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OSOYOO 2WD Balance Car Robot is a fun, educational kit which allows you to make, program, and control a two-wheeled, self-stabilizing motorized vehicle. Once constructed, the car will operate and attempt to maintain an upright position through controlled movements, or after encountering external forces, such as bumps or obstacles in its path. Users can control the car via Bluetooth using the free OSOYOO Balance Car app, available for Android.
It is a Arduino Based Self-balancing Robot Kit. The OSOYOO 2WD Balance Car Robo is Open Source and easy to assemble. It uses strong aluminium alloy structures and keeps the robot balanced using its center of gravity. In order to achieve high-performance, we tests various torque-gear motors to ensure the robot will keep balance and move flexibly even if it gets pushed suddenly.
Building the OSOYOO 2WD Balance Car Robot will be so much fun for novice and experienced robotics fans!
– Build with your kids, at school, for yourself… this is a unique gadget. A perfect STEM education robot
– This self balancing robot has a medium size, perfect to carry your own beer (or mineral water ;-))
– There is a experienced technical support team behind OSOYOO so when you encounter problems, we will help you in the fastest way.
– You can use these self balancing robot parts to create more robots or gadgets, keep in mind all the devices used in a OSOYOO ROBOT are standard electronic devices with a lot of potential. You are now buying a self balancing robot, you are buying your a versatile set of electronics and ancillary devices.
Considering the safety of transportation, the 18650 battery is not included in the kit. (Click here to know how to get free18650 Rechargeable Li-ion battery from old laptop computer).
The OSOYOO 2WD Balance Car Robot is a two-wheeled self-balancing mobile robot kit. The kit is designed to be fun and easy to assemble. Meanwhile, learning about the different modules and their functions to create the robot.
The OSOYOO 2WD Balance Car Robot kit includes everything you need to make your own self-balancing robot: two high torque and high speed gear motors, wheels, aluminium alloy structures, 18650 battery holder (batteries are not included), Balance Shield, and Arduino UNO-compatible board.
The OSOYOO 2WD Balance Car Robot uses three 1.5mm thick aluminium alloy boards and other accessories for its main structure. One board is used to fix the two motors. One of the boards is used to fix the battery and the other is for an Arduino-compatible board plus the Balance Shield.
The robot utilizes a 3-axis accelerometer and a 3-axis gyroscope chip (MPU-6050) to determine if it is tilting over. Two stepper motors then activate appropriately to compensate for this falling motion to maintain the robot’s upright self-balancing position.
The Bluetooth chip (included) adds wireless communication to the OSOYOO 2WD Balance Car Robot. The robot can be remotely controlled by mobile devices running Android app. Control from the app allows for forward, reverse and left / right steering all the while the robot continuously self-balances itself.
A Complete Kit
The kit contains everything needed to make the OSOYOO 2WD Balance Car Robot. Electronic hardware from the embedded processor (Core module) to the steppers motors and wheels are included. Also included are the precision laser cut enclosure pieces to house the eConsidering the safety of transportation, the 18650 battery is not included in the kit. (Click here to know how to get free18650 Rechargeable Li-ion battery from old laptop computer). lectronic hardware. The Open Source code is provided and can be modified for personal.
The main controller chosen for the balancing robot is the Osoyoo UNO. It can be considered as the brain of the balancing robot and is connected to the IMU to process the tilt angle information. After processing, it will communicate with the motor driver in order to adjust the speed and direction of the motor.
The inertial measurement unit are electronic devices that measure and report about velocity, orientation and gravitational forces to which the device is subjected. IMUs combine information from various sensors, mainly magnetometers, accelerometers and gyroscopes. To use an IMU correctly, it will be necessary to combine the measurements of both devices. For this, two different methods are usually used:
The aim of this process is to obtain a measure as realistic as possible of the navigation angles of the object. These angles are defined by solving the problem of determining the position and orientation of an object relative to a base in a three-dimensional space. Allow the relative orientation of both systems to be expressed by describing the orientation of an object by three orthogonal rotations about the X (roll), Y (pitch) and Z (yaw) axes. In our case, the MPU-6050 IMU was used, which incorporates a gyroscope and an accelerometer and is accessible using the I2C communication bus.
Gravity’s acceleration is used as reference to calculate the angle that the accelerometer will use. An accelerometer is not a suitable sensor to determine the speed of a system, much less its position. So another tool must be used to get the value of the inclination value:
A gyroscope is a device that allows us to measure the angle of rotations rotated by a certain mechanism. These devices, unlike the accelerometer, are purely differential devices, so that angles relative to an arbitrary reference are always measured. The main problem of gyroscopes comes from having to obtain the measurements through an integration, an accumulation of errors will occur in the measurement, causing a drift in the measurement, medium and long term, with respect to its real value.
