Microduino 四轴飞行器教程
Language | English |
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概述四旋翼飞行器,又称为四旋翼直升机,顾名思义,是一种具备4个螺旋桨的飞行器,与直升机类似,可以完成空中悬停、飞行的动作。传统直升机会用一个主桨来产生推力,用一个尾桨来抵消主桨产生的扭矩(即锁尾),而四旋翼飞行器对角螺旋桨采用正反桨设计,从而不需要额外的机构进行“锁尾”。4个螺旋桨呈十字形对称分布,1和2 号桨逆时针转动,而3和4号桨顺时针转动,但4个螺旋桨产生的推力相同时,两组正反桨对机身所施加的反扭矩两两抵消,使得绕垂直方向旋转的反扭矩平衡,从而确保了航向的稳定。 | |||||||||||||||||||||||||||||||||||||||||||||
根据飞行器自定义的首尾方向,可以将四旋翼飞行器分为十字模式和X字模式两种。十字模式意味着首尾的方向会指向某个螺旋桨,而X字模式则是指首尾方向指向两个螺旋桨中间。 | |||||||||||||||||||||||||||||||||||||||||||||
大多数飞行器采用的是X字模式。X字模式相对于十字模式来说,控制起来更加困难,但动作的灵活性会更高。
原理系统架构如图是四旋翼飞行器的结构简图。飞行器包括主要包括遥控器(航模遥控)、飞行控制器以及四个电机组成。而飞行控制器又包括微控制器、遥控信号接收模块、传感器模块(陀螺仪、加速度计、电子罗盘和GPS定位模块)和电机驱动模块。 飞行原理垂直运动即飞行器垂直上升或下降。正如前文所说的,四个电机保持在同一转速,就能够在水平方向上保持稳定。如图2.2.1所示,如果四个电机增加到在同一个转速,产生的推力足以克服飞行器自身的重力,便能够上升;反之,如果四个电机同时降低到同一个速度,产生的推力无法克服飞行器的重力,便可以下降。如果外界没有其他的扰动,四个电机产生的推力恰好克服飞行器的重力,这样,飞行器就可以悬停在空中。 | |||||||||||||||||||||||||||||||||||||||||||||
只要让四个电机保持在相同转速,便能够让飞行器平稳地垂直运动,相对来说比较简单。
前后运动和侧向运动电机1为飞行器头部,而电机2为飞行器尾部。
偏航运动前面介绍的三种运动都是空间三个轴上的平移,接下来要介绍的三种运动是绕着三轴的旋转。 | |||||||||||||||||||||||||||||||||||||||||||||
偏航运动就是在水平方向上的左右转动,即绕着Z轴的旋转。旋翼在转动的过程中,由于空气阻力的作用,会形成与转动方向相反的反扭矩。偏航运动就是利用反扭矩实现的。当飞行器悬停时,4个电机的转速相同,两组正反扭矩相互抵消,维持平衡。当四个电机转速不完全相同时,不平衡的反扭力会引起四旋翼飞行器水平转动,从而实现偏航运动。如图所示,提升电机1和2的转速,同时降低电机3和4的转速,1和2 电机产生的顺时针反扭矩大于3和4电机产生的逆时针反扭矩,而且总的向上推力没有发生变化,于是机身在水平面上顺时针转动,又不会出现垂直位移。逆时针转动正好相反。
俯仰运动和滚转运动俯仰运动是指在Y轴上的旋转,而滚转运动则是在X轴上旋转。 | |||||||||||||||||||||||||||||||||||||||||||||
如图所示,提升电机1的转速,降低电机2的转速,两者转速的变化量应该一样,同时保持电机3和4转速不变。机身头部的推力大于尾部的推力,不平衡的力矩使得机身仰起。同样的,俯身运动则是降低电机1的转速,而提升电机2的转速,产生一个向前倾的力矩。 | |||||||||||||||||||||||||||||||||||||||||||||
同样是因为中心对称的缘故,滚转运动与俯仰运动的原理一样。维持电机1和2的转速不变,改变电机3和4的转速,产生不平衡的力矩,使得机身绕着X轴做出滚转的运动。
控制流程遥控器发出控制命令,比如起飞、向左飞等等,控制信号通过无线接收
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因为四旋翼飞行器的四个电机组合控制才能实现6个方向的运动,是一个欠驱动系统,必须要有一个飞行控制器来控制整个系统。 | |||||||||||||||||||||||||||||||||||||||||||||
在飞行控制器中,传感器,如陀螺仪和加速度计,是必须的。微控制器计算这两个传感器所传来的数据,获得当前飞行器的姿态,然后通过PID等算法调整电机的转速,以保持飞行器的稳定。当然还可以加入电子罗盘掌握机身的方向,加入GPS模块确定飞行器的地理位置。所以简单来说,四旋翼飞行器是一个具备两个闭环控制的系统,大环由遥控接收设备注入输入量,小环由姿态传感器注入输入量。 | |||||||||||||||||||||||||||||||||||||||||||||
当然,这个过程中也有一些技术细节需要设计,比如传感器读入的数据需要进行滤波、俯仰(Pitch)、滚转(Roll)、偏航(Yaw)等动作的PID算法设计及调整。这是一个较复杂的综合系统,如果玩家想在理论方面从零开始学习则需要介绍许许多多,受篇幅所限,请参考相关资料,这里就不详细介绍了。 | |||||||||||||||||||||||||||||||||||||||||||||
