Microduino-Quadcopter Tutorial

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Revision as of 07:33, 3 December 2015 by 1304410487@qq.com (talk)
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Language: English  • 中文

Outline

Quadcopter is a kind of aircraft that is equipped with four propellers. Similar to the helicopter, it can finish the action of hover and flight. A traditional helicopter uses a main rotor to generate thrust and a tail rotor to offset the torque from the main rotor, namely, locking the tail. While the quadcopter adopts positive and negative propeller design and therefore, needs no extra structure to lock the tail. For propellers distribute symmetrically in the shape of a cross. The No. 1 and No. 2 propellers rotate anticlockwise while the No.3 and No.4 rotate clockwise. When the four propellers generate the same thrust, the anti-torque imposed on the body by the two groups offset, balancing in the vertical direction and making sure flight stability.

According to the user-defined fore and aft direction of the aircraft, the quadcopter can be divided into the cross mode and X mode. The cross mode means that the fore and aft direction points to a certain propeller and the X mode refers to that the fore and aft direction points to the middle of two propellers.
For most aircraft adopting X mode, the X mode is harder to control but more flexible.
Pitchd Roll.jpg

Principle

System Structure

Jiagou.PNG

As the picture shows, the quadopcter consists of a remote controller, a flight controller and four motors. And for the flight controller includes a microcontrller, a remote control signal reciing module, a sensor(A gyroscope, an accelerator, an electronic compass and a GPS module.) and a motor driving module.

Flying Principle

Vertical Motion

Vertical motion includes rising or falling vertically. As the text mentioned previously, the quadcopter can keep balance horizontally by four motors maintaining the same rotation rate. As you can see from picture 2.2.1, if the four motors increase to the same speed, the generated thrust will be large enough to overcome the quadcopter weight and rise, and vice versa. Under the condition of no surrounding interruption, the four motors can generate enough thrust to overcome the weight and therefore, the quadcopter can suspend in the air.

The quadcopter can fly steadily in the vertical direction as long as the four motors maintain the same speed.
Chuizhi-sport.jpg


Front & Lateral Motion

The motor 1 is the head of the aircraft and the motor 2 is the rear.
How does the quadcopter move forward? Get a thrust in the horizontal direction: By increasing the speed of the motor 2 and the thrust increases in the rear. By decreasing the speed of the motor 1, the thrust will get reduced in the head. In this case, the aircraft will move forward. At the same time, by maintaining the speed of the motor 3 and 4 to keep the anti torque balance, the aircraft will fly forward steadily and vice versa.
Since the quadcopter is symmetrical in the middle, the action of controlling the quadcopter forward or laterally is similar. Just keep in mind, the control of the two groups of motors should be reversed while trying to fly the aircraft laterally. For example, by keeping the speed of the motor 1 and 2 the same, increasing the speed of the motor 4 and decreasing the speed of the motor 3, it will generate horizontal thrust to the left and the aircraft will move left.


enter


Right-left-sport.jpg



Yawing Motion

The three kinds of motion mentioned above all happen in the directions of the three axes. Next, we'll introduce the motion around the three axes.

Yawing motion is the rotation in the horizontal direction, nanely rotation around the Z-axis.

During the rotation, it will form an anti-torque opposite to the rotation due to air resistance. Yawing rotation is realized by using the reverse torque. When the aircraft suspends, the speed of the four motors is the same, which can offset torque in both horizontal and vertical direction, and achieve balance. When the speed of the four motors is different, unbalanced anti-torque will cause horizontal rotation and the aircraft will deviate from the route. As the picture shows, by increasing the speed of the motor 1 and 2, and decreasing that of the motor 3 and 4, the clockwise anti-torque generated by the motor 1 and 2 will be larger than the counter clockwise anti-torque generated by the motor 3 and 4, causing clockwise rotation of the aircraft horizontally and generating no vertical displacement when there is no change in the thrust upside.

Pitch and Roll Motion

Pitch motion refers to the rotation in the Y-axis direction while the roll motion refers to the rotation in the X-axis direction.

As the picture shows, by increasing the speed of the motor 1 and decreasing that of the motor 2, and keeping the same of the variable quantity as well as the speed of the motor 3 and 4: The thrust of the head is larger than that of the rear. The unbalanced torque makes the body rise. Similarly, the roll motion is realized by reducing the speed of the motor 1 and increasing that of the motor 2, generating a torque forward.
The principle of the roll and pitch motion is the same due to symmetry in the middle. By keeping the speed of the motor 1 and 2 unchanged, and changing the speed of motor 3 and 4, it'll generate unbalanced torque and make the aircraft rotate around the X-axis direction.


enter


Turn over-sport.jpg



Control Procedure

The remote controller sends out control command, such as take-off or flying left. The control signal is received wirelessly.

  • A remote control signal receiving module receives a control signal, which is converted into PWM, PPM or other signals and then transmitted to the flight controller.
  • Micro controller uses the remote control signal and the sensor's value (the current state of the aircraft, such as acceleration, direction and other information) to control the four motor and achieve the desired action through the PWM.
Since the four-motor combination control can only reach to six directions, which is an under actuated system. So here we must have a flight controller to control the whole system.
In the flight controllers, sensors such as gyroscope and accelerator are dispensable. Micro controller can calculate data from the two sensors, get the current aircraft's attitude and then adjust the rotation rate with algorithms such PID to keep the stability. Sure you can add an electronic compass to get the direction or a GPS module to get the geographic location. Simply speaking, the quadcopter is system with two closed-loops to control---the large loop gets input volume from the remote receiving device and the small loop aquires input volume from the attitude sensor.
Generally speaking, the quadcopter kit includes an aircraft and a remote controller, the two of which controls instructions through the CoreRF transmission.
The quadcopter is composed of a frame, Microduino-CoreRF , Microduino-Motion and other modules. For Microduino-motion, it integrates a three-axis gyroscope + a three-axis accelerator(MPU6040), a magnetic field intensity sensor(HMC5883L) and a digital pressure sensor(BMP180), and have communication through IIC.
MPU6050 is the most important attitude sensor with a three-axis accelerator and a three-axis gyroscope integrated inside, which not only offsets adjustment errors for the combination of a three-axis accelerator and a three-axis gyroscope, and also has a built-in low pass filter.

Buildup and Debugging

Bill of Materials

  • Microduino Equipment
Module Number Function
Microduino-CoreRF 1 Core board
Microduino-USBTTL 1 Program download module
Microduino-Motion 1 Attitude adjustment
Microduino-QuadCopter 1 Quadcopter driver
2.4G Antenna 1
  • Other Equipment
Component Number Function
USB Cable 1
Frame 1
Battery 1 Power supply
Screw 8
Screwdriver 1
四轴物料1.jpg
  • Step 1:Install the four propellers as shown below:
Quostep1.jpg
  • Step 2:Put the battery into the right place on the bottom of the frame.
Quostep2.jpg
  • Step 3:Put the module base into the top of the frame and then insert the wires into the corresponding interface.
Quostep3.jpg
  • Step 4:Connect the antenna to the CoreRF, and then stack them to the Microduino-Motion on the base plate.
Quostep4.jpg
  • Step 5:Connect the base module and the battery with wires.
Quostep5.jpg
  • Step 6:Paste the antenna on the CoreRF to the back of the frame. Congratulations! You just finished the Quadcopter buildup.
Quostep6.jpg
    • Please be noted of the electrode of the two wires, which is "red wire connects to red wire" and "black to black".
    • Make sure all wires are connected well in order to prevent accident while flying.

Program Download Debugging

*Open Arduino IDE, click【File】->【File】, open the program 【MultiWii_RF】 of  MultiWii_CoreRF and select Microduino-CoreRF from the Board under Tools.  
  • Click "Tools", select the board (Microduino-CoreRF), choose COM-XX and then upload the program. After that, please click "√" on the top left and compile, then click and complete the programming of hardware.
Microduino-CoreRF Pitch Roll.jpg

The Microduino-USBTTL download module can only be used in program download, serial debugging and calibration of the Quadcopter, which needn't be stacked at other times.

