时钟！

HardwareDesign/HardwareDesign.ino

@@ -1,240 +1,74 @@
 #include "REG.h"
 #include "wit_c_sdk.h"
 
-// #define ACC_UPDATE 0x01
-// #define GYRO_UPDATE 0x02
-// #define ANGLE_UPDATE 0x04
-// #define MAG_UPDATE 0x08
-// #define READ_UPDATE 0x80
-
-// char s_cDataUpdate = 0;
-// const uint32_t c_uiBaud[8] = {0,     4800,  9600,   19200,
-//                               38400, 57600, 115200, 230400};
-
-// float fAcc[3], fGyro[3], fAngle[3];
-
-// bool setup_ok = true;
-
-// static void SensorUartSend(uint8_t *p_data, uint32_t uiSize);
-// static void SensorDataUpdate(uint32_t uiReg, uint32_t uiRegNum);
-// static void Delayms(uint16_t ucMs);
-// static void AutoScanSensor();
-
-// void setup() {
-//   Serial.begin(115200);
-//   WitInit(WIT_PROTOCOL_NORMAL, 0x50);
-//   WitSerialWriteRegister(SensorUartSend);
-//   WitRegisterCallBack(SensorDataUpdate);
-//   WitDelayMsRegister(Delayms);
-//   AutoScanSensor();
-
-//   // Ensure the setting for the sensor is the default
-//   if (WitSetBandwidth(BANDWIDTH_256HZ) != WIT_HAL_OK) {
-//     Serial.print("Set Bandwidth Error\r\n");
-//     setup_ok = false;
-//     return;
-//   }
-
-//   // if (WitSetUartBaud(WIT_BAUD_115200) != WIT_HAL_OK) {
-//   //   Serial.print("Set baud error\r\n");
-//   //   setup_ok = false;
-//   //   return;
-//   // } else {
-//   //   Serial1.begin(115200);
-//   // }
-
-//   if (WitSetOutputRate(RRATE_1HZ) != WIT_HAL_OK) {
-//     Serial.print("Can't set report rate to 10Hz!\r\n");
-//     setup_ok = false;
-//     return;
-//   }
-
-//   if (WitSetContent(RSW_ACC | RSW_GYRO | RSW_ANGLE | RSW_MAG) != WIT_HAL_OK)
-//   {
-//     Serial.print("Set RSW Error\r\n");
-//     setup_ok = false;
-//     return;
-//   }
-// }
-
-// void loop() {
-//   while (Serial1.available()) {
-//     WitSerialDataIn(Serial1.read());
-//   }
-
-//   // if (s_cDataUpdate) {
-//   //   for (int i = 0; i < 3; i++) {
-//   //     fAcc[i] = sReg[AX + i] / 32768.0f * 16.0f;      // Unit: g(9.8m/s^2)
-//   //     fGyro[i] = sReg[GX + i] / 32768.0f * 2000.0f;   // Unit: deg/s
-//   //     fAngle[i] = sReg[Roll + i] / 32768.0f * 180.0f; // Unit: deg
-//   //   }
-
-//   //   if (s_cDataUpdate & ACC_UPDATE) {
-//   //     Serial.print("acc:");
-//   //     Serial.print(fAcc[0], 3);
-//   //     Serial.print(" ");
-//   //     Serial.print(fAcc[1], 3);
-//   //     Serial.print(" ");
-//   //     Serial.print(fAcc[2], 3);
-//   //     Serial.print("\r\n");
-//   //     s_cDataUpdate &= ~ACC_UPDATE;
-//   //   }
-//   //   if (s_cDataUpdate & GYRO_UPDATE) {
-//   //     Serial.print("gyro:");
-//   //     Serial.print(fGyro[0], 1);
-//   //     Serial.print(" ");
-//   //     Serial.print(fGyro[1], 1);
-//   //     Serial.print(" ");
-//   //     Serial.print(fGyro[2], 1);
