Is nobody bothered by the fact that these diagrams don't start at 0? I completely misread the diagrams at first. Maybe it's me

Can you please retest while overclocking?

FWIW, one side of it is just plastic.

Not on purpose. I just put my Pi on desk. I want to make sure someone accidentally touching it won't be hurt/surprised in case it happens to be running something heavy. For example, moving it around when cleaning the desk. I guess it's not really a big deal. The case probably won't have time to heat up that much unless I intend to run my Pi at 100% often.

But the N2 is faster, being based on A73 cores, while the RockPi64 uses A72 cores. ODROID made a N1 that was based on the same SoC as the RockPi64, but they cancelled it.

Also, I don't know why you're comparing DDR speeds vs. CPU clock speeds. The N2 runs its A73 cores up to 1.8 GHz and its A53 cores at about 1.9 GHz.

The N2 simply doesn't need a fan. It's manufactured at 12 nm. When running all 6 cores at sustained max load, using the stock, passive heatsink, it plateaus around 73 C, which seems to be below the point of throttling.

Have a good read through their benchmarks (including their N1 comparisons, should you want to compare it with RockPi64).

https://www.hardkernel.com/shop/odro...th-4gbyte-ram/

Clearly, I don't agree with your conclusion.

Are you going to be picking it up while it's running games or some other heavy load? If it's running close to idle, I'm sure it will not be too hot.

In what sense? In 3 tests, it gives a distinct temperature advantage. In 3 other tests, it gives a distinct performance advantage. Still, I'm with you that I expected the gap to be larger. I wonder if he ran it inside a case.

1. The FLIRC seems to have plastic on both sides, including right above the CPU. IMO, they should've kept it aluminum, on that side.
2. They said 28 nm is cheapest per transistor. Previous generations of the Pi all used 40 nm. Eben Upton has been quoted as saying he expects they'll remain on 28 nm for some time, by which I infer at least one more generation. They made the Pi as good as they could, within a budget.

Reference: https://www.raspberrypi.org/magpi/eb...aspberry-pi-4/

So, you're running the Pi caseless in 3 of the trials, and the FLIRC is the only one where you have it in a case? If not, what case are the heatsink, no heatsink, and fan shim using?

Also, is the outside of the fan shim entirely plastic? I imagine it'd work even better, if the bottom was metal and thermally-coupled to the SoC via tape, paste, etc.

And can you please confirm that the FLIRC has big slabs of plastic on both sides?

Finally, what about the noise of the fan shim? Some RPMs or dB measurements (A-weighted @ 1 M seems standard) would be appreciated.

Thanks for the tests. The fan shim wins on cuteness, for those using transparent cases, but the FLIRC is quite handsome. Noise & fan shim performance, inside a case, would factor into my end decision. I would use a case to mitigate dust buildup.

Please consider another article that adds a case to the fan shim, if that's not what you did. Noise measurements (with & without case) would also be nice. Thanks.

We already did the thermal tests here with a theoretical workload (cpuburn-a53): https://amzn.to/31MKgoz
See photo 4 and 6. The Raspberry Pi 4 can work at full speed for around 60 seconds with just a small proper heatsink. If it was a non-theoretical workload, it will last even longer at full speed. Contrary to a lot of information that are subjective, our objective testing shows that Raspberry Pi 4 consumes less power at full theoretical workload than Raspberry Pi 3 models. Only the idle and startup current of the Pi 4 is double that of Pi 3. Peak power consumption is actually 0.3A less (1.5A for Pi 4 @ 1.5GHz vs 1.8A for Pi 3 @ 1.4GHz).