The basic idea behind a complementary filter is to combine the two outputs obtained with the accelerometer and the gyroscope to obtain a good estimate of the orientation angle. The filter will behave as a low-pass filter for the measurement of the accelerometer, and as a high pass filter for the gyroscope measurement. In this way the high frequency components of the accelerometer are dominated by the gyroscope. The mathematical way to implement this filter is:
Where FC is a constant defined by the user which has usually a value between 0.85 and 0.95.
Because we want to be able to control the robot using a smartphone, the easiest solution found was to use a bluetooth wireless communication module. The chosen device is a bluetooth module HC-06, which can be controlled using a communication via serial port.
More info about HC-06 please check this link: https://osoyoo.com/2017/10/25/arduino-lesson-hc-06-bluetooth-module/
In order to grant movement to the robot it will be necessary to use motors. From all of the engines available (brushless, stepper…) we chose DC engines because they have good torque and speed control.
For the DC motor used, below are the features of the DC motor:
i. Rated speed is 130rpm. The robot requires an average rpm so that it could counter the balancing error in a suitable speed. Low speed might not be able to balance the robot properly. Therefore, a higher rpm is chosen.
ii. Rated torque is 127.4 mN.m. The torque of the motors must be carefully chosen because a low torque might not be capable to balance the robot. The torque does not necessarily be too high. The torque required is based on the formula, Torque = Force x Distance
The LM2596 series of regulators are monolithic integrated circuits that provide all the active functions for a step-down (buck) switching regulator, capable of driving a 3-A load with excellent line and load regulation. These devices are available in fixed output voltages of 3.3 V, 5 V, 12 V, and an adjustable output version.
The TB6612FNG Motor Driver can control up to two DC motors at a constant current of 1.2A (3.2A peak). Two input signals (IN1 and IN2) can be used to control the motor in one of four function modes: CW, CCW, short-brake, and stop. The two motor outputs (A and B) can be separately controlled, and the speed of each motor is controlled via a PWM input signal with a frequency up to 100kHz. The STBY pin should be pulled high to take the motor out of standby mode.
If you are not so familiar with the Arduino, you’d better go through the following tutorials before you start exploring this new product:
Though the OSOYOO 2WD Balance Car Robot will be assembled to retransport, here we will demonstrate how to assemble it for those who need deep development.
Main controller board connection
Installation of motor fixed bracket
Installation of motor, shaft connector and tire
Installation of OSOYOO Balance Robot main controller
Battery box installation (Ours is a box of two batteries)
Robot Frame installation (Ours is a box of two batteries)
OSOYOO 2WD Balance Car Robot is a remotely controlledself balancing arduino robot created with aluminium alloy parts. With only two wheels, it is able to maintain its balance all the time by using his internal sensors and driving the motors. You can control your Robot, making him move or spin, by sending commands via a Smartphone, Tablet while it maintains its balance.
To keep the robot balanced, the motors must counteract the robot falling. This action requires feedback and correcting elements. The feedback element is the MPU6050 gyroscope + accelerometer, which gives both acceleration and rotation in all three axes (MPU6050 I2C basics). The Arduino uses this to know the current orientation of the robot. The correcting element is the motor and wheel combination.
In control theory, keeping some variable (in this case, the position of the robot) steady needs a special controller called a PID (proportional integral derivative). Each of these parameters has “gains”, normally called Kp, Ki, and Kd. PID provides correction between the desired value (or input) and the actual value (or output). The difference between the input and the output is called “error”. The PID controller reduces the error to the smallest value possible by continually adjusting the output. In our Arduino self-balancing robot, the input (which is the desired tilt, in degrees) is set by software. The MPU6050 reads the current tilt of the robot and feeds it to the PID algorithm, which performs calculations to control the motor and keep the robot in the upright position. PID requires that the gains Kp, Ki, and Kd values be “tuned” to optimal values. Engineers use software like MATLAB to compute these values automatically. Unfortunately, we can’t use MATLAB in our case because it would further complicate the project. We will tune the PID values manually instead. Here’s how to do this:
The physical problem that B-ROBOT solves is called the Inverted Pendulum. This is the same mechanism you need to balance an umbrella above your hand. The pivot point is under the center of mass of the object. More information on Inverted Pendulum here. The mathematical solution to the problem is not easy but we don’t need to understand it in order to solve our robot´s balance issue. What we need to know is how should do to restore the robot´s balance so we can implement a Control Algorithm to resolve the problem.
