Introduction to MPU6050: Beginner-Friendly Guide

The MPU6050 is a popular motion tracking device. It combines 3-axis Gyroscope and 3-axis Accelerometer sensors. Motion, acceleration and rotation can be easily detected by the combined sensors. The MPU6050 can transfer data through I²C. Its high accuracy and low cost make it very popular for robotic, drone and gaming controller projects.

Key Features

6 Degrees of Freedom (6-DoF)
Measures motion along X, Y, and Z axes (both acceleration and rotation).
Built-in Accelerometer
Detects linear acceleration (movement, tilt, vibration).
Built-in Gyroscope
Measures angular velocity (rotation speed).
Digital Motion Processor (DMP)
Performs complex calculations like sensor fusion internally, reducing the workload on the main microcontroller.
I²C Communication Interface
Communicates with microcontrollers like Arduino, Raspberry Pi, etc.

Pinout

VCC – Power supply (3.3V–5V)
GND – Ground
SCL – I²C Serial Clock
SDA – I²C Serial Data
INT – Interrupt output
XDA – Auxiliary Serial Data (Used when another sensor is connected to this module)
XCL – Auxiliary Serial Clock (Used when another sensor is connected to this module)
AD0 – I²C address selection

I2C Address – 0x68 vs 0x69

The gyroscope and accelerometer values can be read from the chip over I2C. The MPU6050 has two I2C addresses. The default address is 0x68.

0x68 → Default address (ADO pin LOW)
0x69 → Alternate address (ADO pin HIGH)

If you need two MPU6050 sensors on the same I2C bus, use the ADO pin HIGH on one module with the address 0x69.

How It Works

The MPU6050 combines 3-Axis accelerometer and 3-Axis gyroscope integrated on a single chip.

Accelerometer: Measures linear acceleration along X, Y, and Z axes with ranges of ± 2g, ± 4g, ± 8g, and ± 16g. It helps detect tilt, vibration, and movement.

Gyroscope: Measures rotational speed around X, Y, and Z axes with ranges of ± 250, ±500, ±1000, and ±2000 degrees/second. It helps track angular motion and orientation.

Gyroscopes drift over time, but are highly accurate during fast movements. Accelerometers are terrible with fast movements but are highly accurate over the long term. By combining the accelerometer and gyroscope data, the accelerometer continuously provides a baseline “zero-drift” check to correct the gyroscope’s integrated errors. We can get very accurate information about the sensor orientation.

Install MPU6050 and I2Cdev Libraries

Download the zip file by clicking Here.

Open the folders: i2cdevlib-master → Arduino.

Drag Folder I2Cdev and MPU6050 to your libraries folder.

MPU6050 Calibration

MPU6050 units are rarely perfectly calibrated at the factory. MPU6050 needs to be calibrated before it is used for the first time.

Hardware Required

Arduino UNO

For more information, visit Getting to Know Your Arduino Uno: A Beginner’s Guide to Its Components.

MPU6050

Breadboard

Jumper Wires

Setup

MPU6050	Arduino UNO
VCC	5V
GND	GND
SCL	A5
SDA	A4

A4/SDA and A5/SCL are Arduino I2C Pins. The I2C protocol uses two lines to send and receive data: a serial data (SDA) line and a serial clock (SCL) line. With I2C, we can connect multiple devices only using two wires. SCL is used to synchronously clock data. SDA is used to transmit data to or from target devices. The clock signal acts as a metronome. It synchronizes the transfer of serial data, indicating to the devices the correct time to capture each bit. Visit Inter-Integrated Circuit (I2C) Protocol for more information.

Code

// Arduino sketch that returns calibration offsets for MPU6050 //   Version 1.1  (31th January 2014)
// Done by Luis Ródenas <[email protected]>
// Based on the I2Cdev library and previous work by Jeff Rowberg <[email protected]>
// Updates (of the library) should (hopefully) always be available at https://github.com/jrowberg/i2cdevlib

// These offsets were meant to calibrate MPU6050's internal DMP, but can be also useful for reading sensors. 
// The effect of temperature has not been taken into account so I can't promise that it will work if you 
// calibrate indoors and then use it outdoors. Best is to calibrate and use at the same room temperature.