-//   //     Serial.print("\r\n");
-//   //     s_cDataUpdate &= ~GYRO_UPDATE;
-//   //   }
-//   //   if (s_cDataUpdate & ANGLE_UPDATE) {
-//   //     Serial.print("angle:");
-//   //     Serial.print(fAngle[0], 3);
-//   //     Serial.print(" ");
-//   //     Serial.print(fAngle[1], 3);
-//   //     Serial.print(" ");
-//   //     Serial.print(fAngle[2], 3);
-//   //     Serial.print("\r\n");
-//   //     s_cDataUpdate &= ~ANGLE_UPDATE;
-//   //   }
-//   //   if (s_cDataUpdate & MAG_UPDATE) {
-//   //     Serial.print("mag:");
-//   //     Serial.print(sReg[HX]);
-//   //     Serial.print(" ");
-//   //     Serial.print(sReg[HY]);
-//   //     Serial.print(" ");
-//   //     Serial.print(sReg[HZ]);
-//   //     Serial.print("\r\n");
-//   //     s_cDataUpdate &= ~MAG_UPDATE;
-//   //   }
-//   //   s_cDataUpdate = 0;
-//   // }
-// }
-
-// static void SensorUartSend(uint8_t *p_data, uint32_t uiSize) {
-//   Serial1.print("Sensor says: ");
-//   Serial1.write(p_data, uiSize);
-//   Serial1.flush();
-// };
-
-// static void SensorDataUpdate(uint32_t uiReg, uint32_t uiRegNum) {
-//   int i;
-//   for (i = 0; i < uiRegNum; i++) {
-//     switch (uiReg) {
-//     case AZ:
-//       s_cDataUpdate |= ACC_UPDATE;
-//       break;
-//     case GZ:
-//       s_cDataUpdate |= GYRO_UPDATE;
-//       break;
-//     case HZ:
-//       s_cDataUpdate |= MAG_UPDATE;
-//       break;
-//     case Yaw:
-//       s_cDataUpdate |= ANGLE_UPDATE;
-//       break;
-//     default:
-//       s_cDataUpdate |= READ_UPDATE;
-//       break;
-//     }
-//     uiReg++;
-//   }
-//   Serial.println(s_cDataUpdate);
-// };
-
-// static void Delayms(uint16_t ucMs) { delay(ucMs); }
-
-// static void AutoScanSensor() {
-//   int i, iRetry;
-
-//   for (i = 0; i < sizeof(c_uiBaud) / sizeof(c_uiBaud[0]); i++) {
-//     Serial1.begin(c_uiBaud[i]);
-//     Serial1.flush();
-//     iRetry = 2;
-//     s_cDataUpdate = 0;
-//     do {
-//       WitReadReg(AX, 3);
-//       delay(200);
-//       while (Serial1.available()) {
-//         WitSerialDataIn(Serial1.read());
-//       }
-//       if (s_cDataUpdate != 0) {
-//         Serial.print(c_uiBaud[i]);
-//         Serial.print(" baud find sensor\r\n\r\n");
-//         return;
-//       }
-//       iRetry--;
-//     } while (iRetry);
-//   }
-//   Serial.print("can not find sensor\r\n");
-//   Serial.print("please check your connection\r\n");
-// }
-
-/*
-Test on MEGA 2560. use WT901CTTL sensor
-
-WT901CTTL     MEGA 2560a
-    VCC <--->  5V/3.3V
-    TX  <--->  19(TX1)
-    RX  <--->  18(RX1)
-    GND <--->  GND
-*/
-
 #define ACC_UPDATE 0x01
 #define GYRO_UPDATE 0x02
 #define ANGLE_UPDATE 0x04
 #define MAG_UPDATE 0x08
 #define READ_UPDATE 0x80
-static volatile char s_cDataUpdate = 0, s_cCmd = 0xff;
 