Quadcopter Adjustment

Preperation

  • Stack the Microduino-CoreRF, Microduino-Motuion and Microduino-USBTTL, then connect them to the base plate.
Microduino QuadCopter Software11.jpg
  • Open the Quadcopter file and select "MultiWiiConf \application.windows32 \MultiWiiConf.exe" to adjust parameters of the Quadcopter.

Note: The file needs to be opened under JAVA development environment or adopt Microduino_Joypad_QuadCopter\java to install.

Sensor Calibration

  • Put the Quadcopter on the desk, click RECONNECT, you'll the curve of the sensor data; Click CALIB_ACC and keep stable of the Quadcopter for 5s, the accelerator will be calibrated; Click WRITE and write the values into the Quadcopter.
  • Click CALIB_MAG and take the Quadcopter to rotate around the modules to calibrate the electronic compass. After that, please put the Quadcopter on a smooth place and click WRITE to write values into the Quadcopter after the compass being balanced.
RF Pitch Roll.jpg

PID Parameter Setting

Click LOAD to load setting files and select pku.mwi to input, as shown below:

Microduino QuadCopter MultiWiiConf4.jpg

Flying Mode Setting


Click SELECT SETTING on the right side of the PID, we can see various flight patterns and a two-dimensional table corresponding to the auxiliary switch. A combination of a switch or multiple switches can be specified as a flight mode. We recommend that players follow the following chart to set the flight mode.

The setting method is to click the left mouse button in the square. The gray square will become white, such as the figure below by clicking three white squares (this should be gray).
This specifies the corresponding flight mode in such a switch position. ANGLE is a steady mode, which helps us to fly the Quadcopter. You can click WRITE to set up the numerical control writing.


Microduino QuadCopter MultiWiiConf ANGLE.jpg

Close the MultiWiiConf serial port after setting up the flight mode, you can take down the Microduino-USBTTL module, completing the assembly and debugging of the whole flight controller.

Troubleshooting with Sensor Values

This method can help to eliminate the problem of aircraft in direction. It can be used to display the correct direction of the control board installation or if there is no proper control board type in "config.h".

  • Tilt to the right side of the fuselage:
    • MAG_ROLL, ACC_ROLL and GYRO_ROLL values increase
    • MAG_Z and ACC_Z values reduce
  • Move the fuselage forward (rear up):
    • MAG_PITCH, ACC_PITCH and GYRO_PITCH values increase
    • MAG_Z and ACC_Z values reduce
  • Turn the fuselage in a clockwise direction (yaw):
    • CYRO_YAW numerical value
  • body level:
    • MAG_Z and ACC_Z values are positive

Remote Controller(Microduino-Joypad)Buildup & Debugging

As it mentioned previously, the remote controller is composed of the control board (Microduino-Joypad), the microcontroller (Microduino-CoreRF), thedisplay module (Microduino-TFT) as well as download and debugging module (Microduino-USBTTL).

  • Microduino Modules
Module Number Function
Microduino-CoreRF 1 Core board
Microduino-USBTTL 1 Program download
Microduino-Joypad 1 Remote controller
Microduino-TFT 1 Display screen
2.4G antenna 1
TFT cable 1
  • Other Equipment
Module Number Function
Rod cover 1
Key cover 1
Nylon nut 1
Nylon screw 1
Screwdriver 1
2.4G antenna 1
TFT cable 1
Joypad物料.jpg

Joypad Buildup &Debugging

Joypad Buildup

  • * Note: The picture is not good because of the effect of the page, please click to see the big picture.
  • Step 1: Download program for the Microduino-CorRF of Joypad.
  • * open the Joypad_RC program in the MultiWii_CoreRF, select the right board and port for program download after the compiler is finished.
  • Step 2: Put the Microduino-TFT on the back of the Microduino-Joypad panel and fixate it with nylon screws, pay attention to the installation direction of Microduino-TFT.
  • Step 3:As it is shown in the picture, you can fixate the Joypad with nylon nuts and screws. Insert the 2.4G antenna into Microduino-CoreRF and connect them to the base plate of Microduino-Joypad.


  • Step 4:Connect Microduino-TFT and Microduino-Joypad with cables.
  • Step 5:Put the switch on the battery to the side of "Dry bat(1.5V)", install the battery (AAA battery) to the battery box; Open the switch on the right side of the Joypad to see if it is powered. If not, please use the USB data cable to connect to the left of the MicroUSB interface to activate the system.
You can also not use the battery. The power supply can also be achieved through a USB cable.


  • Step 6:Use nylon screws to fix the bottom plate and the panel. The remote sensing cap is installed on the rocker, and the button cap is installed on the button. (If the key is not connected well with the upper plate of the key, you can insert the key into the key interface, and then connect with the bottom button.


  • Step 7:You can open the power switch and see if is the power supply is normal.

Joypad Buildup Debugging

  • Key

Press the Key 1 in 4s after opening the Joypad and enter (Config) mode.

Step1进入设置.jpg
  • Enter setting mode

Key1 to Key 4 from the left to the right as shown below:

Step1按键对应.jpg

Note: Make sure setting before entering the OS interface.

  • Joystick calibration

Press Key3 and Key4 to move the cursor. The Key 1 refers to "Return" and the Key 2 refers to "Confirm". Select the first item Joystick Config to enter the setting mode and the Joystick Correct to enter the calibration mode. After that, you'll see interface shown in the third picture. At this time, you can swing the rocker to the upmost and watch the results.

Step2摇杆校准.jpg
  • Select control mode

Press Key1 to return to the main interface and select Protocol Config to enter mode selection. Choose Mode and then Quadcopter mode, press Key 2 to confirm and return.

Step3设置四轴模式.jpg
  • Set communication channel

Return to the secondary menu, choose Quadcopter Channel and press Key 2 to confirm. Select 12, which corresponds to the setting of "#define RF_Channel 12" under MultiWii.

Step4通信通道设置.jpg

At this point, the flight controller and remote control has been assembled and the next is to combine the two and begin to test flying. Not only to practice using the joystick, but also to observe the actual flight of the aircraft to further optimize the parameters of PID.

Overall Debugging

  • Step 1:Open the switch on the Microduino-QuadCopter, put it in a stable place and press the reset button, the system will calibrate the sensor, the LED light will flash on the unfinished board and go out after the calibration. At this time, please wait to unlock. If the LED lamp has been flashing, meaning the four axis is not calibrated well, please re-calibrate.
  • Unlock the Quadcopter
    • Please dial the Joypad remote control switch to the left side (Close the throttle) to prevent the accident caused by Quadcopter speeding up after unlocking. The switch on the right is allocated to the top (Unlock until reaching the maximum value11).
    • Pull the throttle rocker to the lowest level and wait around 2s, and the brightness of the blue LED means successful unlocking. So you can be ready to fly the aircraft, or put the throttle rocker in the middle and operate again. If you try to unlock for many times and still fail, the n please reset the core module, calibrate the sensor and try to unlock again.
Microduino12 Joypad1 config5-quad.jpg
    • And then put the throttle rocker to the bottom and the left upper switch the top (open the throttle switch), For the first use, it is suggested to dial the switch downside and make sure a stable flying.
Microdu1ino12 Joypad1 config5-quad.jpg
  • You only need to gently push the throttle to see the beginning of the four propellers. Keeping speeding up make sure it's flying. A little higher will be OK, just do not close to the ground, and then keep balance through the joystick.
Microduino QuadCopter Remote6.jpg
  • In the upper left is the throttle control switch, you can open (dial above) it to control, you can shake the joystick to observe the change of the screen.
  • The right switch is a precision adjustment switch.
  • The Joystick in the left controls speeding up in the vertical direction.
  • The Joystick in the right controls flying in the vertical direction, which controls left and right flying in the horizontal direction.

