Ardumower PCB

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Version vom 23. April 2015, 22:02 Uhr von Autega (Diskussion | Beiträge) (Download and flash Arduino code)

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Abstract

This page describes how to assemble the Ardumower PCB, flash the Arduino and configure the robot mower.

The controller is built around a ready microcontroller board (Arduino Mega 2560 using 54 I/O pins).

Needed modules

All modules can be purchased as complete kits via the shop Shopping.png .

  • Main functions
    • Arduino cable (female-female and male-female jumper cable)
    • Arduino Mega 2560 (or Arduino Due)
    • DC voltage step-down module
    • dual motor driver module with integrated current sensor (2 wheel motors)
    • current sensor module
    • motor driver module with integrated current sensor (mower motor)
    • Resistors, Capacitors, Fuse
    • Piezo buzzer, button, ON/OFF switch
  • Perimeter sender (optional)
    • Arduino Nano
    • DC voltage step-down module
    • motor driver module with integrated current sensor
  • Perimeter receiver (optional)
    • pre-amplifier module
    • Capacitor, Receiver coil
  • Additional modules
    • ultrasonic sensor module (optional)
    • IMU module (gyro, accel. compass) (optional)
    • realtime clock module (optional)
    • Bluetooth module (for phone control)

PCB

The printed circuit board (PCB) connects all electronic modules. The PCB is made with the following design parameters:

  • PCB dimensions 241x114mm
  • All modules (motor driver, Bluetooth, etc.) can be soldered (or plugged) on the PCB (modules are available in the Ardumower shop)
  • Uses the Arduino Mega 2560
  • Optional: can use Arduino Due via additional adapter PCB
  • Optional: integrated charging circuit (current limiting)
  • All connections are available on connectors as well as +5V and GND
  • Max. trace current (for motors): 8A

Click here for photos: https://github.com/Ardumower/ardumower/tree/master/pcb/megashield_svn_0.5/Platinenbilder

More photos to come...

Schematics

A schematics says more than a thousand words...

Click here for latest version (PDF): https://github.com/Ardumower/ardumower/blob/master/pcb/megashield_svn_0.5/ardumower%20mega%20shield%20svn.pdf

The schematics and PCB files were created with KiCad. They can be downloaded from github and can be edited by open source KiCAD software.

PCB jumpers

Feature used YES NO Comment
Integrated charging control via adjustable

voltage regulator (LM350T) with potentiometer

for adjustable charging voltage (recommended: NO)

D7: DIODE

D3: DIODE

C1, C4, U4, RV1: used

D7: SHORT-CIRCUIT

D3: SHORT-CIRCUIT

C1, C4, U4, RV1: not used

Do not use if using external battery charger
External power while charging (recommended: NO) JP6: CLOSE

JP7: OPEN

D4: DIODE

C5: not used

JP6: OPEN

JP7: CLOSE

D4: SHORT-CIRCUIT

C5: used

Use to power your PCB from externally (disconnect battery from PCB) while charging
Arduino controlled charge relay (recommended: YES) JP4: CLOSE

JP5: OPEN

JP4: OPEN

JP5: CLOSE

Use for Arduino controlled charge relay (not automatic charging)
Arduino Due (3.3V I/O) LP0, ..., LP15: OPEN LP0, ..., LP15: CLOSE Do not use if using Arduino Mega
Bluetooth VCC=3.3V JP8: OPEN

JP9: CLOSE

JP8: CLOSE

JP9: OPEN

Many latest modules use 3.3V
Bluetooth programming mode JP2: CLOSE JP2: OPEN Use for reprogramming baud rate etc.