-static void CmdProcess(void);
-static void AutoScanSensor(void);
-static void SensorUartSend(uint8_t *p_data, uint32_t uiSize);
-static void SensorDataUpdata(uint32_t uiReg, uint32_t uiRegNum);
-static void Delayms(uint16_t ucMs);
+char s_cDataUpdate = 0;
 const uint32_t c_uiBaud[8] = {0,     4800,  9600,   19200,
                               38400, 57600, 115200, 230400};
 
-int i;
 float fAcc[3], fGyro[3], fAngle[3];
 
+bool setup_ok = true;
+
+static void SensorUartSend(uint8_t *p_data, uint32_t uiSize);
+static void SensorDataUpdate(uint32_t uiReg, uint32_t uiRegNum);
+static void Delayms(uint16_t ucMs);
+static void AutoScanSensor();
+
 void setup() {
-  // put your setup code here, to run once:
   Serial.begin(115200);
   WitInit(WIT_PROTOCOL_NORMAL, 0x50);
   WitSerialWriteRegister(SensorUartSend);
-  WitRegisterCallBack(SensorDataUpdata);
+  WitRegisterCallBack(SensorDataUpdate);
   WitDelayMsRegister(Delayms);
   AutoScanSensor();
 
-  if (WitStartAccCali() == WIT_HAL_OK) {
-    Serial.print("Start Calibri");
-    delay(1000);
-    Serial.print("Stop calibri");
-    WitStopAccCali();
-  } else {
-    Serial.print("Cannot start calibri acc\r\n");
+  // Ensure the setting for the sensor is the default
+  if (WitSetBandwidth(BANDWIDTH_256HZ) != WIT_HAL_OK) {
+    Serial.print("Set Bandwidth Error\r\n");
+    setup_ok = false;
+    return;
   }
 
-  if (WitSetUartBaud(WIT_BAUD_9600) != WIT_HAL_OK)
-    Serial.print("\r\nSet Baud Error\r\n");
-  else {
-    Serial1.begin(c_uiBaud[WIT_BAUD_9600]);
-    Serial.print(" 115200 Baud rate modified successfully\r\n");
+  // if (WitSetUartBaud(WIT_BAUD_115200) != WIT_HAL_OK) {
+  //   Serial.print("Set baud error\r\n");
+  //   setup_ok = false;
+  //   return;
+  // } else {
+  //   Serial1.begin(115200);
+  // }
+
+  if (WitSetOutputRate(RRATE_1HZ) != WIT_HAL_OK) {
+    Serial.print("Can't set report rate to 10Hz!\r\n");
+    setup_ok = false;
+    return;
+  }
+
+  if (WitSetContent(RSW_ACC | RSW_GYRO | RSW_ANGLE | RSW_MAG) != WIT_HAL_OK)
+  {
+    Serial.print("Set RSW Error\r\n");
+    setup_ok = false;
+    return;
   }
 }
+
 void loop() {
   while (Serial1.available()) {
     WitSerialDataIn(Serial1.read());
   }
+
   if (s_cDataUpdate) {
-    for (i = 0; i < 3; i++) {
-      fAcc[i] = sReg[AX + i] / 32768.0f * 16.0f * 9.8f; // Unit: m/s^2
-      fGyro[i] = sReg[GX + i] / 32768.0f * 2000.0f; // Unit: deg/s
+    for (int i = 0; i < 3; i++) {
+      fAcc[i] = sReg[AX + i] / 32768.0f * 16.0f;      // Unit: g(9.8m/s^2)
+      fGyro[i] = sReg[GX + i] / 32768.0f * 2000.0f;   // Unit: deg/s
       fAngle[i] = sReg[Roll + i] / 32768.0f * 180.0f; // Unit: deg
     }
+    Serial.print("Here");
     if (s_cDataUpdate & ACC_UPDATE) {
       Serial.print("acc:");
       Serial.print(fAcc[0], 3);
@@ -282,9 +116,9 @@ void loop() {
 static void SensorUartSend(uint8_t *p_data, uint32_t uiSize) {
   Serial1.write(p_data, uiSize);
   Serial1.flush();
-}
-static void Delayms(uint16_t ucMs) { delay(ucMs); }
-static void SensorDataUpdata(uint32_t uiReg, uint32_t uiRegNum) {
+};
+
+static void SensorDataUpdate(uint32_t uiReg, uint32_t uiRegNum) {
   int i;
   for (i = 0; i < uiRegNum; i++) {
     switch (uiReg) {
@@ -306,9 +140,12 @@ static void SensorDataUpdata(uint32_t uiReg, uint32_t uiRegNum) {
     }
     uiReg++;
   }
-}
+  // Serial.println(s_cDataUpdate);
+};
 
