Arduino　加速度センサ　モーターカー　その2

前回からの続きです。

接続してからの角度を求めるところまでは↓参照

<a href="http://mrinvader007.hatenablog.jp/entry/20150604/1433408861" data-mce-href="http://mrinvader007.hatenablog.jp/entry/20150604/1433408861">Arduino　加速度センサ　モーターカー　その1 - レッドインベーダーの部屋　1F</a>mrinvader007.hatenablog.jp

角度を求めるスケッチと角度を求めるのに必要な数値の計測のスケッチが掲載されています。

前回書いたようにいろんな実験段階としてスケッチを何種類か書きました。

どんな感じに動くかは一応動画を載せますが、

配線はその1をみて接続してください。

実験的なスケッチなので、

名前などはとくにありません。

rotateX,rotateYの部分は個体差があるので、直してください。（その1参照）

int rotateX = (x - 288) / 2.48 - 90; //角度を求める式
int rotateY = (y - 275) / 2.48 - 90;

↑この部分です。

パターン1（sensamotorcar）（青文字部分）

//A,Bは右タイヤ
//C,Dは左タイヤ
//A,Cは前進
//B,Dは後進
const int motorA = 1;
const int motorB = 2;
const int PWM_mot = 3;
const int motorC = 13;
const int motorD = 12;
const int PWM_mot2 = 11;

const int led2 = 5;
const int led3 = 6;
const int led6 = 9;
const int led7 = 10;

void setup() {
// シリアルモニターの初期化をする
Serial.begin(9600) ;
pinMode (motorA, OUTPUT);
pinMode (motorB, OUTPUT);
pinMode (motorC, OUTPUT);
pinMode (motorD, OUTPUT);
}

void loop() {

int i ;
long x, y, z;
//50回センサ値を読み込んで平均を算出
x = y = z = 0;
for (i = 0 ; i < 50 ; i++) {
x = x + analogRead(3) ; // Ｘ軸
y = y + analogRead(4) ; // Ｙ軸
z = z + analogRead(5) ; // Ｚ軸
}
x = x / 50 ;
y = y / 50 ;
z = z / 50 ;
int rotateX = (x - 288) / 2.48 - 90; //角度を求める式
int rotateY = (y - 275) / 2.48 - 90;
Serial.print("X:") ;
Serial.print(x) ;
Serial.print(" ") ;
Serial.print(rotateX) ;
Serial.print(" Y:") ;
Serial.print(y) ;
Serial.print(" ") ;
Serial.println(rotateY) ;

if ( rotateX < 9) {
for (int red = 0; red > -1; red -= 10) {
analogWrite(led2, red);
digitalWrite(motorA, LOW);
digitalWrite(motorB, LOW);
digitalWrite(motorC, LOW);
digitalWrite(motorD, LOW);
analogWrite(PWM_mot, 0);
analogWrite(PWM_mot2, 0);
}
}

if (rotateX >= 10 ) {
for (int red = 1; red < 11; red += 10) {

analogWrite(led2, red);
}
}

if (rotateX >= 20 ) {
for (int red = 10; red < 26; red += 10) {

analogWrite(led2, red);

}
}
if (rotateX >= 30) {
for (int red = 25; red < 51; red += 10) {
analogWrite(led2, red);

digitalWrite(motorA, HIGH);
digitalWrite(motorB, LOW);
analogWrite(PWM_mot, 255);
digitalWrite(motorC, LOW);
digitalWrite(motorD, LOW);
analogWrite(PWM_mot2, 0);
}
}
if (rotateX >= 40) {
for (int red = 50; red < 81; red += 10) {
analogWrite(led2, red);
}
}
if (rotateX >= 50) {
for (int red = 80; red < 111; red += 10) {
analogWrite(led2, red);
}
}
if (rotateX >= 60) {
for (int red = 110; red < 141; red += 10) {
analogWrite(led2, red);
}
}
if (rotateX >= 70) {
for (int red = 140; red < 171; red += 10) {
analogWrite(led2, red);
}
}
if (rotateX >= 80) {
for (int red = 170; red < 201; red += 10) {
analogWrite(led2, red);
}
}
if (rotateX >= 90) {
for (int red = 200; red < 256; red += 10) {
analogWrite(led2, red);
}
}

if ( rotateX > -9) {
for (int red = 0; red > -1; red -= 10) {
analogWrite(led3, red);

