https://www.jeffgeerling.com/blog/2021/m2-on-raspberry-pi-tofu-compute-module-4-carrier-board

Skip to main content
Jeff Geerling

Main menu

  * Blog
  * Projects
  * About

M.2 on a Raspberry Pi - the TOFU Compute Module 4 Carrier Board

March 12, 2021

Ever since the Pi 2 model B went to a 4-core processor, disk IO has
often been the primary bottleneck for my Pi projects.

You can use microSD cards, which aren't horrible, but... well,
nevermind, they're pretty bad as a primary disk. Or you can plug in a
USB 3.0 SSD and get decent speed, but you end up with a cabling mess
and lose bandwidth and latency to a USB-to-SATA or USB-to-NVMe
adapter.

The Pi 4 actually has an x1 PCI Express gen 2.0 lane, but the USB 3.0
controller chip populates that bus on the model B. The Compute Module
4, however doesn't presume anything--it exposes the PCIe lane directly
to any card it plugs into.

TOFU board by Oratek - Raspberry Pi Compute Module 4 Carrier with M.2
slot

And in the case of Oratek's TOFU, it's exposed through an M.2 slot,
making this board the first one I've used that can accept native NVMe
storage, directly under the Pi:

M.2 slot on bottom of TOFU CM4 carrier board

Now, a single x1 lane at gen 2 speeds tops out around 400 MiB/sec in
real-world usage, so many NVMe drives are still underpowered
connected to the Pi, but as you'll see in a bit, a cheap KingSpec SSD
was 3x faster for random IO than a similar SSD plugged in via USB
3.0.

I'd like to thank the Swiss company Oratek for sending me this TOFU
board. The board is just 9 centimeters square, yet packs in most of
the same features on the much larger Compute Module 4 IO Board:

Raspberry Pi TOFU carrier board on top of Compute Module 4 IO Board

Video review

I also posted a video that goes along with this blog post on my
YouTube channel:

M.2 on a Pi

Let's start on the bottom, and take a look at the M.2 slot on the
TOFU. Some other Compute Module 4 boards I've been keeping my eye on
are designed around the more popular 'M key' slot in the 80mm form
factor.

Other boards have 30mm 'A+E' key slots, that accept things like the
Google Coral TPU, or WiFi 6 cards like the Intel AX200 I tested.

But the TOFU has a 'B' type M.2 2242 socket, meaning it accepts only
B or B+M key devices.

And the slot on this board only has one standoff at 42 millimeters,
so you can't fit shorter devices like a 30 mm 'B+M key' NVMe, like
the WD SN520. Of course, if you taped it down it would work, but
that's not a great solution:

Kapton tape holding down WD 30mm 2030 M.2 NVMe SSD on TOFU board

But 42mm devices work great, as long as driver support is present on
the Pi--and for NVMe drives, at least, Pi OS includes support out of
the box.

I bought a KingSpec 128GB 2242 NVMe drive, and after installing it,
it showed up using lsblk, and I could format and mount it like any
other drive.

I compared this setup to a similarly-priced SSD I reviewed in the
Argon One M.2, which connects an SSD inside the same case as a Pi 4,
but using a USB 3.0 to SATA adapter.

Argon One M.2 Kingston SATA SSD over USB 3 benchmark compared to TOFU
KingSpec NVMe SSD

Since the NVMe drive communicates directly over the Pi's PCI express
bus, it performs much better on every benchmark.

And yes, the two drives are not the exact same; but after testing a
few dozen SATA SSDs and NVMe drives, both natively and through USB
adapters, I can say with confidence that the USB adapters soak up at
least 10-20% of the bandwidth, and it's worse for random IO, which
requires better latency. Direct SATA and NVMe connection is a lot
faster, plus cabling (especially for NVMe... where there is none) is
a lot cleaner.

[S:Unfortunately, you can't boot off an NVMe drive--at least not yet.
The Pi's firmware needs to be updated to support this feature. It
seems like it may happen, but there's no timeline for it yet.:S]

    Update: Apparently this week NVMe SSD Boot was just added as a
    beta feature in the Pi firmware, though it requires a bit of a
    process to use it: NVMe SSD Boot (BETA).

NVMe drives are only one of the accessories you can install on the
TOFU, though. What it's really designed for is a 4G LTE module, like
a Sierra Wireless AirPrime. The TOFU includes a built-in SIM tray, so
you can get mobile service on the board.

