Programming ESP32
Project #19: Time – GPS Receiver – GP-20U7 – Mk03
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#DonLucElectronics #DonLuc #Time #DS3231PrecisionRTC #SHARPMemoryDisplay #GPSReceiver #Arduino #ESP32 #SparkFunThingPlusESP32WROOM #Project #Programming #Electronics #Microcontrollers #Consultant #VideoBlog
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GPS Receiver – GP-20U7
The GP-20U7 is a compact GPS receiver with a built-in high performances all-in-one GPS chipset. The GP-20U7 accurately provides position, velocity, and time readings as well possessing high sensitivity and tracking capabilities. Thanks to the low power consumption this receiver requires, the GP-20U7 is ideal for portable applications such as tablet PCs, smart phones, and other devices requiring positioning capability.
This 56-channel GPS module, that supports a standard NMEA-0183 and uBlox 7 protocol, has low power consumption of 40mA@3.3V (max), an antenna on board, and -162dBm tracking sensitivity. With 56 channels in search mode and 22 channels “all-in-view” tracking, the GP-20U7 is quite the work horse for its size.
This one is unused and doesnt have a conection TX pin.
NMEA V3.01 Protocol
- Its output signal level is TTL: 9600bps (default), 8 bit data, 1 stop bit and no parity
- It supports the following NMEA-0183
- Messages: GGA, GLL, GSA, GSV, RMC and VTG
NMEA-0183 Output Messages
- NMEA: Record Description
- GGA: Global positoning system fixed data
- GLL: Geogrphic position – latitude / longitude
- GSA: GNSS DOP and active satellites
- GSV: GNSS satellites in view
- RMC: Recommended minimum specific GNSS data
- VTG: Course over ground and ground speed
DL2108Mk03
1 x SparkFun Thing Plus – ESP32 WROOM
1 x Adafruit SHARP Memory Display
1 x DS3231 Precision RTC FeatherWing
1 x CR1220 3V Lithium Coin Cell Battery
1 x Terminal Block Breakout FeatherWing
1 x Lithium Ion Battery – 850mAh
1 x GPS Receiver – GP-20U7
1 x Half-Size Breadboard
1 x SparkFun Cerberus USB Cable
SparkFun Thing Plus – ESP32 WROOM
SCK – Digital 13
MSI – Digital 12
SS0 – Digital 27
GRX – Digital 16
GTX – Digital 17
SDA – Digital 23
SDL – Digital 22
VIN – +3.3V
GND – GND
DL2108Mk03p.ino
/* ***** Don Luc Electronics © ***** Software Version Information Project #19: Time -GPS Receiver - GP-20U7 - Mk03 08-03 DL2108Mk03p.ino 1 x SparkFun Thing Plus - ESP32 WROOM 1 x Adafruit SHARP Memory Display 1 x DS3231 Precision RTC FeatherWing 1 x CR1220 3V Lithium Coin Cell Battery 1 x Terminal Block Breakout FeatherWing 1 x Lithium Ion Battery - 850mAh 1 x GPS Receiver - GP-20U7 1 x Half-Size Breadboard 1 x SparkFun Cerberus USB Cable */ // Include the Library Code // Wire // #include <Wire.h> // SHARP Memory Display #include <Adafruit_SharpMem.h> #include <Adafruit_GFX.h> // Date and time DS3231 RTC #include <RTClib.h> // GPS Receiver #include <TinyGPS++.h> // ESP32 Hardware Serial #include <HardwareSerial.h> // SHARP Memory Display #define SHARP_SCK 13 #define SHARP_MOSI 12 #define SHARP_SS 27 // Set the size of the display here, e.g. 144x168! Adafruit_SharpMem display(SHARP_SCK, SHARP_MOSI, SHARP_SS, 144, 168); // The currently-available SHARP Memory Display (144x168 pixels) // requires > 4K of microcontroller RAM; it WILL NOT WORK on Arduino Uno // or other <4K "classic" devices. #define BLACK 0 #define WHITE 1 // Date and time functions using a DS3231 RTC RTC_DS3231 RTC; String sDate; String sTime; // ESP32 HardwareSerial HardwareSerial tGPS(2); // GPS Receiver #define gpsRXPIN 16 // This one is unused and doesnt have a conection #define gpsTXPIN 17 // The TinyGPS++ object TinyGPSPlus gps; float TargetLat; float TargetLon; int GPSStatus = 0; String GPSSt = ""; // Software Version Information // Version String sver = "19-03"; void loop() { // Dates and Time timeRTC(); // isGPS isGPS(); // Display Date, Time, GPS isDisplayDate(); delay( 1000 ); }
getDisplay.ino