Phone Bluetooth Control

  • Get prepared.
    • Make sure the serial port of the BT and the Serial0 (D0,D1) of the Quadcopter as well as the baud rate (115200).
Microduino-BT


    • Download APP.
Qua app.gif
  • Debug.

Connect the BT module onto the calibrated Quadcopter, then put them on a smooth place and wait for Bluetooth connection.

Open the phone Bluetooth and the Quadcopter control APP, you'll see Microduino Bluetooth device.

App microduino.png

Click Microduino, connect the Bluetooth and enter the control interface. After the connection, it'll show "Ready" to remind you to unlock the Quadcopter.

Qua app-ready.png

Unlock the Quadcopter: If the Bluetooth indicator on the bottom of the Quadcopter goes on, it means unlocked successfully. If you see "Unlocked" on the screen, please try to unlock again. After unlocking, the middle rod can push up to speed up and the Quadcopter can fly.

Qua app-ok.png

Code & Notes

Program Description

Joypad Program & Description

Joypad_RC.ino

#include "Arduino.h"
#include "def.h"
#include "time.h"
#include "bat.h"
#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
#include "mpu.h"
#endif
#include "joy.h"
#include "key.h"
#include "data.h"
#include "nrf.h"
#include "mwc.h"
#include "tft.h"
#include "eep.h"

#if defined(__AVR_ATmega128RFA1__)
#include <ZigduinoRadio.h>
#endif

//joypad================================
#include <Joypad.h>
//eeprom================================
#include <EEPROM.h>
//TFT===================================
#include <Adafruit_GFX.h>    // Core graphics library
#include <Adafruit_ST7735.h> // Hardware-specific 
#include <SPI.h>
//rf====================================
#include <RF24Network.h>
#include <RF24.h>

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
//MPU===================================
#include "Wire.h"
#include "I2Cdev.h"
#include "MPU6050_6Axis_MotionApps20.h"
#endif

//spi===================================
#include <SPI.h>

void setup()
{
  // initialize serial communication at 115200 bits per second:

#ifdef Serial_DEBUG
  Serial.begin(115200);
  delay(100);
  Serial.println("========hello========");
#endif

  //---------------
  key_init();

  //---------------
#ifdef Serial_DEBUG
  Serial.println("\n\r EEPROM READ...");
#endif
  eeprom_read();

  //---------------
#ifdef Serial_DEBUG
  Serial.println("\n\r TFT INIT...");
#endif
  TFT_init(true, tft_rotation);

  //---------------
#ifdef Serial_DEBUG
  Serial.println("\n\r TFT BEGIN...");
#endif
  TIME1 = millis();
  while (millis() - TIME1 < interval_TIME1)
  {
    TFT_begin();

    if (!Joypad.readButton(CH_SWITCH_1))
    {
#ifdef Serial_DEBUG
      Serial.println("\n\rCorrect IN...");
#endif

      //---------------
#ifdef Serial_DEBUG
      Serial.println("\n\r TFT INIT...");
#endif
      TFT_init(false, tft_rotation);

      while (1)
      {
        if (!TFT_config())
          break;
      }
#ifdef Serial_DEBUG
      Serial.println("\n\rCorrect OUT...");
#endif

      //---------------
#ifdef Serial_DEBUG
      Serial.println("\n\r EEPROM WRITE...");
#endif
      eeprom_write();
    }
  }

  //---------------
#ifdef Serial_DEBUG
  Serial.println("\n\r TFT CLEAR...");
#endif
  TFT_clear();

  //---------------
#ifdef Serial_DEBUG
  Serial.println("\n\r TFT READY...");
#endif
  TFT_ready();

  //---------------.l
  if (mode_protocol)   //Robot
  {
    SPI.begin();		//Initialize SPI






    radio.begin();
    network.begin(/*channel*/ nrf_channal, /*node address*/ this_node);
  }
  else          //QuadCopter
  {
    unsigned long _channel;
#if !defined(__AVR_ATmega128RFA1__)
    switch (mwc_channal)
    {
      case 0:
        _channel = 9600;
        break;
      case 1:
        _channel = 19200;
        break;
      case 2:
        _channel = 38400;
        break;
      case 3:
        _channel = 57600;
        break;
      case 4:
        _channel = 115200;
        break;
    }
#else if
    _channel = mwc_channal;
#endif
    mwc_port.begin(_channel);
  }

  //---------------
#ifdef Serial_DEBUG
  Serial.println("===========start===========");
#endif

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
  if (mode_mpu) initMPU(); //initialize device
#endif
}

void loop()
{
  //  unsigned long time = millis();

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
  //MPU--------------------------------
  if (mode_mpu)
    getMPU();
#endif

  //DATA_begin------------------------------
  data_begin();

  //DATA_send-------------------------------
  if (millis() < time2) time2 = millis();
  if (millis() - time2 > interval_time2)
  {
    if (mode_protocol) nrf_send();    //Robot
    else data_send();           //QuadCopter

    time2 = millis();
  }

  //Node checking -------------------------------
  vodebug();

  //BAT--------------------------------
  if (time3 > millis()) time3 = millis();
  if (millis() - time3 > interval_time3)
  {
    vobat();
    time3 = millis();
  }

  //TFT------------------------------------
  TFT_run();

  //===================================
  //  time = millis() - time;

  //  Serial.println(time, DEC);    //loop time
}
</cpp>
BAT.h
<source lang="cpp">
int8_t _V_bat = _V_min;

boolean mcu_voltage = true; // 5.0 or 3.3
#define _V_fix 0.2  //fix battery voltage
#define _V_math(Y) (_V_fix+((Y*analogRead(PIN_bat)/1023.0f)/(33.0f/(51.0f+33.0f))))

void vobat()
{
  //_V_bat=10*((voltage*analogRead(PIN_bat)/1023.0f)/(33.0f/(51.0f+33.0f)));
  _V_bat = _V_math(mcu_voltage ? 50 : 33);
  _V_bat = constrain(_V_bat, _V_min, _V_max);

#ifdef Serial_DEBUG
  Serial.print("_V_bat: ");
  Serial.println(_V_bat);
#endif
}

data.h

#include "Arduino.h"

byte inBuf[16];

int16_t outBuf[8] =
{
  Joy_MID, Joy_MID, Joy_MID, Joy_MID, Joy_MID, Joy_MID, Joy_MID, Joy_MID
};

boolean AUX[4] = {0, 0, 0, 0};
//======================================
void data_begin()
{
  Joy();

  if (mode_protocol)   //Robot
  {
    if (!sw_l)
    {
      Joy_x = Joy_MID;
      Joy_y = Joy_MID;
      Joy1_x = Joy_MID;
      Joy1_y = Joy_MID;
    }
  }
  else        //QuadCopter
  {
    if (!sw_l)
      Joy_y = Joy_MID - Joy_maximum;
  }

  //but---------------------------------
  for (uint8_t a = 0; a < 4; a++)
  {
    if (key_get(a, 1))  AUX[a] = !AUX[a];
  }

  outBuf[0] = Joy1_x;
  outBuf[1] = Joy1_y;
  outBuf[2] = Joy_x;
  outBuf[3] = Joy_y;
  outBuf[4] = map(AUX[0], 0, 1, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
  outBuf[5] = map(AUX[1], 0, 1, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
  outBuf[6] = map(AUX[2], 0, 1, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
  outBuf[7] = map(AUX[3], 0, 1, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
}

def.h

#include "Arduino.h"

//DEBUG-----------
#define Serial_DEBUG

//MWC-------------
uint8_t mwc_channal = 11; //RF channel

#if  defined(__AVR_ATmega32U4__)
#define mwc_port Serial1    //Serial1 is D0 D1
#elif defined(__AVR_ATmega128RFA1__)
#define mwc_port ZigduinoRadio    //RF
#else
#define mwc_port Serial    //Serial is D0 D1
#endif

//nRF-------------
#define interval_debug  2000  //Interval for node checking. 
uint8_t nrf_channal = 70;  //0~125

