- Cool Paging for Telemetry

- Added basic led library
- updated readme
- implemented fanoverride and lightActive transmission
This commit is contained in:
Lukas Bachschwell 2018-05-10 15:57:38 +02:00
parent 0c3d258bd0
commit d6027e093b
7 changed files with 158 additions and 44 deletions

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@ -33,3 +33,4 @@ monitor_baud = 115200
lib_deps = lib_deps =
ServoESP32 ServoESP32
DallasTemperature DallasTemperature
FastLED

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@ -1 +1,34 @@
This is my take on a eskate remote This is my take on an *eskate remote*
it uses:
* ESPNow on 2 ESP32
* Hal sensor based remote
* 3D model by SolidGeek
it features:
* Basic Skateboard control
* FANCY Displays
* Encryption (Not yet)
* Lights !
* Cruise Mode
* Experimental SteeringMode (for walking your board like a dog)
* Limit Mode
* Telemetry: Voltage, Electronics Temperature, Speed (with cool paging)
* Basic ESC Fan control (relay based...)
# TODO:
### Software:
implement ws2812
add graphics to quick selection
implement display on reciever
rpm direction and calibration
enable ecryption for espnow
Improve steeringmode using rpm knowledge
### Hardware:
improve voltage resistors
improve fans to be PWM controlled

23
src/lights.h Normal file
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@ -0,0 +1,23 @@
#include "FastLED.h"
#define NUM_STRIPS 2
#define NUM_LEDS_PER_STRIP 10
CRGB leds[NUM_STRIPS][NUM_LEDS_PER_STRIP];
#define PIN_STRIP1 34
void setupLights() {
FastLED.addLeds<NEOPIXEL, PIN_STRIP1>(leds[0], NUM_LEDS_PER_STRIP);
}
void loopLights() {
// This outer loop will go over each strip, one at a time
for(int x = 0; x < NUM_STRIPS; x++) {
// This inner loop will go over each led in the current strip, one at a time
for(int i = 0; i < NUM_LEDS_PER_STRIP; i++) {
leds[x][i] = CRGB::Red;
FastLED.show();
leds[x][i] = CRGB::Black;
delay(100);
}
}
}

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@ -54,6 +54,22 @@ long lastPacket = 0;
bool isConnected = false; bool isConnected = false;
#define FANS_AUTO 0
#define FANS_ON 1
#define FANS_OFF 2
bool lightActive = false;
int fanMode = FANS_AUTO;
#include "lights.h"
void setBoardOptions(uint8_t options) {
Serial.print("opt: ");
Serial.println(options, BIN);
lightActive = options & 1;
fanMode = (options >> 2) & 3;
}
// ESPNOW Functions ############################ // ESPNOW Functions ############################
// config AP // config AP
void configDeviceAP(bool hidden) { void configDeviceAP(bool hidden) {
@ -76,7 +92,7 @@ void OnDataRecv(const uint8_t *mac_addr, const uint8_t *data, int data_len) {
snprintf(macStr, sizeof(macStr), "%02x:%02x:%02x:%02x:%02x:%02x", snprintf(macStr, sizeof(macStr), "%02x:%02x:%02x:%02x:%02x:%02x",
mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5]); mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5]);
Serial.print("Last Packet Recv from: "); Serial.println(macStr); Serial.print("Last Packet Recv from: "); Serial.println(macStr);
uint8_t recData[2]; uint8_t recData[3];
memcpy(recData, data, data_len); memcpy(recData, data, data_len);
Serial.print("Last Packet Recv Data: "); Serial.println(recData[0]); Serial.print(" "); Serial.print(recData[1]); Serial.print(" len:"); Serial.println(data_len); Serial.print("Last Packet Recv Data: "); Serial.println(recData[0]); Serial.print(" "); Serial.print(recData[1]); Serial.print(" len:"); Serial.println(data_len);
@ -110,6 +126,7 @@ void OnDataRecv(const uint8_t *mac_addr, const uint8_t *data, int data_len) {
isConnected = true; isConnected = true;
// Could check mac here for some security // Could check mac here for some security
writeServos(recData[0], recData[1]); writeServos(recData[0], recData[1]);
setBoardOptions(recData[2]);
display.clear(); display.clear();
char buf[25]; char buf[25];
@ -196,8 +213,19 @@ void checkTemperature() {
temperature = sensors.getTempCByIndex(0); temperature = sensors.getTempCByIndex(0);
//Serial.print("Temp: "); //Serial.print("Temp: ");
//Serial.println(temperature); //Serial.println(temperature);
switch(fanMode) {
case FANS_AUTO:
if(temperature < 35) digitalWrite(fanRelais, LOW); if(temperature < 35) digitalWrite(fanRelais, LOW);
if(temperature > 40) digitalWrite(fanRelais, HIGH); if(temperature > 40) digitalWrite(fanRelais, HIGH);
break;
case FANS_ON:
digitalWrite(fanRelais, HIGH);
break;
case FANS_OFF:
digitalWrite(fanRelais, LOW);
break;
}
sendTemperature = abs(floor(temperature)); sendTemperature = abs(floor(temperature));
sendTemperatureDecimals = (temperature - sendTemperature) * 100; sendTemperatureDecimals = (temperature - sendTemperature) * 100;
} }