// SHARP Memory Display // SHARP Memory Display - UID void isDisplayUID() { // Text Display // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Don Luc Electronics display.setCursor(0,10); display.println( "Don Luc" ); display.setTextSize(2); display.setCursor(0,40); display.println( "Electronics" ); // Version display.setTextSize(3); display.setCursor(0,70); display.println( "Version" ); display.setTextSize(2); display.setCursor(0,100); display.println( sver ); // Refresh display.refresh(); delay( 100 ); } // Display Date void isDisplayDate() { // Text Display Date // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Date display.setCursor(0,5); display.println( sDate ); // Time display.setCursor(0,30); display.println( sTime ); // GPS Status display.setCursor(0,55); display.print( "GPS: " ); display.println( GPSSt ); // Target Latitude display.setCursor(0,75); display.println( "Latitude" ); display.setCursor(0,100); display.println( TargetLat ); // Target Longitude display.setCursor(0,120); display.println( "Longitude" ); display.setCursor(0,145); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); }
getGPS.ino
// GPS Receiver // Setup GPS void setupGPS() { // Setup GPS tGPS.begin( 9600 , SERIAL_8N1 , gpsRXPIN , gpsTXPIN ); } // isGPS void isGPS(){ // Receives NEMA data from GPS receiver // This sketch displays information every time a new sentence is correctly encoded while ( tGPS.available() > 0) if (gps.encode( tGPS.read() )) { // GPS Vector Pointer Target displayInfo(); } if (millis() > 5000 && gps.charsProcessed() < 10) { while(true); } } // GPS Vector Pointer Target void displayInfo(){ // Location if (gps.location.isValid()) { // Latitude TargetLat = gps.location.lat(); // Longitude TargetLon = gps.location.lng(); // GPS Status 2 GPSStatus = 2; GPSSt = "Yes"; } else { // GPS Status 0 GPSStatus = 0; GPSSt = "No"; } }
getRTCDS3231.ino
// DS3231 Precision RTC // Setup RTC void setupRTC() { // DS3231 Precision RTC RTC.begin(); if (! RTC.begin()) { while (1); } // Date Time DateTime now = RTC.now(); if (RTC.lostPower()) { // Following line sets the RTC to the date & time this sketch was compiled RTC.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // August 2, 2021 at 13:53:0 you would call: // RTC.adjust(DateTime(2021, 8, 2, 14, 11, 0)); } } // timeRTC void timeRTC() { // DS3231 Precision RTC sDate = ""; sTime = ""; // Date Time DateTime now = RTC.now(); // sData sDate += String(now.year(), DEC); sDate += "/"; sDate += String(now.month(), DEC); sDate += "/"; sDate += String(now.day(), DEC); // sTime sTime += String(now.hour(), DEC); sTime += ":"; sTime += String(now.minute(), DEC); sTime += ":"; sTime += String(now.second(), DEC); }
setup.ino
// Setup void setup() { // GPS Receiver // Setup GPS setupGPS(); // Set up I2C bus // Wire.begin(); // SHARP Display Start & Clear the Display display.begin(); // Clear Display display.clearDisplay(); // Display UID isDisplayUID(); // Setup RTC setupRTC(); delay( 5000 ); }
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People can contact us: https://www.donluc.com/?page_id=1927
Technology Experience
- Single-Board Microcontrollers (PIC, Arduino, Raspberry Pi,Espressif, etc…)
- IoT
- Robotics
- Research & Development (R & D)
- Desktop Applications (Windows, OSX, Linux, Multi-OS, Multi-Tier, etc…)
- Mobile Applications (Android, iOS, Blackberry, Windows Mobile, Windows CE, etc…)
- Web Applications (LAMP, Scripting, Java, ASP, ASP.NET, RoR, Wakanda, etc…)
- Social Media Programming & Integration (Facebook, Twitter, YouTube, Pinterest, etc…)
- Content Management Systems (WordPress, Drupal, Joomla, Moodle, etc…)
- Bulletin Boards (phpBB, SMF, Vanilla, jobberBase, etc…)
- eCommerce (WooCommerce, OSCommerce, ZenCart, PayPal Shopping Cart, etc…)
Instructor
- PIC Microcontrollers
- Arduino
- Raspberry Pi
- Espressif
- Robotics
- DOS, Windows, OSX, Linux, iOS, Android, Multi-OS
- Linux-Apache-PHP-MySQL
Follow Us
J. Luc Paquin – Curriculum Vitae – 2021 English & Español
https://www.jlpconsultants.com/CV/LucPaquinCVEngMk2021c.pdf
https://www.jlpconsultants.com/CV/LucPaquinCVEspMk2021c.pdf
Web: https://www.donluc.com/
