business scenario (ASRock Industrial stated that they had optimized the BIOS defaults for industrial deployment). 'Advanced > CPU Configuration > CPU Operation Mode' was changed from default 'Normal Mode' (PL1 = 28W / PL2 = 28W) to 'Performance Mode' (PL1 = 38W / PL2 = 55W), 'Advanced > CPU Configuration > CPU C-States Support' was changed from default 'Disabled' to 'Enabled', 'CPU C States Support > Enhanced Halt State (C1E)' set to 'Enabled', 'CPU C States Support > Package C State Support' set to 'Auto', and 'CPU C States Support > CFG Lock' left at 'Disabled'.
The OnLogic HX500 is a representation for Intel's previous generation in a fanless avatar. Even though it utilizes a desktop CPU with a 35W TDP, it makes sense to include it in the comparisons as Tiger Lake-U includes fine-grained power management with boosts up to 64W to make it competitive against real desktop CPUs.
The Akasa Turing / Bean Canyon configuration is also included in the benchmarks to identify improvements that consumers can see for similarly priced systems when upgrading after a couple of generations. Results from a Core i5 Comet Lake-U system (the Minisforum UM850) are also included. Finally, we have Supermicro's SM-E100-12T-H - another TGL-U representation, albeit at a much lower package power limit.
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meacupla - Sunday, July 24, 2022 - link
At that point, you may just want to use a white noise makerabufrejoval - Sunday, July 24, 2022 - link
Thanks, that's what I've been hearing, too!And in a way that's what I've been thinking without hinting it explicitely to Ryan1981: Getting yourself tuned to zero noise is both very expensive and counter-productive.
Humanity has operated on communal and external noises for hundreds of thousands of years: a large part of our brain is designed to do nothing but discriminate between sounds that indicate danger and those that don't. A total absense of sound only has your brain increase the sensitivity of your receptors to the point where minute sounds become a bother.
Instead of making electronics completely silient, we should have them emit a soft snore or other comforting noises akin to humans being human.
There is an auditorium in the midst of Gibraltar's rock, that offers a level of silence no recording studio can match. Anyone left alone in there is bound to develop tinnitus as the brain keeps increasing the sensitivity in your in-ear "DSPs" to the point where they get the "social noise" evolution set as a base line.
abufrejoval - Saturday, July 23, 2022 - link
Your previous Akasa tests had me hoping, that I’d be able to silence any NUC, if a passive Mini-ITX based solution, like the one I’d been using for Gemini Lake Atoms, wasn’t going to be available.I had sampled a NUC or Brix once before and was quite shocked at the nervous noise it generated: the fan gave you an audio variant of a CPU graph that you couldn’t just click away. And at top load, it was an unacceptable howler.
I wanted something with a bit more punch than an Atom, but a similar idle power and obviously a notebook SoC should be able to do that. But the only way to get that stationary and at a reasonable price (with a full complement of RAM) was to get a NUC.
When I hit across a NUC8i7BEK with the “double sized” Iris 655 48EU iGPU for only €300, my resistance to the form factor melted away and I gave it a try, even if the primary use case—a Linux based HCI server—had zero use for a GPU. After all you never know if it might be recycled as a desktop later and I was just curious to see how this “Apple spec” SoC would perform.
It turned out that they key to making it unnoticeable was to ensure that the fan would never rev beyond 3200rpm and for that I had to ensure that PL2 would never last longer than 10 seconds nor exceed 50 Watts, while a PL1 of 15 Watts ensured low fan revs even for a power virus.
I had just ordered another, when I saw a hexa-core i7-10700U based NUC (with a very ordinary 24EU iGPU) going for just €50 extra. So I cancelled and got that one instead. It turned out much more difficult to tame, because Intel was desperate to wring performance leadership out of 14nm in a tiny NUC and only Watts can get you there. I managed again, playing with the PL1/PL2/TAU to get a system rather good for those sprints where the Atoms were trying my patience, yet with a low-enough power and noise footprint to operate 24x7 as a server.
Half a year later in February 2021 I landed a fresh Tiger Lake NUC11PAHi7, that’s played hard to get ever since. But mine is a Panther Canyon variant, evidently consumer optimized, with a completely different layout of ports for which Akasa doesn’t build a chassis. I don’t know if Intel already made these differentiations in earlier generations, but it’s rather annoying when only the number of models increases, not their availability.