-static void AutoScanSensor(void) {
+static void Delayms(uint16_t ucMs) { delay(ucMs); }
+
+static void AutoScanSensor() {
   int i, iRetry;
 
   for (i = 0; i < sizeof(c_uiBaud) / sizeof(c_uiBaud[0]); i++) {
@@ -333,3 +170,165 @@ static void AutoScanSensor(void) {
   Serial.print("can not find sensor\r\n");
   Serial.print("please check your connection\r\n");
 }
+
+/*
+Test on MEGA 2560. use WT901CTTL sensor
+
+WT901CTTL     MEGA 2560a
+    VCC <--->  5V/3.3V
+    TX  <--->  19(TX1)
+    RX  <--->  18(RX1)
+    GND <--->  GND
+*/
+
+// #define ACC_UPDATE 0x01
+// #define GYRO_UPDATE 0x02
+// #define ANGLE_UPDATE 0x04
+// #define MAG_UPDATE 0x08
+// #define READ_UPDATE 0x80
+// static volatile char s_cDataUpdate = 0, s_cCmd = 0xff;
+
+// static void CmdProcess(void);
+// static void AutoScanSensor(void);
+// static void SensorUartSend(uint8_t *p_data, uint32_t uiSize);
+// static void SensorDataUpdata(uint32_t uiReg, uint32_t uiRegNum);
+// static void Delayms(uint16_t ucMs);
+// const uint32_t c_uiBaud[8] = {0,     4800,  9600,   19200,
+//                               38400, 57600, 115200, 230400};
+
+// int i;
+// float fAcc[3], fGyro[3], fAngle[3];
+
+// void setup() {
+//   // put your setup code here, to run once:
+//   Serial.begin(115200);
+//   WitInit(WIT_PROTOCOL_NORMAL, 0x50);
+//   WitSerialWriteRegister(SensorUartSend);
+//   WitRegisterCallBack(SensorDataUpdata);
+//   WitDelayMsRegister(Delayms);
+//   AutoScanSensor();
+
+//   // if (WitStartAccCali() == WIT_HAL_OK) {
+//   //   Serial.print("Start Calibri");
+//   //   delay(1000);
+//   //   Serial.print("Stop calibri");
+//   //   WitStopAccCali();
+//   // } else {
+//   //   Serial.print("Cannot start calibri acc\r\n");
+//   // }
+
+//   if (WitSetUartBaud(WIT_BAUD_9600) != WIT_HAL_OK)
+//     Serial.print("\r\nSet Baud Error\r\n");
+//   else {
+//     Serial1.begin(c_uiBaud[WIT_BAUD_9600]);
+//     Serial.print(" 9600 Baud rate modified successfully\r\n");
+//   }
+// }
+// void loop() {
+//   while (Serial1.available()) {
+//     WitSerialDataIn(Serial1.read());
+//   }
+//   if (s_cDataUpdate) {
+//     for (i = 0; i < 3; i++) {
+//       fAcc[i] = sReg[AX + i] / 32768.0f * 16.0f * 9.8f; // Unit: m/s^2
+//       fGyro[i] = sReg[GX + i] / 32768.0f * 2000.0f; // Unit: deg/s
+//       fAngle[i] = sReg[Roll + i] / 32768.0f * 180.0f; // Unit: deg
+//     }
+//     if (s_cDataUpdate & ACC_UPDATE) {
+//       Serial.print("acc:");
+//       Serial.print(fAcc[0], 3);
+//       Serial.print(" ");
+//       Serial.print(fAcc[1], 3);
+//       Serial.print(" ");
+//       Serial.print(fAcc[2], 3);
+//       Serial.print("\r\n");
+//       s_cDataUpdate &= ~ACC_UPDATE;
+//     }
+//     if (s_cDataUpdate & GYRO_UPDATE) {
+//       Serial.print("gyro:");
+//       Serial.print(fGyro[0], 1);
+//       Serial.print(" ");
+//       Serial.print(fGyro[1], 1);
+//       Serial.print(" ");
+//       Serial.print(fGyro[2], 1);
+//       Serial.print("\r\n");
+//       s_cDataUpdate &= ~GYRO_UPDATE;
+//     }
+//     if (s_cDataUpdate & ANGLE_UPDATE) {
+//       Serial.print("angle:");
+//       Serial.print(fAngle[0], 3);
+//       Serial.print(" ");
+//       Serial.print(fAngle[1], 3);
+//       Serial.print(" ");
+//       Serial.print(fAngle[2], 3);
+//       Serial.print("\r\n");
+//       s_cDataUpdate &= ~ANGLE_UPDATE;
+//     }
+//     if (s_cDataUpdate & MAG_UPDATE) {
+//       Serial.print("mag:");
+//       Serial.print(sReg[HX]);
+//       Serial.print(" ");
+//       Serial.print(sReg[HY]);
+//       Serial.print(" ");
+//       Serial.print(sReg[HZ]);
+//       Serial.print("\r\n");
+//       s_cDataUpdate &= ~MAG_UPDATE;
+//     }
+//     s_cDataUpdate = 0;
+//   }
+// }
+
+// static void SensorUartSend(uint8_t *p_data, uint32_t uiSize) {
+//   Serial1.write(p_data, uiSize);
+//   Serial1.flush();
+// }
+// static void Delayms(uint16_t ucMs) { delay(ucMs); }
+// static void SensorDataUpdata(uint32_t uiReg, uint32_t uiRegNum) {
+//   int i;
+//   for (i = 0; i < uiRegNum; i++) {
+//     switch (uiReg) {
+//     case AZ:
+//       s_cDataUpdate |= ACC_UPDATE;
+//       break;
+//     case GZ:
+//       s_cDataUpdate |= GYRO_UPDATE;
+//       break;
+//     case HZ:
+//       s_cDataUpdate |= MAG_UPDATE;
+//       break;
+//     case Yaw:
+//       s_cDataUpdate |= ANGLE_UPDATE;
+//       break;
+//     default:
+//       s_cDataUpdate |= READ_UPDATE;
+//       break;
+//     }
+//     uiReg++;
+//   }
+// }
+
+// static void AutoScanSensor(void) {
+//   int i, iRetry;
+
+//   for (i = 0; i < sizeof(c_uiBaud) / sizeof(c_uiBaud[0]); i++) {
+//     Serial1.begin(c_uiBaud[i]);
+//     Serial1.flush();
+//     iRetry = 2;
+//     s_cDataUpdate = 0;
+//     do {
+//       WitReadReg(AX, 3);
+//       delay(200);
+//       while (Serial1.available()) {
+//         WitSerialDataIn(Serial1.read());
+//       }
+//       if (s_cDataUpdate != 0) {
+//         Serial.print(c_uiBaud[i]);
+//         Serial.print(" baud find sensor\r\n\r\n");
+//         return;
+//       }
+//       iRetry--;
+//     } while (iRetry);
+//   }
+//   Serial.print("can not find sensor\r\n");
+//   Serial.print("please check your connection\r\n");
+// }