//Battery---------
#define PIN_bat A7	//BAT

#define _V_max 41		//Maximum voltage for the lithium battery: 4.2V
#define _V_min 36		//Minimum voltage for the lithium battery: 3.7V

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
//MPU-------------
#define MPU_maximum 70
#endif


//Time------------
#define interval_TIME1 2000    //setup delay
#define interval_time2 40      //send interval
#define interval_time3 1000    //battery interval

eep.h

#include "Arduino.h"

#include <EEPROM.h>

#define EEPROM_write(address, p) {int i = 0; byte *pp = (byte*)&(p);for(; i < sizeof(p); i++) EEPROM.write(address+i, pp[i]);}
#define EEPROM_read(address, p)  {int i = 0; byte *pp = (byte*)&(p);for(; i < sizeof(p); i++) pp[i]=EEPROM.read(address+i);}

struct config_type
{
  int16_t eeprom_correct_min[4];
  int16_t eeprom_correct_max[4];
  uint8_t eeprom_Joy_deadzone_val;
#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
  boolean eeprom_mode_mpu;
#endif
  boolean eeprom_mode_protocol;
  uint8_t eeprom_mwc_channal;
  uint8_t eeprom_nrf_channal;
  boolean eeprom_tft_theme;
  boolean eeprom_tft_rotation;
  boolean eeprom_mcu_voltage;
};

//======================================
void eeprom_read()
{
  //EEPROM reads the assigned values. 
  config_type config_readback;
  EEPROM_read(0, config_readback);

  for (uint8_t a = 0; a < 4; a++)
  {
    joy_correct_min[a] = config_readback.eeprom_correct_min[a];
    joy_correct_max[a] = config_readback.eeprom_correct_max[a];
  }
  Joy_deadzone_val = config_readback.eeprom_Joy_deadzone_val;

  mode_protocol = config_readback.eeprom_mode_protocol;
#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
  mode_mpu = config_readback.eeprom_mode_mpu;
#endif

  mwc_channal = config_readback.eeprom_mwc_channal;
  nrf_channal = config_readback.eeprom_nrf_channal;
  tft_theme = config_readback.eeprom_tft_theme;
  tft_rotation = config_readback.eeprom_tft_rotation;
  mcu_voltage = config_readback.eeprom_mcu_voltage;
}

void eeprom_write()
{
  // Define structure variable "config" as well as the content of the variable. 
  config_type config;

  for (uint8_t a = 0; a < 4; a++)
  {
    config.eeprom_correct_min[a] = joy_correct_min[a];
    config.eeprom_correct_max[a] = joy_correct_max[a];
  }
  config.eeprom_Joy_deadzone_val = Joy_deadzone_val;

  config.eeprom_mode_protocol = mode_protocol;
#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
  config.eeprom_mode_mpu = mode_mpu;
#endif

  config.eeprom_mwc_channal = mwc_channal;
  config.eeprom_nrf_channal = nrf_channal;
  config.eeprom_tft_theme = tft_theme;
  config.eeprom_tft_rotation = tft_rotation;
  config.eeprom_mcu_voltage = mcu_voltage;

  // Save the variable "config" into EEPROM and write in address 0.
  EEPROM_write(0, config);
}

joy.h

#include "Arduino.h"

#include <Joypad.h>

//Joy-------------
//1000~2000
uint8_t Joy_deadzone_val = 10;
#define Joy_s_maximum 200 //MAX 300
#define Joy_maximum 450 //MAX 500
#define Joy_MID 1500  //1500

boolean mode_mpu, mode_protocol;   //{(0: 0 is mwc, 1 is nrf),(1: 0 is mpu, 1 is no mpu)}

int16_t joy_correct_max[4], joy_correct_min[4];
int16_t Joy_x, Joy_y, Joy1_x, Joy1_y;

int16_t s_lig, s_mic;

boolean Joy_sw, Joy1_sw;

boolean but1, but2, but3, but4;

boolean sw_l, sw_r;

//======================================
int16_t Joy_dead_zone(int16_t _Joy_vol)
{
  if (abs(_Joy_vol) > Joy_deadzone_val)
    return ((_Joy_vol > 0) ? (_Joy_vol - Joy_deadzone_val) : (_Joy_vol + Joy_deadzone_val));
  else
    return 0;
}

int16_t Joy_i(int16_t _Joy_i, boolean _Joy_b, int16_t _Joy_MIN, int16_t _Joy_MAX)
{
  int16_t _Joy_a;
  switch (_Joy_i)
  {
    case 0:
      _Joy_a = Joy_dead_zone(Joypad.readJoystickX());
      break;
    case 1:
      _Joy_a = Joypad.readJoystickY();    //throt
      break;
    case 2:
      _Joy_a = Joy_dead_zone(Joypad.readJoystick1X());
      break;
    case 3:
      _Joy_a = Joy_dead_zone(Joypad.readJoystick1Y());
      break;
  }

  if (_Joy_b)
  {
    if (_Joy_a < 0)
      _Joy_a = map(_Joy_a, joy_correct_min[_Joy_i], 0, _Joy_MAX, Joy_MID);
    else
      _Joy_a = map(_Joy_a, 0, joy_correct_max[_Joy_i], Joy_MID, _Joy_MIN);

    if (_Joy_a < _Joy_MIN) _Joy_a = _Joy_MIN;
    if (_Joy_a > _Joy_MAX) _Joy_a = _Joy_MAX;
  }
  return _Joy_a;
}

void Joy()
{
  sw_l = Joypad.readButton(CH_SWITCH_L);
  sw_r = Joypad.readButton(CH_SWITCH_R);

  //------------------------------------
  //s_lig=Joypad.readLightSensor();
  //s_mic=Joypad.readMicrophone();

  //------------------------------------
  Joy_sw = Joypad.readButton(CH_JOYSTICK_SW);
  Joy1_sw = Joypad.readButton(CH_JOYSTICK1_SW);

  //------------------------------------
  but1 = Joypad.readButton(CH_SWITCH_1);
  but2 = Joypad.readButton(CH_SWITCH_2);
  but3 = Joypad.readButton(CH_SWITCH_3);
  but4 = Joypad.readButton(CH_SWITCH_4);

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
  //====================================
  int16_t y[3];        //MPU---------------------------------
  if (mode_mpu)     //MPU---------------------------------
  {
    for (uint8_t a = 0; a < 3; a++)
    {
      y[a] = ypr[a] * 180 / M_PI;
      if (y[a] > MPU_maximum) y[a] = MPU_maximum;
      if (y[a] < -MPU_maximum) y[a] = -MPU_maximum;
    }
  }
#endif

  if (Joypad.readButton(CH_SWITCH_R))
  {
    Joy_x = Joy_i(0, true, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
    Joy_y = Joy_i(1, true, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
    if (mode_mpu)     //MPU---------------------------------
    {
      Joy1_x = map(y[2], -MPU_maximum, MPU_maximum, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
      Joy1_y = map(y[1], -MPU_maximum, MPU_maximum, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
    }
    else
#endif
    {
      Joy1_x = Joy_i(2, true, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
      Joy1_y = Joy_i(3, true, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
    }
  }
  else
  {
    Joy_x = Joy_i(0, true, Joy_MID - Joy_s_maximum, Joy_MID + Joy_s_maximum);
    Joy_y = Joy_i(1, true, mode_protocol ? Joy_MID - Joy_s_maximum : Joy_MID - Joy_maximum, 
mode_protocol ? Joy_MID + Joy_s_maximum : Joy_MID + Joy_maximum); //  Robot,QuadCopter

