KS0556 Keyestudio 8833 Motor Driver Expansion Board: Difference between revisions
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* Environmental attributes: ROHS | * Environmental attributes: ROHS | ||
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Schematic Diagram: | Schematic Diagram: | ||
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'''Install jumper caps''' | '''Install jumper caps''' | ||
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Then connect motors | Then connect motors | ||
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Test Code | Test Code |
Latest revision as of 16:07, 4 July 2022
Description
The 8833 motor driver expansion board uses PH2.0 terminals and an 8833 motor driver chip driven by the two-channel H bridge whose the largest current can be up to be 1.5A. It also integrates an IR receiver, ultrasonic sensor ports, analog ports, line tracking interfaces and pin headers for BT wifi and servo drivers.
Parameters
- Voltage USB 5V,DC 6-9V
- Current Max current is 3A,the real output is around 1A(2A, when the motor is loaded)
- Max Power
- Max power is 27W; in fact, it is 9W
- Working Temperature: -10~50℃
- Size: 69*56*18mm
- Weight: 25.5g
- Environmental attributes: ROHS
Schematic Diagram:
Install jumper caps
Then connect motors
Test Code
#define ML_Ctrl 4 //define control pins of the left motor #define ML_PWM 6 //define PWM control pins of the left motor #define MR_Ctrl 2 //define control pins of the right motor #define MR_PWM 5 //define PWM control pins of the right motor byte speeds_L = 200; //initial speed of the left motor is 200 byte speeds_R = 200; //initial speed of the right motor is 200 String speeds_l, speeds_r; //receive character strings of PWM,used to transfer into the PWM value void setup() { pinMode(ML_Ctrl, OUTPUT); pinMode(ML_PWM, OUTPUT); pinMode(MR_Ctrl, OUTPUT); pinMode(MR_PWM, OUTPUT); } void loop() { Car_front(); //go forward delay(2000); Car_back(); //go back delay(2000); Car_left(); //turn left delay(2000); Car_right(); //turn right delay(2000); Car_Stop(); //stop delay(2000); } /***************motor running**************/ void Car_back() { digitalWrite(MR_Ctrl, LOW); analogWrite(MR_PWM, speeds_R); digitalWrite(ML_Ctrl, LOW); analogWrite(ML_PWM, speeds_L); delay(10); } void Car_front() { digitalWrite(MR_Ctrl, HIGH); analogWrite(MR_PWM, 255 - speeds_R); digitalWrite(ML_Ctrl, HIGH); analogWrite(ML_PWM, 255 - speeds_L); delay(10); } void Car_left() { digitalWrite(MR_Ctrl, HIGH); analogWrite(MR_PWM, 255 - speeds_R); digitalWrite(ML_Ctrl, LOW); analogWrite(ML_PWM, speeds_L); delay(10); } void Car_right() { digitalWrite(MR_Ctrl, LOW); analogWrite(MR_PWM, speeds_R); digitalWrite(ML_Ctrl, HIGH); analogWrite(ML_PWM, 255 - speeds_L); delay(10); } void Car_Stop() { digitalWrite(MR_Ctrl, LOW); analogWrite(MR_PWM, 0); digitalWrite(ML_Ctrl, LOW); analogWrite(ML_PWM, 0); delay(10); }
Test Result
The motor will rotate clockwise for 2s then anticlockwise for 2s, turn left for 2s, turn right for 2s and stop for 2s.