}
}

if (rotateX <= -10 ) {
for (int red = 1; red < 11; red += 10) {

analogWrite(led3, red);
}
}

if (rotateX <= -20 ) {
for (int red = 10; red < 26; red += 10) {

analogWrite(led3, red);

}
}
if (rotateX <= -30) {
for (int red = 25; red < 51; red += 10) {
analogWrite(led3, red);

digitalWrite(motorA, LOW);
digitalWrite(motorB, LOW);
digitalWrite(motorC, LOW);
digitalWrite(motorD, LOW);
analogWrite(PWM_mot, 0);
analogWrite(PWM_mot2, 0);
}
}
if (rotateX <= -40) {
for (int red = 50; red < 81; red += 10) {
analogWrite(led3, red);
}
}
if (rotateX <= -50) {
for (int red = 80; red < 111; red += 10) {
analogWrite(led3, red);
}
}
if (rotateX <= -60) {
for (int red = 110; red < 141; red += 10) {
analogWrite(led3, red);
}
}
if (rotateX <= -70) {
for (int red = 140; red < 171; red += 10) {
analogWrite(led3, red);
}
}
if (rotateX <= -80) {
for (int red = 170; red < 201; red += 10) {
analogWrite(led3, red);
}
}
if (rotateX <= -90) {
for (int red = 200; red < 256; red += 10) {
analogWrite(led3, red);
}
}

if ( rotateY < 9) {
for (int red = 0; red > -1; red -= 10) {
analogWrite(led6, red);
}
}

if (rotateY >= 10 ) {
for (int red = 1; red < 11; red += 10) {

analogWrite(led6, red);
}
}

if (rotateY >= 20 ) {
for (int red = 10; red < 26; red += 10) {

analogWrite(led6, red);

}
}
if (rotateY >= 30) {
for (int red = 25; red < 51; red += 10) {
analogWrite(led6, red);
}
}
if (rotateY >= 40) {
for (int red = 50; red < 81; red += 10) {
analogWrite(led6, red);
}
}
if (rotateY >= 50) {
for (int red = 80; red < 111; red += 10) {
analogWrite(led6, red);
}
}
if (rotateY >= 60) {
for (int red = 110; red < 141; red += 10) {
analogWrite(led6, red);
}
}
if (rotateY >= 70) {
for (int red = 140; red < 171; red += 10) {
analogWrite(led6, red);
}
}
if (rotateY >= 80) {
for (int red = 170; red < 201; red += 10) {
analogWrite(led6, red);
}
}
if (rotateY >= 90) {
for (int red = 200; red < 256; red += 10) {
analogWrite(led6, red);
}
}

if ( rotateY > -9) {
for (int red = 0; red > -1; red -= 10) {
analogWrite(led7, red);
}
}

if (rotateY <= -10 ) {
for (int red = 1; red < 11; red += 10) {

analogWrite(led7, red);
}
}

if (rotateY <= -20 ) {
for (int red = 10; red < 26; red += 10) {

analogWrite(led7, red);

}
}
if (rotateY <= -30) {
for (int red = 25; red < 51; red += 10) {
analogWrite(led7, red);
}
}
if (rotateY <= -40) {
for (int red = 50; red < 81; red += 10) {
analogWrite(led7, red);
}
}
if (rotateY <= -50) {
for (int red = 80; red < 111; red += 10) {
analogWrite(led7, red);
}
}
if (rotateY <= -60) {
for (int red = 110; red < 141; red += 10) {
analogWrite(led7, red);
}
}
if (rotateY <= -70) {
for (int red = 140; red < 171; red += 10) {
analogWrite(led7, red);
}
}
if (rotateY <= -80) {
for (int red = 170; red < 201; red += 10) {
analogWrite(led7, red);
}
}
if (rotateY <= -90) {
for (int red = 200; red < 256; red += 10) {
analogWrite(led7, red);
}
}

}

前提としてあまりにも初期段階のため走りません。

動画

youtu.be

パターン2（sensamotorcar2）（青文字部分）

//加速度センサを使用したモーターカー
//線が短いため走行不可
//ベータ版

const int led2 = 5;
const int led3 = 6;
const int led6 = 9;
const int led7 = 10;

void setup() {
// シリアルモニターの初期化をする
Serial.begin(9600) ;
pinMode (motorA, OUTPUT);
pinMode (motorB, OUTPUT);
pinMode (motorC, OUTPUT);
pinMode (motorD, OUTPUT);