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
    if (mode_mpu)     //MPU---------------------------------
    {
      Joy1_x = map(y[2], -MPU_maximum, MPU_maximum, Joy_MID - Joy_s_maximum, Joy_MID + Joy_s_maximum);
      Joy1_y = map(y[1], -MPU_maximum, MPU_maximum, Joy_MID - Joy_s_maximum, Joy_MID + Joy_s_maximum);
    }
    else
#endif
    {
      Joy1_x = Joy_i(2, true, Joy_MID - Joy_s_maximum, Joy_MID + Joy_s_maximum);
      Joy1_y = Joy_i(3, true, Joy_MID - Joy_s_maximum, Joy_MID + Joy_s_maximum);
    }
  }
}

key.h

#include "arduino.h"

uint8_t key_pin[4] = {CH_SWITCH_1, CH_SWITCH_2, CH_SWITCH_3, CH_SWITCH_4}; //Key (1,2,3,4)
 
boolean key_status[4];			//Key 
boolean key_cache[4];		//Detect the key releasing cache. 

void key_init()
{
  for (uint8_t a = 0; a < 4; a++)
  {
    key_status[a] = LOW;
    key_cache[a] = HIGH;
  }
}

boolean key_get(uint8_t _key_num, boolean _key_type)
{
  key_cache[_key_num] = key_status[_key_num];		//Cache as a judge 

  key_status[_key_num] = !Joypad.readButton(key_pin[_key_num]);	//When it is triggered  

  switch (_key_type)
  {
    case 0:
      if (!key_status[_key_num] && key_cache[_key_num])		//After pressing down and releasing
        return true;
      else
        return false;
      break;
    case 1:
      if (key_status[_key_num] && !key_cache[_key_num])		// After pressing down and releasing

        return true;
      else
        return false;
      break;
  }
}

mpu.h

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
#include "Wire.h"
#include "I2Cdev.h"
#include "MPU6050_6Axis_MotionApps20.h"

MPU6050 mpu;

//MPU-------------
#define MPU_maximum 70

// MPU control/status vars
boolean dmpReady = false;  // set true if DMP init was successful
uint8_t mpuIntStatus;   // holds actual interrupt status byte from MPU
uint8_t devStatus;      // return status after each device operation (0 = success, !0 = error)
uint16_t packetSize;    // expected DMP packet size (default is 42 bytes)
uint16_t fifoCount;     // count of all bytes currently in FIFO
uint8_t fifoCache[64]; // FIFO storage cache

// orientation/motion vars
Quaternion q;           // [w, x, y, z]         quaternion container
VectorInt16 aa;         // [x, y, z]            accel sensor measurements
VectorFloat gravity;    // [x, y, z]            gravity vector
float ypr[3];           // [yaw, pitch, roll]   yaw/pitch/roll container and gravity vector

void initMPU()
{
  Wire.begin();
#ifdef Serial_DEBUG
  Serial.println(F("Initializing I2C devices..."));
#endif
  mpu.initialize();
  // verify connection
#ifdef Serial_DEBUG
  Serial.println(F("Testing device connections..."));
#endif
  if (mpu.testConnection())
  {
#ifdef Serial_DEBUG
    Serial.println("MPU6050 connection successful");
#endif
  }
#ifdef Serial_DEBUG
  else
    Serial.println(F("MPU6050 connection failed"));
#endif

  // load and configure the DMP
#ifdef Serial_DEBUG
  Serial.println(F("Initializing DMP..."));
#endif
  devStatus = mpu.dmpInitialize();

  // make sure it worked (returns 0 if so)
  if (devStatus == 0) {
    // turn on the DMP, now that it's ready
#ifdef Serial_DEBUG
    Serial.println(F("Enabling DMP..."));
#endif
    mpu.setDMPEnabled(true);

    mpuIntStatus = mpu.getIntStatus();

    // set our DMP Ready flag so the main loop() function knows it's okay to use it
    //    Serial.println(F("DMP ready! Waiting for first interrupt..."));
    dmpReady = true;

    // get expected DMP packet size for later comparison
    packetSize = mpu.dmpGetFIFOPacketSize();
  }
  else {
    // ERROR!
    // 1 = initial memory load failed
    // 2 = DMP configuration updates failed
    // (if it's going to break, usually the code will be 1)
#ifdef Serial_DEBUG
    Serial.print(F("DMP Initialization failed (code "));
    Serial.print(devStatus);
    Serial.println(F(")"));
#endif
  }
}

void getMPU()
{
  if (!dmpReady) return;
  {
    // reset interrupt flag and get INT_STATUS byte
    mpuIntStatus = mpu.getIntStatus();

    // get current FIFO count
    fifoCount = mpu.getFIFOCount();

    // check for overflow (this should never happen unless our code is too inefficient)
    if ((mpuIntStatus & 0x10) || fifoCount == 1024)
    {
      // reset so we can continue cleanly
      mpu.resetFIFO();
#ifdef Serial_DEBUG
      Serial.println(F("FIFO overflow!"));
#endif
      // otherwise, check for DMP data ready interrupt (this should happen frequently)
    }
    else if (mpuIntStatus & 0x02)
    {
      // wait for correct available data length, should be a VERY short wait
      while (fifoCount < packetSize) fifoCount = mpu.getFIFOCount();

      // read a packet from FIFO
      mpu.getFIFOBytes(fifoCache, packetSize);

      // track FIFO count here in case there is > 1 packet available
      // (this lets us immediately read more without waiting for an interrupt)
      fifoCount -= packetSize;

      // display ypr angles in degrees
      mpu.dmpGetQuaternion(&q, fifoCache);
      mpu.dmpGetGravity(&gravity, &q);
      mpu.dmpGetYawPitchRoll(ypr, &q, &gravity);

      //Serial.print("ypr\t");
      //Serial.print(ypr[0] * 180/M_PI);
      //Serial.print("\t");
      //Serial.print(ypr[1] * 180/M_PI);
      //Serial.print("\t");
      // Serial.println(ypr[2] * 180/M_PI);
    }
  }
}

#endif

mwc.h

#include "Arduino.h"

#if defined(__AVR_ATmega128RFA1__)
#include <ZigduinoRadio.h>
#endif

int16_t RCin[8], RCoutA[8], RCoutB[8];

int16_t p;
uint16_t read16()
{
  uint16_t r = (inBuf[p++] & 0xFF);
  r += (inBuf[p++] & 0xFF) << 8;
  return r;
}

uint16_t t, t1, t2;
uint16_t write16(boolean a)
{
  if (a)
  {
    t1 = outBuf[p++] >> 8;
    t2 = outBuf[p - 1] - (t1 << 8);
    t = t1;
  }
  else
    t = t2;
  return t;
}

typedef  unsigned char byte;
byte getChecksum(byte length, byte cmd, byte mydata[])
{
  //Three parameters including data length, instruction code and the actual data array. 
  byte checksum = 0;
  checksum ^= (length & 0xFF);
  checksum ^= (cmd & 0xFF);
  for (uint8_t i = 0; i < length; i++)
  {
    checksum ^= (mydata[i] & 0xFF);
  }
  return checksum;
}

void data_rx()
{
  //  s_struct_w((int*)&inBuf,16);
  p = 0;
  for (uint8_t i = 0; i < 8; i++)
  {
    RCin[i] = read16();
    /*
    Serial.print("RC[");
     Serial.print(i+1);
     Serial.print("]:");

     Serial.print(inBuf[2*i],DEC);
     Serial.print(",");
     Serial.print(inBuf[2*i+1],DEC);

     Serial.print("---");
     Serial.println(RCin[i]);
     */
    //    delay(50);        // delay in between reads for stability
  }
}

void data_tx()
{
  p = 0;
  for (uint8_t i = 0; i < 8; i++)
  {
    RCoutA[i] = write16(1);
    RCoutB[i] = write16(0);

    /*
    Serial.print("RC[");
     Serial.print(i+1);
     Serial.print("]:");

     Serial.print(RCout[i]);

     Serial.print("---");

     Serial.print(RCoutA[i],DEC);
     Serial.print(",");
     Serial.print(RCoutB[i],DEC);

     Serial.println("");
     */
    //    delay(50);        // delay in between reads for stability
  }
}

/*
if Core RF
[head,2byte,0xAA 0xBB] [type,1byte,0xCC] [data,16byte] [body,1byte(from getChecksum())]
 Example:
 AA BB CC 1A 01 1A 01 1A 01 2A 01 3A 01 4A 01 5A 01 6A 01 0D **
 */
void data_send()
{
  data_tx();

