SmartKnob is an open-source input device with software-configurable endstops and virtual detents.

A brushless gimbal motor is paired with a magnetic encoder to provide closed-loop torque feedback control, making it possible to dynamically create and adjust the feel of detents and endstops.



SmartKnob View

Premium SmartKnob experience. Under active development.

Not recommended for general use yet (mechanical and electrical revisions are planned).

Requires advanced soldering experience to build – reflow and/or small-pitch surface-mount soldering are required, and assembly is quite time-consuming and delicate.


  • 240×240 round LCD, protected by 39.5mm watch glass on rotor
  • Low cost BLDC gimbal motor, with a hollow shaft for mechanically & electrically connecting the LCD
  • Powered by ESP32-PICO-V3-02 (Lilygo TMicro32 Plus module)
  • PCB flexure and strain gauges used for press detection (haptic feedback provided via the motor)
  • 8 side-firing RGB LEDs (SK6812-SIDE-A) illuminate ring around the knob
  • USB-C (2.0) connector for 5V power and serial data/programming (CH340)
  • VEML7700 ambient light sensor for automatic backlight & LED intensity adjustment
  • Versatile back plate for mounting – use either 4x screws, or 2x 3M medium Command strips (with cutouts for accessing removal tabs after installation)
  • Front cover snaps on for easy access to the PCB

Demo video


Exploded view

Latest Fusion 360 Model:

Build your own?

More documentation on the BOM and what parts you need to order is coming in the future – thanks so much for your interest! Follow me on Twitter for the latest updates on this and other projects.

A few miscellaneous notes in the meantime:

  • This can probably be FDM 3D printed with a well-tuned printer, but the parts shown in videos/photos were MJF printed in nylon for tight tolerances and better surface finish
  • If you wanted a simpler build, you could omit the LCD and just merge the knob + glass from the model into a single STL to get a closed-top knob
  • There’s limited space inside the LCD mount for wiring, and 8 wires need to fit through the hole in the center. I used 30 AWG wire-wrapping wire. Enamel-coated wire would probably work too.
  • Strain gauges are BF350-3AA, and glued in place with CA glue (I’ll include video of this process in the future, but essentially I used kapton tape to pick up the strain gauge and hold it in place during curing). This has to be done after reflow soldering, and would be hard to remove in case of a mistake, so MAKE SURE TO PRACTICE FIRST!
  • The TMC6300 is tiny and has a bottom pad, so I would seriously consider getting a stencil along with the PCB order. Even with the stencil I needed to manually clean up some bridging afterward; I highly recommend Chip Quik NC191 gel flux, available on Amazon (or use this non-affiliate link instead) or from your electronics distributor of choice.
  • For breadboard prototyping, the TMC6300-BOB is awesome and way easier to work with than the bare chip
  • Make sure to check the open issues – this design is not yet “stable”, so beware that everything may not go smoothly, but that’s the fun of DIY, right?

Future plans:

  • consider switch to using an ESP32-S3-MINI-1 module (once Arduino core support is complete), as that would allow for direct USB HID support (for joystick/macro-pad type input to a computer)
  • get wifi configured and working (probably MQTT?). Currently memory is an issue with the full display framebuffer sprite. PSRAM might fix this (requires newer ESP-IDF & unreleased Arduino core, and from a brief test I got horrible performance with PSRAM enabled), or the next item might help reduce memory:
  • migrate to LVGL, for better display rendering and easy support for menus, etc. Shouldn’t require a full 240x240x24b framebuffer in memory, freeing some for wifi, etc.
  • integrate nanopb for structured serial data (see splitflap protobuf protocol for example)
  • Home Assistant integration, or other real-world applications
  • ???
  • Profit 😉

Base PCB

Ordering notes: use white soldermask, for reflecting light from RGB LED ring around the knob. Should be 1.2mm thick (not “standard” 1.6mm).


Interactive BOM

PCB Packet


Screen PCB

Ordering notes: Must be 1.2mm thick (not “standard” 1.6mm) per mechanical design.


Interactive BOM

PCB Packet


SmartKnob Handheld

An exploration of a small handheld form-factor. Under active development.

SmartKnob Mini

Planned for the future.

Component Info

Magnetic encoders

MT6701 (MagnTek)

Excellent sensor at a reasonable price – highly recommended. Less noisy than TLV493D, and more responsive (control loop is more stable) using SSI.