PCB modules

Module Feature Pinout Optional Comment
U1 DC/DC converter (10V) GND, Vout, Vin, GND No
U2 Bluetooth (HC-05) VCC, GND, TXD, RXD, Key, LED Yes
U3 Current sensor (charging) VCC, GND, OUT, IP+, IP-5 Yes
U4 Charge control (LM350T) AJD, OUT, IN Yes
U5 Current sensor (charging) VCC, GND, OUT, IP+, IP-5 Yes
U6 DC/DC converter (3.3V) GND, Vout, Vin, GND No
U7 DC/DC converter (5V) GND, Vout, Vin, GND No
U8 Realtime clock (DS1307) Batt, GND, VCC, SDA, SCL, DS, SQ Yes
U9 Wifi (ESP8266) TX, CH_PD, Reset, VCC, GND, GP_IO2, GP_IO0, RX Yes
U10 Level shifter 5V->3V (Arduino Due) Yes
U11 Wifi (ESP8266) TX, CH_PD, Reset, VCC, GND, GP_IO2, GP_IO0, RX Yes alternative mount position

PCB connectors

Connector Feature Pinout Optional Comment
P1 Sonar center (HC SR-04) 5V, GND, Trigger, Echo Yes
P2 Sonar right (HC SR-04) 5V, GND, Trigger, Echo Yes
P3 Sonar left (HC SR-04) 5V, GND, Trigger, Echo Yes
P4 reserved Yes
P5 IMU (gyro,acceleration,compass) (GY-80) Yes
P6 Lawn sensor Yes
P7 Status LEDs Yes
P8 Odometry right Yes
P9 Odometry left Yes
P10 GPS (GY-NEO6MV2) Yes
P11 Bumper GND, GND, right, left Yes
P12 Perimeter coil (center or left) 5V, GND, perimeter Yes
P13 R/C remote control 5V, GND, mow, steer, speed, switch Yes
P14 Measurement points 5V, GND, (Depending on JP15: 3.3V, 5V or Arduino 3.3V) Yes
P15 Wheel motor left M1OUT1, M1OUT2 No
P16 Optional motor driver input Yes Do not connect
P17 Optional motor driver input Yes Do not connect
P18 Wheel motor right M2OUT1, M2OUT2 No
P19 Tilt sensor 5V, GND, tilt Yes
P20 Button (Start/Stop) No
P21 Drop sensor right Yes
P22 Reserved Yes
P23 Reserved Yes
P24 Reserved Yes
P25 Reserved Yes
P26 Reserved Yes
P27 Reserved Yes
P28 Reserved Yes
P29 Reserved Yes
P30 Perimeter coil right Yes
P31 Drop sensor left Yes
P32 GND Yes
P33 5V Yes
P34 3.3V Yes
P35 Mower motor RPM Yes
P36 Reserved Yes
P37 Mower motor No
P38 Reserved Yes
P39 Reserved Yes
P40 User switches Yes
P41 Rain sensor Yes
P42 Charging pins Yes
P43 Battery (24V) No
P44 Wifi module (ESP8266) Yes
P45 Reserved Yes
P46 Reserved Yes

Power supply

Please also read the section 'Voltages' under Motor driver for more information on motor voltages.

It is recommended to use a voltage step-down converter (e.g. module using LM2596) to generate the 5V voltage for the Arduino and all additional modules. Before connecting, set the voltage of the converter to 5V.

Warning.pngWarning : never connect more than 5V on the Arduino 5V pins, or you will damage the Arduino. Therefore, always measure the 5V voltage before connecting it to the Arduino 5V pin! All components together (as shown in the schematics) need about 5W power.

Download and flash Arduino code

NOTE: If you have never worked with Arduino before, read our 'Arduino first steps' introduction.

You have two options:

Finally, download and start the Arduino IDE to flash the code to your Arduino.

Arduino Version: It is very Importent that you use the Arduino IDE version 1.6.3 or above AND select the right Board (Mega 2560 or Due).

Warning.png Note: Always verify that the pin configuration in your Arduino code (config.h/mower.cpp) matches your actual circuit!

First-time calibration

Wheel motors

Warning.pngSecurity note: For security reasons, always remove mower blades in your first tests!