总的来说,所使用四旋翼飞行套件包括飞行器和遥控器两大部分,两者通过CoreRF传输控制指令。 | |||||||||||||||||||||||||||||||||||||||||||||
飞行器主要由带4个电机的机架、Microduino-CoreRF和Microduino-10DOF等模块组成。其中Microduino-10DOF集成了四种传感器,分别是三轴加速度+三轴陀螺仪传感器(MPU6050)、磁场强度传感器(HMC5883L)、数字气压传感器(BMP180)。通过I2C进行通信。 | |||||||||||||||||||||||||||||||||||||||||||||
MPU6050是其中最主要的姿态传感器,内部集成了三轴加速度计和三轴陀螺仪,不仅消除了组合加速度计和陀螺仪时容易出现的对准误差,而且内置了可编程的低通滤波器,即使在飞行器经受较大振动时,控制程序通过配置适当频率的低通滤波器,可以滤掉高频振动。这种处理方式可以减小四旋翼飞行器自身的振动对陀螺仪数据产生的影响。
四轴飞行器机架搭建与调试四旋翼飞行器材料清单
请参考文字说明与说明图片进行拼装
程序下载调试
Microduino-USBTTL下载模块在下载程序和串口调试校准四轴的时候才用到,其他时候可以不叠加。 校正四旋翼飞行器准备
注意:文件需使用JAVA开发环境打开,没有JAVA开发环境可以选择Microduino_Joypad_QuadCopter\java环境安装。 传感器校准
设置PID参数直接LOAD配置文件,点击LOAD,浏览到你下载你配置文件夹选择pkj.mwi导入,如图所示: 设置飞行模式 | |||||||||||||||||||||||||||||||||||||||||||||
在调整PID的右侧点击”SELECT SETTING”(下图右下)我们可以看到各种飞行模式以及对应辅助开关的一个二维表。一个开关或者多个开关的组合可以指定为一种飞行模式。我们建议玩家按照下图设置飞行模式。 | |||||||||||||||||||||||||||||||||||||||||||||
设置方法为在方块处点击鼠标左键,灰色的方块就会变成白色,如下图点击3个白色方块处(本应为灰色)。 | |||||||||||||||||||||||||||||||||||||||||||||
这样就指定了在这样的开关方位时处于对应的飞行模式。ANGLE是增稳模式,这有助于我们飞行。设置好点击WRITE以将数值写入飞控。
设置完飞行模式后,关闭MultiWiiConf串口连接,可以取下Microduino-USBTTL模块。完成了整个飞行控制器的组装和调试。 使用传感器值排除故障这种方法有助于排除飞行器在方向上出现的问题。它可以用来显示控制板安装的方向正确是否正确,或者有没有在“config.h”中选择正确的控制板类型。
遥控器(Microduino-Joypad)搭建与调试前面已经提及,遥控器由控制板(Microduino-Joypad)、微控制器(Microduino-CoreRF)、显示模块(Microduino-TFT)、以及下载调试模块(Microduino-USBTTL)组成。
Joypad搭建与调试Joypad搭建
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也可以不用电池,直接通过USB线接入左边的MicroUSB来供电。
Joypad搭建调试
按照图中的颜色,从左至右对应为Key1~Key4
在打开Joypad之后的4秒左右时间之内按下Key1,会进入设置(Config)模式 注意:必须在进入操作界面前进入(4S左右时间)。若未进入则重启进入
按动Key3和Key4使光标上下移动,Key1为返回,Key2为确认 选择第一项Joystick Config进入摇杆设置模式 继续选择Joystick Correct进入摇杆校准模式。 进入之后会显示如图中第三张图所示的界面,初始状态为两个十字 此时摇动左右摇杆至最上,最下,最左,最右四个极限状态 (推荐操作方式:将摇杆摇动一圈) 摇动之后会看到十字的四个方向出现圆圈,圆圈扩大到最大状态证明已经是摇杆的极限位置 校准之后按Key2确认并返回上一页面
按Key1回到主界面,选择第二项Protocol Config进入模式选择 选择第一项Mode,之后选择Quodro即四轴飞行器控制模式,按下Key2确认并返回
返回二级菜单,选择Quodrotor Channel按下Key2确认 选择12,它是与MultiWii.h中"#define RF_Channel 12"中的设置相对应的 至此,飞行控制器和遥控器已经组装完成,接下来便是将两者结合起来,开始试飞,除了练习使用操纵杆,还要观察飞行器实际的飞行状态,以便进一步优化PID等参数。 整体测试
手机蓝牙控制
将BT模块叠加到校准好的四轴上(四轴校准参考上文)。然后将四轴放置在平稳的地方,等待蓝牙连接。 打开手机蓝牙,打开四轴控制App,可以发现Microduino的蓝牙设备。 点击Microduino,进行蓝牙连接,进入控制界面,连接成功之后,屏幕出现“Reday”提示即可开始对四轴解锁。 电机Locked对四轴解锁,解锁之后四轴底板上的蓝色指示灯常亮,解锁成功,如果屏幕出现“Unlocked”,请重新尝试解锁。 解锁后,中间摇杆往上推就可以加油门,四轴就可以飞起来,前后左右则通过重力感应来控制。 代码及注释程序说明Joypad程序及说明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(); //初始化SPI总线