Test/Test.ino

@@ -1,50 +1,14 @@
-byte status = 0;
-byte layer = 0;
-
 void setup() {
-  Serial.begin(115200);
+  pinMode(A7, INPUT_PULLUP);
+  pinMode(2, INPUT_PULLUP);
   for (int i = 0; i < 8; i++) {
     pinMode(22 + i, OUTPUT);
+    digitalWrite(22 + i, HIGH);
   }
-  // pinMode(30, OUTPUT);
-  // pinMode(31, OUTPUT);
-
-  for (int i = 0; i < 8; i++) {
-    pinMode(30 + i, OUTPUT);
-  }
-
-  for (int i = 0; i < 8; i++) {
-    pinMode(38 + i, OUTPUT);
-  }
+  Serial.begin(115200);
 }
 
-int column = 0;
-
 void loop() {
-  if (Serial.available()) {
-    int num = Serial.read();
-    if (num >= '0' && num <= '7') {
-      num = num - '0';
-      status ^= 1 << num;
-
-      for (int i = 0; i < 8; i++) {
-        digitalWrite(22 + i, status >> i & 1);
-      }
-
-      Serial.println(status, BIN);
-    } else if (num >= 'a' && num <= 'h') {
-      num = num - 'a';
-      column = num;
-      Serial.print("LOAD");
-      Serial.print(num);
-      Serial.println(status, BIN);
-      digitalWrite(30 + column, HIGH);
-      digitalWrite(30 + column, LOW);
-    }
-    else if (num == 'z') {
-      digitalWrite(38 + layer, LOW);
-      layer = (layer + 1) % 8;
-      digitalWrite(38 + layer, HIGH);
-    }
-  }
+  Serial.println(digitalRead(2));
+  delay(100);
 }