#if !defined(__AVR_ATmega128RFA1__)
  static byte buf_head[3];
  buf_head[0] = 0x24;
  buf_head[1] = 0x4D;
  buf_head[2] = 0x3C;
#endif

#define buf_length 0x10   //16
#define buf_code 0xC8     //200

  static byte buf_data[buf_length];
  for (uint8_t a = 0; a < (buf_length / 2); a++)
  {
    buf_data[2 * a] = RCoutB[a];
    buf_data[2 * a + 1] = RCoutA[a];
  }

  static byte buf_body;
  buf_body = getChecksum(buf_length, buf_code, buf_data);

  //----------------------
#if defined(__AVR_ATmega128RFA1__)
  mwc_port.beginTransmission();
  mwc_port.write(0xaa);
  mwc_port.write(0xbb);
  mwc_port.write(0xcc);
#else
  for (uint8_t a = 0; a < 3; a++) {
    mwc_port.write(buf_head[a]);
  }
  mwc_port.write(buf_length);
  mwc_port.write(buf_code);
#endif
  for (uint8_t a = 0; a < buf_length; a++) {
    mwc_port.write(buf_data[a]);
  }
  mwc_port.write(buf_body);
#if defined(__AVR_ATmega128RFA1__)
  mwc_port.endTransmission();
#endif
}

nrf.h

#include "Arduino.h"

#include <RF24Network.h>
#include <RF24.h>
#include <SPI.h>

// nRF24L01(+) radio attached using Getting Started board
RF24 radio(9, 10);   //ce,cs
RF24Network network(radio);

#define this_node  0	//Set ID for the machine. 
#define other_node 1

//--------------------------------
struct send_a	//Send 
{
  uint32_t ms;
  uint16_t rf_CH0;
  uint16_t rf_CH1;
  uint16_t rf_CH2;
  uint16_t rf_CH3;
  uint16_t rf_CH4;
  uint16_t rf_CH5;
  uint16_t rf_CH6;
  uint16_t rf_CH7;
};

struct receive_a	//Receive 
{
  uint32_t node_ms;
};

//--------------------------------
unsigned long node_clock, node_clock_debug, node_clock_cache = 0;		// Node running time, node response checking time and node time cache. 
//debug--------------------------
boolean node_clock_error = false;	//Node response status 
unsigned long time_debug = 0;		//Timer 


//======================================
void vodebug()
{
  if (millis() - time_debug > interval_debug)
  {
    node_clock_error = boolean(node_clock == node_clock_debug);		//Within a certain, if you find the running time of the node returning unchanged, then it has problem. 

    node_clock_debug = node_clock;

    time_debug = millis();
  }
}


void nrf_send()
{
#ifdef Serial_DEBUG
  Serial.print("Sending...");
#endif

  send_a sen = {
    millis(), outBuf[0], outBuf[1], outBuf[2], outBuf[3], outBuf[4], outBuf[5], outBuf[6], outBuf[7]
  };		//Send out the data, corresponding to the previous array. 
  RF24NetworkHeader header(other_node);
  if (network.write(header, &sen, sizeof(sen)))
  {
#ifdef Serial_DEBUG
    Serial.print("Is ok.");
#endif

    delay(50);
    network.update();
    // If it's time to send a message, send it!
    while ( network.available() )
    {
      // If so, grab it and print it out
      RF24NetworkHeader header;
      receive_a rec;
      network.read(header, &rec, sizeof(rec));

      node_clock = rec.node_ms;		//Assign values for the running time. 
    }
  }
#ifdef Serial_DEBUG
  else
    Serial.print("Is failed.");

  Serial.println("");
#endif
}

tft.h

#include "Arduino.h"

#include <Adafruit_GFX.h>    // Core graphics library
#include <Adafruit_ST7735.h> // Hardware-specific library
#include <SPI.h>

Adafruit_ST7735 tft = Adafruit_ST7735(5, 4, -1);    //cs,dc,rst
//-------Set front(Large, medium, small)
 #define setFont_M tft.setTextSize(2)
#define setFont_S tft.setTextSize(0)

#define tft_width  128
#define tft_height 160

boolean tft_theme = false;  //0 is white,1 is black
boolean tft_rotation = 1;

#define TFT_TOP ST7735_BLACK
#define TFT_BUT ST7735_WHITE

uint16_t  tft_colorA = TFT_BUT;
uint16_t  tft_colorB = TFT_TOP;
uint16_t  tft_colorC = 0x06FF;
uint16_t  tft_colorD = 0xEABF;

#define tft_bat_x 24
#define tft_bat_y 12
#define tft_bat_x_s 2
#define tft_bat_y_s 6

#define tft_font_s_height 8
#define tft_font_m_height 16
#define tft_font_l_height 24

#define _Q_x 33
#define _Q_y 36
#define _W_x 93
#define _W_y 5

#define _Q_font_x 2
#define _Q_font_y (_Q_y - 1)

int8_t tft_cache = 1;

//======================================
void TFT_clear()
{
  tft.fillScreen(tft_colorB);
}

void TFT_init(boolean _init, boolean _rot)
{
  tft_colorB = tft_theme ? TFT_TOP : TFT_BUT;
  tft_colorA = tft_theme ? TFT_BUT : TFT_TOP;

  if (_init) {
    tft.initR(INITR_BLACKTAB);   // initialize a ST7735S chip, black tab
    //  Serial.println("init");
    tft.fillScreen(tft_colorB);

    if (_rot)
      tft.setRotation(2);
  }

  tft.fillRect(0, 0, tft_width, 40, tft_colorA);
  tft.setTextColor(tft_colorB);
  setFont_M;
  tft.setCursor(26, 6);
  tft.print("Joypad");
  setFont_S;
  tft.setCursor(32, 24);
  tft.print("Microduino");
  tft.fillRect(0, 40, tft_width, 120, tft_colorB);
}

void TFT_begin()
{
  setFont_S;

  tft.setTextColor(tft_colorA);
  tft.setCursor(_Q_font_x, 44);
  tft.println("[key1] enter config");

  setFont_M;
  tft.setCursor(4, 150);
  for (uint8_t a = 0; a < (millis() - TIME1) / (interval_TIME1 / 10); a++) {
    tft.print("-");
  }
}

int8_t menu_num_A = 0;
int8_t menu_num_B = 0;
int8_t menu_sta = 0;

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
char *menu_str_a[5] = {
  "Joystick Config", "Protocol Config", "System Config", "Gyroscope Config", "Exit"
};
#else
char *menu_str_a[4] = {
  "Joystick Config", "Protocol Config", "System Config", "Exit"
};
#endif

#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
char *menu_str_b[4][3] = {
  {"Joystick Correct.", "Dead Zone config"},
  {"Mode", "Quadrotor Channel", "nRF24 Channel"},
  {"TFT Theme", "TFT Rotation", "MCU Voltage"},
  {"Gyroscope OFF", "Gyroscope ON"}
};
#else
char *menu_str_b[3][3] = {
  {"Joystick Correct.", "Dead Zone config"},
  {"Mode", "Quadrotor Channel", "nRF24 Channel"},
  {"TFT Theme", "TFT Rotation", "MCU Voltage"},
};
#endif

void TFT_menu(int8_t _num, char *_data)
{
  tft.drawRect(7, 49 + 15 * _num, 114, 16, tft_colorA);
  tft.setCursor(10, 54 + 15 * _num);
  tft.print(_data);
}

void TFT_menu(int8_t _num, int16_t _data)
{
  tft.drawRect(7, 49 + 15 * _num, 114, 16, tft_colorA);
  tft.setCursor(10, 54 + 15 * _num);
  tft.print(_data);
}