/* ==========  LICENSE  ==================================
 I2Cdev device library code is placed under the MIT license
 Copyright (c) 2011 Jeff Rowberg
 
 Permission is hereby granted, free of charge, to any person obtaining a copy
 of this software and associated documentation files (the "Software"), to deal
 in the Software without restriction, including without limitation the rights
 to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 copies of the Software, and to permit persons to whom the Software is
 furnished to do so, subject to the following conditions:
 
 The above copyright notice and this permission notice shall be included in
 all copies or substantial portions of the Software.
 
 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 THE SOFTWARE.
 =========================================================
 */

// I2Cdev and MPU6050 must be installed as libraries
#include "I2Cdev.h"
#include "MPU6050.h"
#include "Wire.h"

///////////////////////////////////   CONFIGURATION   /////////////////////////////
//Change this 3 variables if you want to fine tune the skecth to your needs.
int buffersize=1000;     //Amount of readings used to average, make it higher to get more precision but sketch will be slower  (default:1000)
int acel_deadzone=8;     //Acelerometer error allowed, make it lower to get more precision, but sketch may not converge  (default:8)
int giro_deadzone=1;     //Giro error allowed, make it lower to get more precision, but sketch may not converge  (default:1)

// default I2C address is 0x68
// specific I2C addresses may be passed as a parameter here
// AD0 low = 0x68 (default for InvenSense evaluation board)
// AD0 high = 0x69
//MPU6050 accelgyro;
MPU6050 accelgyro(0x68); // <-- use for AD0 high

int16_t ax, ay, az,gx, gy, gz;

int mean_ax,mean_ay,mean_az,mean_gx,mean_gy,mean_gz,state=0;
int ax_offset,ay_offset,az_offset,gx_offset,gy_offset,gz_offset;

///////////////////////////////////   SETUP   ////////////////////////////////////
void setup() {
  // join I2C bus (I2Cdev library doesn't do this automatically)
  Wire.begin();
  // COMMENT NEXT LINE IF YOU ARE USING ARDUINO DUE
  TWBR = 24; // 400kHz I2C clock (200kHz if CPU is 8MHz). Leonardo measured 250kHz.

  // initialize serial communication
  Serial.begin(9600);

  // initialize device
  accelgyro.initialize();

  // wait for ready
  while (Serial.available() && Serial.read()); // empty buffer
  while (!Serial.available()){
    Serial.println(F("Send any character to start sketch.\n"));
    delay(1500);
  }                
  while (Serial.available() && Serial.read()); // empty buffer again

  // start message
  Serial.println("\nMPU6050 Calibration Sketch");
  delay(2000);
  Serial.println("\nYour MPU6050 should be placed in horizontal position, with package letters facing up. \nDon't touch it until you see a finish message.\n");
  delay(3000);
  // verify connection
  Serial.println(accelgyro.testConnection() ? "MPU6050 connection successful" : "MPU6050 connection failed");
  delay(1000);
  // reset offsets
  accelgyro.setXAccelOffset(0);
  accelgyro.setYAccelOffset(0);
  accelgyro.setZAccelOffset(0);
  accelgyro.setXGyroOffset(0);
  accelgyro.setYGyroOffset(0);
  accelgyro.setZGyroOffset(0);
}

///////////////////////////////////   LOOP   ////////////////////////////////////
void loop() {
  if (state==0){
    Serial.println("\nReading sensors for first time...");
    meansensors();
    state++;
    delay(1000);
  }

  if (state==1) {
    Serial.println("\nCalculating offsets...");
    calibration();
    state++;
    delay(1000);
  }