}
void loop() {

{
{ switch (rotateX) {
case 0:
{ for (int red = 0; red >= 0; red += -1)

analogWrite (led2, red);
}
{ for (int red = 0; red >= 0; red += -1)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 0);
break;
case 10:
{ for (int red = 1; red < 11; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 50);
analogWrite ( PWM_mot2, 0);
break;
case 20:
{ for (int red = 10; red < 31; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 70);
analogWrite ( PWM_mot2, 0);
break;
case 30:
{ for (int red = 30; red < 51; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 90);
analogWrite ( PWM_mot2, 0);
break;
case 40:
{ for (int red = 50; red < 71; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 110);
analogWrite ( PWM_mot2, 0);
break;
case 50:
{ for (int red = 70; red < 101; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 150);
analogWrite ( PWM_mot2, 0);
break;
case 60:
{ for (int red = 100; red < 131; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 170);
analogWrite ( PWM_mot2, 0);
break;
case 70:
{ for (int red = 130; red < 161; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 190);
analogWrite ( PWM_mot2, 0);
break;
case 80:
{ for (int red = 160; red < 201; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 220);
analogWrite ( PWM_mot2, 0);
break;
case 90:
{ for (int red = 200; red < 256; red += 10)
analogWrite (led2, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 0);
break;
case -10:
{ for (int red = -1; red < 11; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 50);
break;
case -20:
{ for (int red = 10; red < 31; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 70);
break;
case -30:
{ for (int red = 30; red < 51; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 90);
break;
case -40:
{ for (int red = 50; red < 71; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 110);
break;
case -50:
{ for (int red = 70; red < 101; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 150);
break;
case -60:
{ for (int red = 100; red < 131; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 170);
break;
case -70:
{ for (int red = 130; red < 161; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 190);
break;
case -80:
{ for (int red = 160; red < 201; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 220);
break;
case -90:
{ for (int red = 200; red < 256; red += 10)
analogWrite (led3, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 255);
break;
}
}
{ switch (rotateY) {
case 0:
{ for (int red = 0; red >= 0; red += -1)

analogWrite (led6, red);
}
{ for (int red = 0; red >= 0; red += -1)
analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 0);
break;
case 10:
{ for (int red = 1; red < 11; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 50);
analogWrite ( PWM_mot2, 50);
break;
case 20:
{ for (int red = 10; red < 31; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 70);
analogWrite ( PWM_mot2, 70);
break;
case 30:
{ for (int red = 30; red < 51; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 90);
analogWrite ( PWM_mot2, 90);
break;
case 40:
{ for (int red = 50; red < 71; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 110);
analogWrite ( PWM_mot2, 110);
break;
case 50:
{ for (int red = 70; red < 101; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 150);
analogWrite ( PWM_mot2, 150);
break;
case 60:
{ for (int red = 100; red < 131; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 170);
analogWrite ( PWM_mot2, 170);
break;
case 70:
{ for (int red = 130; red < 161; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 190);
analogWrite ( PWM_mot2, 190);
break;
case 80:
{ for (int red = 160; red < 201; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 220);
analogWrite ( PWM_mot2, 220);
break;
case 90:
{ for (int red = 200; red < 256; red += 10)

analogWrite (led6, red);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 255);
break;
case -10:
{ for (int red = 1; red < 11; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 50);
analogWrite ( PWM_mot2, 50);
break;
case -20:
{ for (int red = 10; red < 31; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 70);
analogWrite ( PWM_mot2, 70);
break;
case -30:
{ for (int red = 30; red < 51; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 90);
analogWrite ( PWM_mot2, 90);
break;
case -40:
{ for (int red = 50; red < 71; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 110);
analogWrite ( PWM_mot2, 110);
break;
case -50:
{ for (int red = 70; red < 101; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 150);
analogWrite ( PWM_mot2, 150);
break;
case -60:
{ for (int red = 100; red < 131; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 170);
analogWrite ( PWM_mot2, 170);
break;
case -70:
{ for (int red = 130; red < 161; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 190);
analogWrite ( PWM_mot2, 190);
break;
case -80:
{ for (int red = 160; red < 201; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 220);
analogWrite ( PWM_mot2, 220);
break;
case -90:
{ for (int red = 200; red < 256; red += 10)

analogWrite (led7, red);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 255);
break;
}
}
}
}