void TFT_cursor(int8_t _num)
{
  tft.drawLine(1, 51 + 15 * _num, 4, 56 + 15 * _num, tft_colorA);
  tft.drawLine(4, 57 + 15 * _num, 1, 62 + 15 * _num, tft_colorA);
  tft.drawLine(1, 51 + 15 * _num, 1, 62 + 15 * _num, tft_colorA);
}

boolean return_menu = false;

boolean TFT_config()
{
  tft.setTextColor( tft_colorA);

  if (key_get(0, 1)) {
    menu_sta --;
    tft_cache = 1;

    if (menu_sta <= 0)
      menu_num_B = 0; //zero
  }
  if (key_get(1, 1)) {
    if (return_menu)
      menu_sta --;
    else
      menu_sta ++;
    tft_cache = 1;
  }

  if (menu_sta > 2)
    menu_sta = 2;
  if (menu_sta < 0)
    menu_sta = 0;

  return_menu = false;
  //-------------------------------
  if (tft_cache)
    tft.fillRect(0, 40, tft_width, 100, tft_colorB);

  if (menu_sta == 2) {
    switch (menu_num_A) {
      case 0: {
          switch (menu_num_B) {
            case 0: {
                if (tft_cache)
                {
                  for (uint8_t a = 0; a < 4; a++)
                  {
                    joy_correct_min[a] = 0;
                    joy_correct_max[a] = 0;
                  }
                }
                for (uint8_t a = 0; a < 4; a++) {
                  tft.setCursor(2, 120);
                  tft.print("Move Joystick MaxGear");
                  int16_t _c = Joy_i(a, false, Joy_MID - Joy_maximum, Joy_MID + Joy_maximum);
                  if (_c > joy_correct_max[a]) {
                    tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                    joy_correct_max[a] = _c;
                  }
                  //                  joy_correct_max[a] = constrain(joy_correct_max[a], 0, Joy_maximum);
                  if (_c < joy_correct_min[a]) {
                    tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                    joy_correct_min[a] = _c;
                  }
                  //                  joy_correct_min[a] = constrain(joy_correct_min[a], -Joy_maximum, 0);
                }

                for (uint8_t d = 0; d < 2; d++) {
                  tft.drawFastHLine(12 + 70 * d, 80, 33, tft_colorA);
                  tft.drawFastVLine(28 + 70 * d, 64, 33, tft_colorA);
                  //                tft.fillRect(2, 90-4, 20, 12, tft_colorB);
                  tft.drawCircle(44 + 70 * d, 80, map(joy_correct_min[0 + 2 * d], 0, -512, 1, 10), tft_colorA);
                  tft.drawCircle(12 + 70 * d, 80, map(joy_correct_max[0 + 2 * d], 0, 512, 1, 10), tft_colorA);
                  tft.drawCircle(28 + 70 * d, 64, map(joy_correct_min[1 + 2 * d], 0, -512, 1, 10), tft_colorA);
                  tft.drawCircle(28 + 70 * d, 96, map(joy_correct_max[1 + 2 * d], 0, 512, 1, 10), tft_colorA);
                }
                return_menu = true;
              }
              break;
            case 1: {
                if (key_get(2, 1)) {
                  Joy_deadzone_val--;
                  tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                }
                if (key_get(3, 1)) {
                  Joy_deadzone_val++;
                  tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                }
                Joy_deadzone_val = constrain(Joy_deadzone_val, 0, 25);

                TFT_menu(0, Joy_deadzone_val);
                TFT_cursor(0);
                return_menu = true;
              }
              break;
          }
        }
        break;

      case 1: {
          switch (menu_num_B) {
            case 0: {
                char *menu_str_c[2] = { "Quadro.", "nRF24"};
                if (key_get(2, 1) || key_get(3, 1)) {
                  mode_protocol = !mode_protocol;
                  tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                }
                for (uint8_t c = 0; c < 2; c++) {
                  TFT_menu(c, menu_str_c[c]);
                }

                TFT_cursor(mode_protocol);
                return_menu = true;
              }
              break;
            case 1: {
#if !defined(__AVR_ATmega128RFA1__)
                char *menu_str_c[5] = {"9600", "19200", "38400", "57600", "115200"};
#endif
                if (key_get(2, 1)) {
                  mwc_channal--;
                  tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                }
                if (key_get(3, 1)) {
                  mwc_channal++;
                  tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                }

#if !defined(__AVR_ATmega128RFA1__)
                mwc_channal = constrain(mwc_channal, 0, 4);
                TFT_menu(0, menu_str_c[mwc_channal]);
#else
                mwc_channal = constrain(mwc_channal, 11, 26);
                TFT_menu(0, mwc_channal);
#endif
                TFT_cursor(0);
                return_menu = true;
              }
              break;

            case 2: {
                if (key_get(2, 1)) {
                  nrf_channal--;
                  tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                }
                if (key_get(3, 1)) {
                  nrf_channal++;
                  tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                }
                nrf_channal = constrain(nrf_channal, 0, 125);

                TFT_menu(0, nrf_channal);
                TFT_cursor(0);
                return_menu = true;
              }
              break;
          }
        }
        break;
      case 2: {
          switch (menu_num_B) {
            case 0: {
                tft_theme = !tft_theme;
                TFT_init(true, tft_rotation);
                tft_cache = 1;
                tft.setTextColor(tft_colorA);
                menu_sta --;
              }
              break;
            case 1: {
                tft_rotation = !tft_rotation;
                TFT_init(true, tft_rotation);
                tft_cache = 1;
                tft.setTextColor(tft_colorA);
                menu_sta --;
              }
              break;
            case 2: {
                char *menu_str_c[2] = { "3.3V", "5.0V"};
                return_menu = true;

                if (key_get(2, 1) || key_get(3, 1)) {
                  mcu_voltage = !mcu_voltage;
                  tft.fillRect(0, 40, tft_width, 100, tft_colorB);
                }

                TFT_cursor(mcu_voltage);

                for (uint8_t c = 0; c < 2; c++) {
                  TFT_menu(c, menu_str_c[c]);
                }
                //                tft.fillRect(0, 40, tft_width, 100,tft_colorB);
              }
              break;
          }

        }
        break;

#if !(defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__))
      case 3: { //mpu
          mode_mpu = menu_num_B;
          tft_cache = 1;
          menu_sta = 0; //back main menu
          menu_num_B = 0; //zero
        }
        break;
#endif
    }
  }

  /*
    Serial.print(menu_sta);
    Serial.print(",");
    Serial.print(menu_num_A);
    Serial.print(",");
    Serial.println(menu_num_B);
  */
  //----------------------------
  if (menu_sta == 1) {
#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
    int8_t meun_b_max[5] = {1, 2, 2, 1, 0};
#else
    int8_t meun_b_max[4] = {1, 2, 2, 0};
#endif
    if (!meun_b_max[menu_num_A])
      return false;
    else {
      if (key_get(2, 1)) {
        tft.fillRect(0, 40, 5, 100, tft_colorB);
        menu_num_B--;
      }
      if (key_get(3, 1)) {
        tft.fillRect(0, 40, 5, 100, tft_colorB);
        menu_num_B++;
      }
      menu_num_B = constrain(menu_num_B, 0, meun_b_max[menu_num_A]);

      TFT_cursor(menu_num_B);

      if (tft_cache) {
        for (uint8_t b = 0; b < (meun_b_max[menu_num_A] + 1); b++) {
          TFT_menu(b, menu_str_b[menu_num_A][b]);
        }
      }
    }
  }

  //main menu
  if (menu_sta == 0) {
    //custer
    if (key_get(2, 1)) {
      tft.fillRect(0, 40, 5, 100, tft_colorB);
      menu_num_A--;
    }
    if (key_get(3, 1)) {
      tft.fillRect(0, 40, 5, 100, tft_colorB);
      menu_num_A++;
    }
#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
    menu_num_A = constrain(menu_num_A, 0, 4);
#else
    menu_num_A = constrain(menu_num_A, 0, 3);
#endif