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();
}
//节点查错-------------------------------
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 //节点查错间隔
uint8_t nrf_channal = 70; //0~125
//Battery---------
#define PIN_bat A7 //BAT
#define _V_max 41 //锂电池满电电压4.2V
#define _V_min 36 //锂电池没电电压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读取赋值
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()
{
// 定义结构变量config,并定义config的内容
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;
// 变量config存储到EEPROM,地址0写入
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}; //按键1 2 3 4
boolean key_status[4]; //按键
boolean key_cache[4]; //检测按键松开缓存
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]; //缓存作判断用
key_status[_key_num] = !Joypad.readButton(key_pin[_key_num]); //触发时
switch (_key_type)
{
case 0:
if (!key_status[_key_num] && key_cache[_key_num]) //按下松开后
return true;
else
return false;
break;
case 1:
if (key_status[_key_num] && !key_cache[_key_num]) //按下松开后
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 fifoBuffer[64]; // FIFO storage buffer
// 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(fifoBuffer, 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, fifoBuffer);
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[])
{
//三个参数分别为: 数据长度 , 指令代码 , 实际数据数组
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 //设置本机ID
#define other_node 1
//--------------------------------
struct send_a //发送
{
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 //接收
{
uint32_t node_ms;
};
//--------------------------------
unsigned long node_clock, node_clock_debug, node_clock_cache = 0; //节点运行时间、节点响应检查时间、节点时间缓存
//debug--------------------------
boolean node_clock_error = false; //节点响应状态
unsigned long time_debug = 0; //定时器
//======================================
void vodebug()
{
if (millis() - time_debug > interval_debug)
{
node_clock_error = boolean(node_clock == node_clock_debug); //一定时间内,节点返回的运行时间若不变则有问题
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]
}; //把这些数据发送出去,对应前面的发送数组
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; //运行时间赋值
}
}
#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
//-------字体设置,大、中、小
#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
注意问题尽管在前面的内容中列出了不少要注意的一些问题,这里再总结一下。
若出现其他问题,欢迎在讨论部分提出 |