Initially, you should verify that the wheel motors are controlled correctly and in the right direction. The software offers a diagnostic mode. Open the serial console in the Arduino IDE (CTRL+SHIFT+M) and set the baudrate to 19200. The motor and sensor values should appear constantly:

    20 OFF  spd    0    0    0 sen    0    0    0 bum    0    0 son...
    21 OFF  spd    0    0    0 sen    0    0    0 bum    0    0 son...
    22 OFF  spd    0    0    0 sen    0    0    0 bum    0    0 son...
    23 OFF  spd    0    0    0 sen    0    0    0 bum    0    0 son...
    24 OFF  spd    0    0    0 sen    0    0    0 bum    0    0 son...
    ...

Now, press the key ‘t’ on the keyboard, and confirm using ENTER. The diagnostic mode should appear, and you can test your motors.

ADC calibration

Run the ADC calibration once (either via serial console or "pfodApp->ADC Calibration"), so that the received signal is symmetric around zero.

Diagnostics/troubleshooting

Each time a sensor triggers, its corresponding sensor counter increases. The sensor trigger counters as well as the current sensor values can be viewed on the serial console. The following values are shown for the trigger counters in the serial console:

  1. Time of state machine's state (ms)
  2. loop()-counts per second
  3. choosen Verbose-Mode (0=counter readings/1=current values/2=current values)
  4. current state machine state (FORW, REV, ROLL etc.)
  5. drive home? (1/0)
  6. "spd" - Control/speed motors: left (PWM), right (PWM), mower (RPM)
  7. "sen" - Current limit exceeded counter motors: left, right, mower
  8. "bum" - bumper counter: left, right
  9. "son" - Ultrasonic-distance threshold exceeded (counter)
  10. "pit/roll" - Tilt (computed by acceleration sensor)
  11. "com" - compass course
  12. "per" - Perimeter loop detected: counter
  13. "bat" - Battery voltage
  14. "chg" - Charging current

Using the key 'v', you can toggle between sensor trigger counters and current sensor values.

Warning.png Additionally, you can use pfodApp (Android) to plot the sensors (trigger counters and current values) over time. This allows you to wirelessly monitor your robot mower for error diagnostics. It is highly recommended.

Starting the mower

To start the mower, you need to add a button and a buzzer:

pinButton —o Button o— GND (button for ON/OFF)
pinBuzzer —o Buzzer o— GND (Piezo buzzer)

Now, press the button as long as you hear the beeps:

Mode (press button for x beeps):

1 beeps : Normal mowing (using blade modulation if available)
2 beeps : Normal mowing (without blade modulation)
3 beeps : Drive by model remote control (RC)
4 beeps : Drive without mowing
5 beeps : Find perimeter and track it

Error counter / error beeps

If there's a communication problem or another serious problem, the error counter increases. The error counter can be monitored via pfodApp. Additionally, the robot mower will beep when started.

I2C bus / error beeps

Several components (Arduino Nano, RTC, IMU, etc.) are communicating via the I2C bus (SDA/SCL wires). These wires should be very short (maybe even twisted) and they should be far away from DC converter and motor drivers. If there's a communication problem, the error counter will increase and robot will beep when started. The error counter can be monitored via pfodApp.

Config files

You can adapt the Ardumower code to your own robot mower hardware using the config file:

  • config.h (old v9.0.3)
  • mower.cpp (SVN version)

Config files translate the commands of the main program into the specific hardware (i.e. actuators and sensors) - that allows us to adapt the main program to different robot mowers:

Example:

The main program wants to drive the left wheel motor with speed 100. The chosen robot config file is called by the main program with this command:

setActuator(ACT_MOTOR_LEFT, 100)

The actual config file will execute this command by calling the specific motor driver:

setL298N(pinMotorLeft, pinMotorLeftPWM, 100)

To enable a sensor, remove the comment of that line. To disable a sensor, comment the line with a double slash (//).

pfodApp

The configuration of the robot mower can be set via Android phone (pfodApp).

Important: If you flashed a new version, reset all settings via pfodApp once (Settings->Factory reset). This will delete all existing settings. Old settings can produce malfunction if the internal settings format has changed.

Further links