Again, that Tiger could also be tamed to unnoticeability via the excellent control Intel’s NUCs offer in the BIOS. Of course, even better would be a set of CLI tools which allow you to adjust these things from Linux…
In terms of snappiness, none of them needs to hide, because at least for a couple of seconds they will all clock to 4.5 GHz or more and match any desktop. For brutal workloads I have other machines with 16 or 18 cores and 140-150 Watts of TDP made tolerable via lots of giant Noctua fans and coolers.
While there is no noticeable difference in scalar performance between the NUC8 and NUC10, the two extra cores on the NUC10 i7-10700U will obviously deliver a bit of extra punch until TAU runs out. But the Tiger Lake annihilates their value with better IPC: with its four cores it matches pretty exactly the six cores of its predecessor on any parallelized workload while the single core performance is on par with a Zen 3 at the same clocks.
The “double sized” Iris 655 with its 128MB of eDRAM on the NUC8 turned out to be a paper tiger, effectively adding only 50% of extra power vs. a normal 24EU UHD iGPU at the expense of quite a bit of silicon real-estate and production complexity. If Intel were to sell “Apple spec” chips only, I doubt they’d be nearly as profitable. The list price of an i7-8565U is $409 while the list price of an i7-8559U is only $22 higher. They are close to identical on the CPU side, but the GT3e extra die area and the 128MB eDRAM chip must have cost a pretty penny! I still own a notebook with an i5-6267U, a dual-core Skylake variant of GT3e where the CPU cores were probably the smallest piece of the chip’s silicon pie.
Really astounding was how badly it got beaten by the 96 Tiger Lake Xe iGPU, which doesn’t have eDRAM for extra bandwidth: that one scaled rather nicely to 4x 24EU performance, beating my Ryzen 3 based 5800U APUs in most benchmarks, just as you describe.
I don’t really know where that performance is coming from, because DRAM bandwidth is very similar across the board and only around 40GB/s. All my NUCs run with 64GB and while the timings may have gone from DDR4-2400 (NUC8) to DDR4-3200 (NUC11), that’s just adding wait states on these low power devise.
I love running Google Maps in 3D globe view on Chrome derived browsers at 4k, because it really shows what this low power hardware is capable of with perhaps the most efficient 3D pipeline on the planet: it puts Microsoft’s best flight simulator to shame on an RTX 2080ti!
It proves the main issue is software, not hardware. But existing real-world games are no fun on these boxes, even the Tiger Lake needs another power of 10 to become reasonably attractive at 4k.
Another aftermarket NUC solution would evidently be one that adds a beefy active cooling, say a Noctua NH-L9i or even a Noctua NH-L9x65. Obviously these chips could sustain 65 Watts with proper cooling and then deliver quite a reasonable desktop performance in only a slightly bigger form factor.
BTW: for my use as µ-servers I've added TB3 based 10Gbase-T NICs so the NVMe based SSDs contributing bricks to the Gluster file system don't get slowed down to inacceptable levels.
I'd have preferred to make do with TB3 based networking via direct connect cables, but fell afoul the fact that Thunderbolt ports don't have MACs and will randomly generate them on every boot or plug event. It's the software.... again!
xane - Sunday, July 24, 2022 - link
Interesting to see continued development, but for me nothing beats Cirrus7 cases from Germany. I do understand it's subjective, though.Hixbot - Tuesday, July 26, 2022 - link
Ganesh, I've been politely asking you add noise testing to your mini-pc tests for the last couple years. Noise is a very important characteristic to home theater PCs.Here we are with a fanless offering with some obvious thermal compromises, but your other reviews don't highlight noise at load and therefore cannot be compared.
ganeshts - Tuesday, July 26, 2022 - link
If there is any noise / electrical coil whine, or anything of that sort, I do make a mention of it in the concluding section (like I did in the Zotac ZBOX CI660 nano).Other than that, the ambient noise / noise floor is too high in the environment where these systems are tested for a sound meter to pick up anything at all from them.
kepstin - Wednesday, August 24, 2022 - link
You should really consider retiring/updating that Gimp application startup benchmark… The multithreaded scaling being weird is actually a bug where it's doing extra redundant work that it shouldn't have been, and has been fixed (or at least worked around) in newer versions.storapa - Thursday, September 1, 2022 - link
Had an old NUC3 with the old version of the Akasa Newton. Worked like a charm for years, until the board died (google results suggests it was a common problem with NUC3, not the case).But note that the kensington "lock" doesn't add any security, as you can remove the entire backplate with 4 screws..