  if (state==2) {
    meansensors();
    Serial.println("\nFINISHED!");
    Serial.print("\nSensor readings with offsets:\t");
    Serial.print(mean_ax); 
    Serial.print("\t");
    Serial.print(mean_ay); 
    Serial.print("\t");
    Serial.print(mean_az); 
    Serial.print("\t");
    Serial.print(mean_gx); 
    Serial.print("\t");
    Serial.print(mean_gy); 
    Serial.print("\t");
    Serial.println(mean_gz);
    Serial.print("Your offsets:\t");
    Serial.print(ax_offset); 
    Serial.print("\t");
    Serial.print(ay_offset); 
    Serial.print("\t");
    Serial.print(az_offset); 
    Serial.print("\t");
    Serial.print(gx_offset); 
    Serial.print("\t");
    Serial.print(gy_offset); 
    Serial.print("\t");
    Serial.println(gz_offset); 
    Serial.println("\nData is printed as: acelX acelY acelZ giroX giroY giroZ");
    Serial.println("Check that your sensor readings are close to 0 0 16384 0 0 0");
    Serial.println("If calibration was succesful write down your offsets so you can set them in your projects using something similar to mpu.setXAccelOffset(youroffset)");
    while (1);
  }
}

///////////////////////////////////   FUNCTIONS   ////////////////////////////////////
void meansensors(){
  long i=0,buff_ax=0,buff_ay=0,buff_az=0,buff_gx=0,buff_gy=0,buff_gz=0;

  while (i<(buffersize+101)){
    // read raw accel/gyro measurements from device
    accelgyro.getMotion6(&ax, &ay, &az, &gx, &gy, &gz);
    
    if (i>100 && i<=(buffersize+100)){ //First 100 measures are discarded
      buff_ax=buff_ax+ax;
      buff_ay=buff_ay+ay;
      buff_az=buff_az+az;
      buff_gx=buff_gx+gx;
      buff_gy=buff_gy+gy;
      buff_gz=buff_gz+gz;
    }
    if (i==(buffersize+100)){
      mean_ax=buff_ax/buffersize;
      mean_ay=buff_ay/buffersize;
      mean_az=buff_az/buffersize;
      mean_gx=buff_gx/buffersize;
      mean_gy=buff_gy/buffersize;
      mean_gz=buff_gz/buffersize;
    }
    i++;
    delay(2); //Needed so we don't get repeated measures
  }
}

void calibration(){
  ax_offset=-mean_ax/8;
  ay_offset=-mean_ay/8;
  az_offset=(16384-mean_az)/8;

  gx_offset=-mean_gx/4;
  gy_offset=-mean_gy/4;
  gz_offset=-mean_gz/4;
  while (1){
    int ready=0;
    accelgyro.setXAccelOffset(ax_offset);
    accelgyro.setYAccelOffset(ay_offset);
    accelgyro.setZAccelOffset(az_offset);

    accelgyro.setXGyroOffset(gx_offset);
    accelgyro.setYGyroOffset(gy_offset);
    accelgyro.setZGyroOffset(gz_offset);

    meansensors();
    Serial.println("...");

    if (abs(mean_ax)<=acel_deadzone) ready++;
    else ax_offset=ax_offset-mean_ax/acel_deadzone;

    if (abs(mean_ay)<=acel_deadzone) ready++;
    else ay_offset=ay_offset-mean_ay/acel_deadzone;

    if (abs(16384-mean_az)<=acel_deadzone) ready++;
    else az_offset=az_offset+(16384-mean_az)/acel_deadzone;

    if (abs(mean_gx)<=giro_deadzone) ready++;
    else gx_offset=gx_offset-mean_gx/(giro_deadzone+1);

    if (abs(mean_gy)<=giro_deadzone) ready++;
    else gy_offset=gy_offset-mean_gy/(giro_deadzone+1);

    if (abs(mean_gz)<=giro_deadzone) ready++;
    else gz_offset=gz_offset-mean_gz/(giro_deadzone+1);

    if (ready==6) break;
  }
}

1. Upload code. Put your MPU6050 as horizontally as possible. Input any character and hit Enter to start.

2. Make sure the MPU6050 does not move. Wait for the results.

3. Write down the offset values for your projects using MPU6050 library.

 // supply your own gyro offsets here, scaled for min sensitivity
 mpu.setXGyroOffset(0);
 mpu.setYGyroOffset(0);
 mpu.setZGyroOffset(0);
 mpu.setZAccelOffset(0); // 1688 factory default for my test chip