    TFT_cursor(menu_num_A);

    if (tft_cache) {
#if defined(__AVR_ATmega1284P__) || defined(__AVR_ATmega644P__) || defined(__AVR_ATmega128RFA1__)
      for (uint8_t a = 0; a < 5; a++) {
#else
      for (uint8_t a = 0; a < 4; a++) {
#endif
        TFT_menu(a, menu_str_a[a]);
      }
    }
  }

  if (tft_cache) {
    //BACK
    tft.fillCircle(12, 149, 8, tft_colorA);
    tft.drawLine(11, 145, 7, 149, tft_colorB);
    tft.drawLine(7, 149, 11, 153, tft_colorB);
    tft.drawLine(7, 149, 17, 149, tft_colorB);
    //ENTER
    tft.fillCircle(12 + 20, 149, 8, tft_colorA);
    tft.drawLine(10 + 20, 146, 7 + 20, 149, tft_colorB);
    tft.drawLine(7 + 20, 149, 10 + 20, 152, tft_colorB);
    tft.drawLine(7 + 20, 149, 15 + 20, 149, tft_colorB);
    tft.drawLine(15 + 20, 146, 15 + 20, 149, tft_colorB);
    //PREV
    tft.fillCircle(127 - 12, 149, 8, tft_colorA);
    tft.drawLine(127 - 12, 153, 127 - 8, 149, tft_colorB);
    tft.drawLine(127 - 12, 153, 127 - 16, 149, tft_colorB);
    tft.drawLine(127 - 12, 153, 127 - 12, 145, tft_colorB);
    //NEXT
    tft.fillCircle(127 - 32, 149, 8, tft_colorA);
    tft.drawLine(127 - 32, 145, 127 - 28, 149, tft_colorB);
    tft.drawLine(127 - 32, 145, 127 - 36, 149, tft_colorB);
    tft.drawLine(127 - 32, 145, 127 - 32, 153, tft_colorB);
  }
  tft_cache --;
  if (tft_cache < 0)  tft_cache = 0;

  return true;
}

//------------------
#define _C_x_S  (_Q_x + 1)
#define _C_x_M  (_Q_x + ((_W_x + 1) / 2))
#define _C_x_E  (_Q_x + _W_x - 1)

char *NAME[8] = {
  "ROLL", "PITCH", "YAW", "THROT", "AUX1", "AUX2", "AUX3", "AUX4"
};

void TFT_ready()
{
  tft.fillRect(0, 0, 128, 26, tft_colorA);

  tft.drawRect(tft_width - tft_bat_x - tft_bat_x_s - 2, 2, tft_bat_x, tft_bat_y, tft_colorB);
  tft.drawRect(tft_width - tft_bat_x_s - 2, 2 + (tft_bat_y - tft_bat_y_s) / 2, tft_bat_x_s, tft_bat_y_s, tft_colorB);

  tft.setTextColor(tft_colorB);
  setFont_S;

  tft.setCursor(_Q_font_x, 3);
  tft.print(mode_protocol ? "nRF24" : "Quadr");
  tft.print(" CHAN.");
  tft.print(mode_protocol ? nrf_channal : mwc_channal);
  tft.setCursor(_Q_font_x, 16);
  tft.print("Time:");

  tft.setTextColor(tft_colorA);
  for (uint8_t a = 0; a < 8; a++) {
    tft.setCursor(_Q_font_x, _Q_font_y + a * 15);
    tft.print(NAME[a]);
    //------------------------------------------
    tft.drawRect(_Q_x, _Q_y + a * 15, _W_x, _W_y, tft_colorA);
  }
}

boolean _a = false, _b = false;
void TFT_run()
{
  if (outBuf[3] > (Joy_MID - Joy_maximum)) {
    if (_a) {
      Joy_time[0] = millis() - Joy_time[1];
      _a = false;
    }
    Joy_time[1] = millis() - Joy_time[0];
  }
  else
    _a = true;

  if (!_b && ((Joy_time[1] / 1000) % 2)) {
    _b = !_b;
    tft.fillRect(_Q_font_x + 30, 16, 50, 7, tft_colorA);
    tft.setTextColor(tft_colorB);
    tft.setCursor(_Q_font_x + 30, 16);
    tft.print((Joy_time[1] / 1000) / 60);
    tft.print("m");
    tft.print((Joy_time[1] / 1000) % 60);
    tft.print("s");
  }
  _b = boolean((Joy_time[1] / 1000) % 2);

  //battery------------------
  tft.fillRect(tft_width - tft_bat_x - 3, 3, map(_V_bat, _V_min, _V_max, 0, tft_bat_x - 2) , tft_bat_y - 2, tft_colorB);
  tft.fillRect(tft_width - tft_bat_x - 3 + map(_V_bat, _V_min, _V_max, 0, tft_bat_x - 2), 3, 
map(_V_bat, _V_min, _V_max, tft_bat_x - 2, 0) , tft_bat_y - 2,tft_colorA);

  for (uint8_t a = 0; a < 8; a++) {
    int8_t _C_x_A0, _C_x_B0, _C_x_A, _C_x_B, _C_x_A1, _C_x_B1;
    int8_t _C_x;

    if (outBuf[a] < Joy_MID) {
      _C_x = map(outBuf[a], Joy_MID - Joy_maximum, Joy_MID, _C_x_S, _C_x_M);

      _C_x_A0 = _C_x_S;
      _C_x_B0 = _C_x - _C_x_S;

      _C_x_A = _C_x;
      _C_x_B = _C_x_M - _C_x;

      _C_x_A1 = _C_x_M;
      _C_x_B1 = _C_x_E - _C_x_M;
    } else if (outBuf[a] > Joy_MID) {
      _C_x = map(outBuf[a], Joy_MID, Joy_MID + Joy_maximum, _C_x_M, _C_x_E);

      _C_x_A0 = _C_x_S;
      _C_x_B0 = _C_x_M - _C_x_S;

      _C_x_A = _C_x_M;
      _C_x_B = _C_x - _C_x_M;

      _C_x_A1 = _C_x;
      _C_x_B1 = _C_x_E - _C_x;
    } else {
      _C_x_A0 = _C_x_S;
      _C_x_B0 = _C_x_M - _C_x_S;

      _C_x_A = _C_x_M;
      _C_x_B = 0;

      _C_x_A1 = _C_x_M;
      _C_x_B1 = _C_x_E - _C_x_M;
    }
    tft.fillRect(_C_x_A0,  _Q_y + a * 15 + 1, _C_x_B0, _W_y - 2, tft_colorB);
    tft.fillRect(_C_x_A,  _Q_y + a * 15 + 1, _C_x_B, _W_y - 2, tft_colorC);
    tft.fillRect(_C_x_A1,  _Q_y + a * 15 + 1, _C_x_B1, _W_y - 2, tft_colorB);

    tft.fillRect(_C_x_M,  _Q_y + a * 15 - 1, 1, _W_y + 2, tft_colorD);
  }
  //netsta------------------
  tft.fillRect(0, 158, 128, 2, node_clock_error ? tft_colorD : tft_colorC);
}

time.h

#include "Arduino.h"

//unsigned long time;
unsigned long TIME1;            //setup delay
unsigned long time2; //send data
unsigned long time3; //battery
unsigned long Joy_time[2] = {0, 0}; //joy

Caution

  • For installation
    • The four propellers must be installed in order.
    • Electrode for the Lithium battery. Please be noted that the red wire points to the positive pole and the black wire points to the negative pole.
  • For parameter adjustment
    • Please refer to the fourth section of the content to adjust the aircraft PID parameters and flight mode, which can be modified according to the recommended configurations. If you want to change PID parameters manually, please choose to change one parameter each time.
  • About debugging
    • Please adjust the Microduino-Joypad and the quadcopter before flying.
  • About flying control
    • Make sure flying in an empty place.
    • Please put the switch on the top left before unlocking the remote controller(Shut off the throttle) and set the throttle to the lowest before flying for fear of the take-off accident.
  • Please cut off the power supply of the Quadcopter firstly and then the power supply of the remote controller or it'll make the Quadcopter out of control.