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@ -252,9 +252,7 @@ bool manageBoard() {
// send data // send data
void sendData() { void sendData() {
const uint8_t data[] = { esc1, esc2 }; const uint8_t data[] = { esc1, esc2, boardOptions };
//const uint8_t data[] = { esc1, esc2, options};
const uint8_t *peer_addr = board.peer_addr; const uint8_t *peer_addr = board.peer_addr;
DEBUG_PRINT("Sending: "); DEBUG_PRINTLN(esc1); DEBUG_PRINT("Sending: "); DEBUG_PRINTLN(esc1);
@ -404,11 +402,34 @@ void checkClicks(void * parameter) {
//DEBUG_PRINT("Trig: "); DEBUG_PRINT(triggerActive()); DEBUG_PRINT(" LAST: "); DEBUG_PRINTLN(lastTriggerState); //DEBUG_PRINT("Trig: "); DEBUG_PRINT(triggerActive()); DEBUG_PRINT(" LAST: "); DEBUG_PRINTLN(lastTriggerState);
if(millis()-lastClick > clickDiff && clickCounter!=0) { if(millis()-lastClick > clickDiff && clickCounter!=0) {
DEBUG_PRINTLN("reset"); DEBUG_PRINTLN("reset");
//timeout, check amount
if(clickCounter == 2) {
// cycle page if active
DEBUG_PRINTLN("Double, rotate page");
if(settings[pageDisplay] != 0) {
displayData++;
if (displayData > 2) {
displayData = 0;
}
// write and save
settings[pageDisplay] = displayData + 1;
shouldUpdateSettings = true;
}
} else if(clickCounter == 3) {
DEBUG_PRINTLN("YEAH TRIPPLE");
if(currentMode == M_NORMAL) {
currentMode = M_SELECT;
selectedIndex = 2;
} else {
currentMode = M_NORMAL;
}
}
clickCounter = 0; clickCounter = 0;
} }
if(!triggerActive() && lastTriggerState) { if(!triggerActive() && lastTriggerState) {
DEBUG_PRINTLN("CLICK##################### "); DEBUG_PRINTLN("CLICK ##################### ");
int timeSinceLastClick = millis()-lastClick; int timeSinceLastClick = millis()-lastClick;
lastClick = millis(); lastClick = millis();
@ -425,6 +446,7 @@ void checkClicks(void * parameter) {
break; break;
case 2: case 2:
lightActive = !lightActive; lightActive = !lightActive;
updateBoardOptions();
currentMode = M_NORMAL; currentMode = M_NORMAL;
break; break;
case 3: case 3:
@ -436,19 +458,10 @@ void checkClicks(void * parameter) {
} }
} }
if(timeSinceLastClick < clickDiff) clickCounter++; if(timeSinceLastClick < clickDiff) {
else clickCounter = 1; clickCounter++;
if(clickCounter == 3) {
DEBUG_PRINTLN("YEAH TRIPPLE");
if(currentMode == M_NORMAL) {
currentMode = M_SELECT;
selectedIndex = 2;
} else { } else {
currentMode = M_NORMAL; clickCounter = 1;
}
vTaskDelay(pdMS_TO_TICKS(2000));
} }
lastClick = millis(); lastClick = millis();
@ -459,7 +472,6 @@ void checkClicks(void * parameter) {
vTaskDelay(pdMS_TO_TICKS(20)); vTaskDelay(pdMS_TO_TICKS(20));
} }
} }
//############ End Hardware Helpers //############ End Hardware Helpers
//############ Drawing Functions //############ Drawing Functions
@ -553,6 +565,7 @@ void drawPage() {
int y = 16; int y = 16;
// Rotate the realtime data each 4s. // Rotate the realtime data each 4s.
if(settings[pageDisplay] == 0) {
if ((millis() - lastDataRotation) >= 4000) { if ((millis() - lastDataRotation) >= 4000) {
lastDataRotation = millis(); lastDataRotation = millis();
@ -562,6 +575,9 @@ void drawPage() {
displayData = 0; displayData = 0;
} }
} }
} else {
displayData = settings[pageDisplay] - 1;
}
switch (displayData) { switch (displayData) {
case 0: case 0:

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@ -9,7 +9,6 @@
#define wheelCircumference 26.062 #define wheelCircumference 26.062
TaskHandle_t rpmTaskHandle; TaskHandle_t rpmTaskHandle;
int rpmRight = 0; int rpmRight = 0;
int rpmLeft = 0; int rpmLeft = 0;

