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This self-balancing robot was designed and built by Kerry Wong and uses just a few ICs and some basic electronic components to get the job done. This project is definitely more up your alley if you’re interested in using discrete components rather than a microcontroller designed for prototyping, but the cost in doing it this way makes it attractive.

From Kerry’s site:

I used a LPY450AL for the gyroscope and anMMA8453Q for the accelerometer. These two devices are rather inexpensive and the IMU can be built for well under $10.

The toy truck I used for this project has a single motor that drives both of the rear wheels. Since I only need the drive wheels, I cut off the unused front portion. The toy car’s plastic chassis is not rigid enough so I hot-glued a few pieces of plastic and metal support on the back. The extra support is important as excessive vibrations affect the accuracy of the sensor measurements.

Here is the bill of material in my build:

Platform: Toy truck (0 – $20)
Controller: ATmega328P (~$4)
Accelerometer: MMA8453Q (~$2)
Gyroscope: LPY450AL ($4)
H-Bridge: SN754410 (~$2)
Miscellaneous: ~$10

[via Hacked Gadgets]

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Michael Colombo

In addition to being an online editor for MAKE Magazine, Michael Colombo works in fabrication, electronics, sound design, music production and performance (Yes. All that.) In the past he has also been a childrens’ educator and entertainer, and holds a Masters degree from NYU’s Interactive Telecommunications Program.


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Comments

  1. fumingsolder says:

    From the video, it looks as if compensating for dis-balance would have been easier if the batteries were moved all the way to the bottom and the gyroscope – all the way to the top (where the acceleration would have been increased by increasing the distance to the center of rotation). I am intrigued why the builder chose to put the heavy batteries all the way up, even extended them further out on the stick? This seems like a conscious choice I can’t explain.

    1. Peter says:

      Putting the batteries up high raises the center of mass. This increases the rotational inertia. The higher rotational inertia means the pendulum is slower to fall, although it does require a stronger push to compensate. But this also means the slower response motors and control circuitry are up to the task of balancing.

    2. bob says:

      it is meant to make the robot look more jmpressive and it proves that it stabilizes well.

  2. fumingsolder says:

    Yes, I thought the rotational inertia would have something to do with it. My guess is this particular design would not be as good at showing tricks of quick recovery or putting itself upright from an “OFF” position as I’ve seen on other Youtube videos. And still, wouldn’t it make more sense to move the sensors (pardon the pun) as high as possible to further increase the mass at the top and also add to the acceleration which would probably make the sensor respond even quicker? You can guess: I’m collecting some preliminary info for starting my own self-balancing project :)

  3. sashank says:

    Can i get the code………..
    me a student gng to proceed further having problem with gyro interface?

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