動画

youtu.be

パターン3（sensamotorcar3）（青文字部分）

int led2 = 5;
int led3 = 6;
int led6 = 9;
int led7 = 10;

void setup() {
// シリアルモニターの初期化をする
Serial.begin(9600) ;
pinMode (motorA, OUTPUT);
pinMode (motorB, OUTPUT);
pinMode (motorC, OUTPUT);
pinMode (motorD, OUTPUT);
pinMode (led2, OUTPUT);
pinMode (led3, OUTPUT);
pinMode (led6, OUTPUT);
pinMode (led7, OUTPUT);

}
void loop() {

{{{ if (rotateX <= 30, -30 <= rotateX) {

{ digitalWrite (led2, LOW);
digitalWrite (led3, LOW);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 0);
}
}
{ if (rotateX > 30) {

{ digitalWrite (led2, HIGH);
digitalWrite (led3, LOW);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 100);
}
}
{ if (rotateX < -30) {

{ digitalWrite (led2, LOW);
digitalWrite (led3, HIGH);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 100);
}
}
}

{ { if (rotateY <= 30, -30 <= rotateY) {

{ digitalWrite (led6, LOW);
digitalWrite (led7, LOW);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 0);
}
}
{ if (rotateY > 30) {

{ digitalWrite (led6, HIGH);
digitalWrite (led7, LOW);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 100);
}
}
{ if (rotateY < -30) {

{ digitalWrite (led6, LOW);
digitalWrite (led7, HIGH);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 100);
}
}
}
}

}

動画

youtu.be

パターン4　（sensamotorcar4）（青文字部分）

//A,Bは右タイヤ
//C,Dは左タイヤ
//A,Cは前進
//B,Dは後進

//led2は右
//led3は左
//led6は前
//led7は後ろ
const int motorA = 1;
const int motorB = 2;
const int PWM_mot = 3;
const int motorC = 13;
const int motorD = 12;
const int PWM_mot2 = 11;

int led2 = 5;
int led3 = 6;
int led6 = 9;
int led7 = 10;

}
void loop() {

{

{ if (rotateX <= 30, -30 <= rotateX )
if ( rotateY <= 30, -30 <= rotateY) {

{ digitalWrite (led2, LOW);
digitalWrite (led3, LOW);
digitalWrite (led6, LOW);
digitalWrite (led7, LOW);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 0);
}
}
{ if (rotateX > 30 )
if ( rotateY <= 30, -30 <= rotateY) {
{ digitalWrite (led2, HIGH);
digitalWrite (led3, LOW);
digitalWrite (led6, LOW);
digitalWrite (led7, LOW);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 0);
analogWrite ( PWM_mot2, 100);
}
}
{ if (rotateX < -30 )
if ( rotateY <= 30, -30 <= rotateY) {

{ digitalWrite (led2, LOW);
digitalWrite (led3, HIGH);
digitalWrite (led6, LOW);
digitalWrite (led7, LOW);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, LOW);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 100);
}
}

{ if (rotateY > 30 )
if ( rotateX <= 30, -30 <= rotateX) {

{ digitalWrite (led6, HIGH);
digitalWrite (led7, LOW);
digitalWrite (led2, LOW);
digitalWrite (led3, LOW);
}
digitalWrite (motorA, HIGH);
digitalWrite (motorB, LOW);
digitalWrite (motorC, HIGH);
digitalWrite (motorD, LOW);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 100);
}
}
{ if (rotateY < -30 )
if ( rotateX <= 30, -30 <= rotateX) {
{ digitalWrite (led6, LOW);
digitalWrite (led7, HIGH);
digitalWrite (led2, LOW);
digitalWrite (led3, LOW);
}
digitalWrite (motorA, LOW);
digitalWrite (motorB, HIGH);
digitalWrite (motorC, LOW);
digitalWrite (motorD, HIGH);
analogWrite ( PWM_mot, 255);
analogWrite ( PWM_mot2, 100);
}
}
}
}