A Control System is very useful in Robotics (an Industrial automation). Basically it´s a code that receives information from sensors and target commands as inputs and creates, in consequence, output signals to drive the Robot actuators (the motors in our example) in order to regulate the system. We are using a PID controller (Proportional + Derivative + Integral). This type of control has 3 constants to adjust kP,kD,kI.
From Wikipedia: “A PID controller calculates an ‘error’ value as the difference between a measured [Input] and a desired setpoint. The controller attempts to minimize the error by adjusting [an Output].”
So, you tell the PID what to measure (the “Input”) ,where you want that measurement to be (the “Setpoint”,) and the variable you wish to adjust to make that happen (the “Output”.) The PID then adjusts the output trying to make the input equal the setpoint.
For reference, a water tank we want to fill up to a level, the Input, Setpoint, and Output would be the level according to the water level sensor, the desired water level and the water pumped into the tank.
kP is the Proportional part and is the main part of the control, this part is proportional to the error. kD is the Derivative part and is applied to the derivative of the error. This part depends on the dynamics of the system (depends on the robot,´s weight motors, inertias…). The last one, kI is applied to the integral of the error and is used to reduce steady errors, it is like a trim on the final output (think in the trim buttons on an RC car steering wheel to make the car go totally straight, kI removes the offset between the target required and the actual value).
More information on PID controller here.
On OSOYOO ROBOT the steering command from the user is added to the motors output (one motor with a positive sign and the other with a negative sign). For example if the user sends the steering command 6 to turn to the right (from -10 to 10) we need to add 6 to the left motor value and subtract 6 from the right motor. If the robot is not moving forward or backwards, the result of the steering command is a spin of the robot.
Above: Top view of the Robot and the commands to the motors
We pre-installed the program for each robot before it was shipped. So you don’t need to upload any sketch into the car and the car can ran as per following steps:
1) Put the car to the ground.
2) Hold it with your hand firmly.
3)Then turn on the power.
4)At the moment the motors begin to move, release the hand gently from the car.
Now the car will self-balance standing in a fixed position. You can test the APP control later.
If you want to use Cell phone App to control this car , read following tutorial:
If you want to overwrite the balance car pre-installed code with your own code, please follow follow these steps:
Download https://osoyoo.com/driver/balance-car-libraries.zip, unzip the file, you will find a folder balance-car-libraries, enter this folder , you will find 6 zip files, load these zip files to Arduino library as following:
For geeks who are very practical, you could modify the source code of this robot to perform new tasks but the communication protocol is also open so you can develop your own IOS, Android, PC remote apps to control your OSOYOO 2WD Balance Car Robot!
Note: When uploading the program, the bluetooth switch beside the bluetooth of the balancing car needs to be put to “OFF”, because the uploading program uses serial communication, occupying the digital port 0 (RX), 1 (TX), so when uploading the program can not be followed by Bluetooth module. Put the bluetooth switch to “ON” after the program is uploaded.
We are looking for some one who will be interested in developing iOS app for Balanbot.
You know we can use a Bluetooth 4.0 Low Energy (BLE) module to connect Balanbot with iOS device (iPhone 4S and above). We will share the protocol and Android code to you, and help you understand the communication method we use. Now you need is just coding for iOS and share it to all the fans later.
What is really important is, we must be open for everyone. Open the hardware and open the software.
When you have done iOS, then tell us and we will share people where the App is.
|1||OSOYOO UNO R3(fully compatible with Arduino UNO R3)||1||Click here to buy|
|2||OSOYOO Balance Robot Shield||1||Click here to buy|
|3||TB6612FNG Driver Module||1||Click here to buy|
|4||MPU6050 Gyroscope Module||1||Click here to buy|
|5||HC-06 Bluetooth Module||1||Click here to buy|
|6||DC Motor||2||Click here to buy|
|7||Motor Bracket||2||Click here to buy|
|8||65mm Wheel||2||Click here to buy|
|9||6mm Motor Axis||2||Click here to buy|
|10||6Pin 20cm Wire||2||Click here to buy|
|11||Battery Box||1||Click here to buy|
|12||2Pin DC Power Connector||1||Click here to buy|
|13||Aluminium Alloy Fixed Plate||1||Click here to buy|
|14||Phillips Screwdriver||1||Click here to buy|
|15||Slot Type Screwdriver||1||Click here to buy|
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