  • Lots of IO options – SSI, I2C, and ABZ – should offer good response latency
  • SSI includes CRC to validate data
  • No power-down or low-power options – may not be ideal for battery-powered devices
  • Not available from US distributors (Mouser, Digi-Key)


Ordering (LCSC)

TLV493D (Infineon)

A mediocre choice. Easy to prototype with using Adafruit’s QWIIC breakout board.

In my testing, it is a little noisy, requiring filtering/smoothing that can slow responsiveness, hurting control loop stability. Or, with less filtering, the noise
can easily be “amplified” by the derivative component in the PID motor torque controller, causing audible (and tactile) humming/buzzing.

There is also apparently a known silicon issue that causes the internal ADC to sometimes completely lock up, requiring a full reset and re-configuration. See section
5.6 in the User Manual

In the Master Controlled Mode (MCM) or the Fast Mode (FM) the ADC conversion may hang up. A hang up can
be detected by:
 - Frame Counter (FRM) counter stucks and does not increment anymore.

In my experience testing 4 different Adafruit breakout boards, 2 of them (50%) regularly exhibit this lockup behavior within a minute or two of use. It is possible to detect and auto-reset (and there is code in the project to do so), but it is slow and may cause undesirable jumps/delays if the sensor locks up often.


AS5600 (AMS)

A mediocre choice. Cheap breakout boards are readily available.

In my testing, it’s fairly noisy (anecdotally, noisier than the TLV493d), requiring filtering/smoothing that can slow responsiveness, hurting control loop stability. Additionally, it saturates at a lower magnetic field strength than other sensors I tested, requiring a significant air gap (8-10mm) when used with a strong neodymium diametric magnet like Radial Magnets 8995.


Motor drivers


This is a relatively new IC and it’s a perfect match! There generally aren’t any other drivers (with integrated fets) that meet the requirements for the low-voltage and low-current motors used in this project (DRV8316 might work, but has not been tested).


  • 2-11V DC motor supply input
  • Up to 1.2A RMS
  • Tiny (3x3mm QFN)


Product page


32mm Rotor, Hollow Shaft, Diametric magnet

  • 32mm rotor
  • 15mm overall height (including magnet), 12.75mm height w/o magnet, 9mm rotor height
  • low/zero cogging – excellent for completely smooth input
  • 5.9mm hollow shaft
  • built-in diametric magnet for encoder
  • Proven option

This is overall the easiest motor to get started with. Low cogging and a built-in diametric magnet are great!


Coming soon: I’ve ordered over a dozen different BLDC motors to test and will create an overview of which ones are suitable for this kind of haptic feedback use-case.


TODO: document this

Also TODO: implement a lot more of the firmware

Frequently Asked Questions (FAQ)

How much does it cost?

I wish I could tell you now, but I don’t actually know off the top of my head. Check back soon – I’ve only built 1 so far, which was the result of a bunch of tinkering and prototyping over an extended period, so I don’t have all the expenses tallied up yet. Certainly less than $200 in parts, and maybe closer to $100?

Does it work with XYZ?

No. So far I’ve only implemented enough firmware for the demo shown in the video, so you can’t actually use it for anything productive yet. The basic detent configuration API is there, but not much else. Lots of firmware work remains to be done. If you build one, I’d love your help adding support for XYZ though!

Can I buy one as a kit or already assembled?

Probably not? Or at least, I don’t have any immediate plans to sell them myself. It’s not that I don’t want you to be happy, but hardware is a hard business and I just work on this stuff in my free time.

It’s open source with a fairly permissive license though, so in theory anyone could start offering kits/assemblies. If someone does go down that route of selling them, note that attribution is
required (and I wouldn’t say no to royalties/tips/thanks if you’re in a giving mood 🙂).


This project was greatly inspired by Jesse Schoch’s video “haptic textures and virtual detents” and the
corresponding discussion in the SimpleFOC community. Seriously, this project wouldn’t exist if not for that video – thank you Jesse!


This project is licensed under Apache v2 (software, electronics, documentation) and Creative Commons Attribution 4.0 (hardware/mechanical) (see LICENSE.txt and Creative Commons).

Copyright 2022 Scott Bezek

Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at

Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
See the License for the specific language governing permissions and
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