Industrial Use

As more industrial systems require more Internet connectivity, it's
important to make robust control boards with both wireless and wired
networking. And the Raspberry Pi Compute Module is a great platform
to build on, since it can run a full Linux OS and is easy to remotely
administer.

The TOFU has another feature that's extremely useful in industrial
settings: It accepts a wide range of power inputs.

Pi CM4 TOFU Board Power inputs 7.5-28v

You can either use a barrel plug (like the regular Compute Module IO
board) or a 3.5mm terminal block, and power the board with between
7.5 to 28V of DC power.

It also includes a 5 volt, 3.5 amp fuse to protect against
overcurrent, and also supports Power over Ethernet through the
standard Pi PoE HAT, since it includes the extra four pins used to
extract power from the ethernet connector and deliver it to the HAT.

Feature Overview

Outside of commercial use, the $100 dollar price tag is a little high
for the 'impulse buy then stick it in a drawer' use case most of us
using Pis are familiar with.

But it's a great, compact board for things like Pi clusters, remote
camera installations, or an interactive display system.

It preserves most of the ports you would get on a full size IO board
in half the space, including:

  * 1 CSI camera connector
  * 1 DSI display connector
  * 1 full-size HDMI port
  * 3 USB 2.0 ports (which need to be enabled to work)
  * 1 Gigabit Ethernet port
  * 40-pin GPIO header
  * microSD slot (only usable with CM4 Lite)
  * 1 USB-C port (used for flashing CM4 eMMC models--hold down the
    'boot' button while plugging into a host computer)

If powering the board via PoE or USB-C, the power lines to the M.2
slot are disabled, since these power methods can't guarantee enough
current for the M.2 spec--to use an M.2 slot you still need to power
the board through one of the 12V options.

On the bottom, there's:

  * 1 M.2 2242 slot
  * 1 microSIM slot for wireless cards

A case for the TOFU

Oratek was kind to provide the TOFU carrier board, but so far they
don't have a case for it. That's something they may be offering in
the future, but for now, I wanted something to house the board on my
desk, so I designed my first-ever 3D object: a case for the TOFU.

TOFU board inside custom 3D Printed case by geerlingguy

I built it in Fusion 360 following Shawn Victor's great PCB case
design tutorial, and printed it on my Ender 3 V2 printer. I had to go
through a few revisions before I got to the final form, but it is a
nice little enclosure, about the same size as the Argon One M.2 I
mentioned earlier.

I posted the case design to Thingiverse: TOFU Enclosure by
geerlingguy

Someday I'll learn how to make a top for the enclosure with a cutout
for a fan to cool the TOFU. For now, it just looks nicer and protects
the bottom of the TOFU, where the SSD is exposed.

Conclusion

At over $100 shipped to the US, I don't expect everyone to go out and
buy one of these things. But I like the design of the board, and
there are some applications where it is a great value, like for
remote installations, using solar power and a battery, for camera
surveillance or remote monitoring or control.

You can pre-order the TOFU at tofu.oratek.com, and see all the
Compute Module 4-based boards I've been tracking on my Pi PCI website
.

Further reading

  * The Raspberry Pi Compute Module 4 Review
  * Argon One M.2 Raspberry Pi SSD Case Review
  * Building the fastest Raspberry Pi NAS, with SATA RAID

raspberry pi
tofu
oratek
compute module
cm4
m2
ssd
nvme
review
youtube
video

  * Add new comment

Comments

T-Main - 5 hours ago

I Have a Laptop that's running Linux and the WD Black M.2/NVMe Drive
requires an addition to the Grub boot options in order to Boot Linux
so This:

nvme_core.default_ps_max_latency_us=5500

And that has to be added after the quiet splash part of the existing
Grub boot option/environment variables settings.

So I'd be very careful with any WD M.2/NVMe as Linux will not Boot on
an ASUS Tuf FX505DY-WH51 laptop(Ryzen 5 3550H/Radeon RX 560X discrete
GPU)! And the real annoying part is that I always keep the Linux Mint
Live USB handy to boot the laptop if the Grub Boot needs to get
repaired and I have to hand type in that:
nvme_core.default_ps_max_latency_us=5500 every time that I want to
Boot from the Mint Live USB Image on that ASUS Laptop. So I'll be
shopping soon for a Samsung M.2 NVMe SSD and out with that WD M.2 SSD
to some external/internal M.2 to USB adapter, for some external drive
usage more than likely!

  * Reply

Search [                              ]
[Search]
Geerling Family Crest
All content copyright Jeff Geerling. Top of page.