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@ -1,18 +1,23 @@
uint8_t currentSetting = 0; uint8_t currentSetting = 0;
#define SETTINGS_COUNT 7 #define SETTINGS_COUNT 7
#define limitMode 0 #define pageDisplay 0
#define fanOveride 1 #define limitMode 1
#define wheelDiameter 2 // Speed factor #define fanOveride 2
#define minHallValue 3 #define wheelDiameter 3 // Speed factor
#define centerHallValue 4 #define minHallValue 4
#define maxHallValue 5 #define centerHallValue 5
#define maxHallValue 6
int settings[SETTINGS_COUNT]; int settings[SETTINGS_COUNT];
float gearRatio; uint8_t boardOptions = 0b00000000;
float ratioRpmSpeed; // Map:(Light, Fan) XXXXFFLL
float ratioPulseDistance; /*
float gearRatio;
float ratioRpmSpeed;
float ratioPulseDistance;
*/
// Defining variables for Settings menu // Defining variables for Settings menu
bool changeSelectedSetting = false; bool changeSelectedSetting = false;
@ -22,9 +27,9 @@ bool settingsChangeFlag = false;
bool settingsChangeValueFlag = false; bool settingsChangeValueFlag = false;
const char *settingPages[SETTINGS_COUNT] = { const char *settingPages[SETTINGS_COUNT] = {
"Page Display",
"LimitMode", "LimitMode",
"FanOveride", "FanOveride",
"TriggerMode",
"Wheel diameter", "Wheel diameter",
"Throttle Min", "Throttle Min",
"Throttle Center", "Throttle Center",
@ -33,9 +38,9 @@ const char *settingPages[SETTINGS_COUNT] = {
// Setting rules format: default, min, max. // Setting rules format: default, min, max.
int settingRules[SETTINGS_COUNT][3] { int settingRules[SETTINGS_COUNT][3] {
{0, 0, 1}, // default is no limit {0, 0, 3}, //page: 0 cycle, 1 speed, 2 volt, 3 temp
{0, 0, 2}, // 0 no, 1 on, 2 off {0, 0, 1}, //limit default is no limit
{0, 0, 3}, // 0 Killswitch, 1 cruise & 2 data toggle {0, 0, 2}, //fan 0 no, 1 on, 2 off
{83, 0, 250}, // wheel mm {83, 0, 250}, // wheel mm
{HAL_MIN, 1000, 2000}, {HAL_MIN, 1000, 2000},
{HAL_CENTER, 1000, 2000}, {HAL_CENTER, 1000, 2000},
@ -51,22 +56,33 @@ int settingRules[SETTINGS_COUNT][3] {
//"Throttle Max" //"Throttle Max"
}; };
*/ */
// Check if an integer is within a min and max value // Check if an integer is within a min and max value
bool inRange(int val, int minimum, int maximum) { bool inRange(int val, int minimum, int maximum) {
return ((minimum <= val) && (val <= maximum)); return ((minimum <= val) && (val <= maximum));
} }
void updateBoardOptions() {
boardOptions = 0;
boardOptions |= (uint8_t) settings[fanOveride] << 2;
boardOptions |= boardOptions | (uint8_t) lightActive;
Serial.print("board: "); Serial.println(boardOptions);
}
void updateSettings() { void updateSettings() {
preferences.begin("remote-set", false); preferences.begin("remote-set", false);
for (int i = 0; i < SETTINGS_COUNT; i++) { for (int i = 0; i < SETTINGS_COUNT; i++) {
preferences.putInt(settingPages[i], settings[i]); preferences.putInt(settingPages[i], settings[i]);
} }
preferences.end(); preferences.end();
DEBUG_PRINTLN("UPDATED"); DEBUG_PRINTLN("UPDATED");
preferences.begin("remote-set", false); preferences.begin("remote-set", false);
DEBUG_PRINTLN(preferences.getInt(settingPages[0], 0)); DEBUG_PRINTLN(preferences.getInt(settingPages[0], 0));
preferences.end(); preferences.end();
//calculateRatios(); //calculateRatios();
updateBoardOptions();
} }
void setDefaultSettings() { void setDefaultSettings() {
@ -84,9 +100,7 @@ void loadSettings() {
} }
preferences.end(); preferences.end();
bool rewriteSettings = false; bool rewriteSettings = false;
// Loop through all settings to check if everything is fine // Loop through all settings to check if everything is fine
for (int i = 0; i < SETTINGS_COUNT; i++) { for (int i = 0; i < SETTINGS_COUNT; i++) {
int val = settings[i]; int val = settings[i];
@ -97,12 +111,12 @@ void loadSettings() {
settings[i] = settingRules[i][0]; settings[i] = settingRules[i][0];
} }
} }
if (rewriteSettings == true) { if (rewriteSettings == true) {
updateSettings(); updateSettings();
} else { } else {
// Calculate constants // Calculate constants
//calculateRatios(); //calculateRatios();
updateBoardOptions();
} }
} }