Web: https://www.jlpconsultants.com/
Web: https://www.donluc.com/DLE/
Web: https://www.donluc.com/DLHackster/
Web: https://www.hackster.io/neosteam-labs
Web: https://zoom.us/
Patreon: https://www.patreon.com/DonLucElectronics
Facebook: https://www.facebook.com/neosteam.labs.9/
YouTube: https://www.youtube.com/channel/UC5eRjrGn1CqkkGfZy0jxEdA
Twitter: https://twitter.com/labs_steam
Pinterest: https://www.pinterest.com/NeoSteamLabs/
Instagram: https://www.instagram.com/neosteamlabs/
Don Luc
Project #19: Time – SHARP Memory Display – Mk02
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#DonLucElectronics #DonLuc #Time #DS3231PrecisionRTC #SHARPMemoryDisplay #Arduino #ESP32 #SparkFunThingPlusESP32WROOM #Project #Programming #Electronics #Microcontrollers #Consultant #VideoBlog
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Adafruit SHARP Memory Display Breakout – 1.3 Inches – 168 Pixels x 144 Pixels Monochrome
The 1.3 inches 168 pixels x 144 pixels SHARP Memory LCD display is a cross between an eInk display and an LCD. It has the ultra-low power usage of eInk and the fast-refresh rates of an LCD. This model has a gray background, and pixels show up as black-on-gray for a nice e-reader type display. It does not have a backlight, but it is daylight readable. For dark/night reading you may need to illuminate the LCD area with external LEDs.
The display is write only which means that it only needs 3 pins to send data. However, the downside of a write-only display is that the entire 168×144 bits must be buffered by the microcontroller driver. That means you cannot use this with an ATmega328 or ATmega32u4. You must use a high-RAM chip such as ATSAMD21, Teensy 3, ESP8266, ESP32, etc. On those chips, this display works great and looks wonderful.
DL2108Mk02
1 x SparkFun Thing Plus – ESP32 WROOM
1 x Adafruit SHARP Memory Display
1 x DS3231 Precision RTC FeatherWing
1 x CR1220 3V Lithium Coin Cell Battery
1 x Terminal Block Breakout FeatherWing
1 x Lithium Ion Battery – 850mAh
1 x Half-Size Breadboard
1 x SparkFun Cerberus USB Cable
SparkFun Thing Plus – ESP32 WROOM
SCK – Digital 13
MSI – Digital 12
SS0 – Digital 27
SDA – Digital 23
SDL – Digital 22
VIN – +3.3V
GND – GND
DL2108Mk02p.ino
/* ***** Don Luc Electronics © ***** Software Version Information Project #19: Time -SHARP Memory Display - Mk02 08-02 DL2108Mk02p.ino 1 x SparkFun Thing Plus - ESP32 WROOM 1 x Adafruit SHARP Memory Display 1 x DS3231 Precision RTC FeatherWing 1 x CR1220 3V Lithium Coin Cell Battery 1 x Terminal Block Breakout FeatherWing 1 x Qwiic Cable - 50mm 1 x Lithium Ion Battery - 850mAh 1 x Half-Size Breadboard 1 x SparkFun Cerberus USB Cable */ // Include the Library Code #include <Wire.h> // SHARP Memory Display #include <Adafruit_SharpMem.h> #include <Adafruit_GFX.h> // Date and time DS3231 RTC #include <RTClib.h> // SHARP Memory Display #define SHARP_SCK 13 #define SHARP_MOSI 12 #define SHARP_SS 27 // Set the size of the display here, e.g. 144x168! Adafruit_SharpMem display(SHARP_SCK, SHARP_MOSI, SHARP_SS, 144, 168); // The currently-available SHARP Memory Display (144x168 pixels) // requires > 4K of microcontroller RAM; it WILL NOT WORK on Arduino Uno // or other <4K "classic" devices. #define BLACK 0 #define WHITE 1 // Set this to 1000 to get _about_ 1 second timing const int CLOCK_SPEED = 1000; // Last Draw unsigned long lastDraw = 0; // Date and time functions using a DS3231 RTC RTC_DS3231 RTC; String sDate; String sTime; // Software Version Information // Version String sver = "19-02"; void loop() { // Check if we need to update date, time if (lastDraw + CLOCK_SPEED < millis()) { // Last Draw lastDraw = millis(); // Dates and Time timeRTC(); // is OLED //isOLED(); isDisplayDate(); } }
getDisplay.ino
// SHARP Memory Display // SHARP Memory Display - UID void isDisplayUID() { // Text Display // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Don Luc Electronics display.setCursor(0,10); display.println( "Don Luc" ); display.setTextSize(2); display.setCursor(0,40); display.println( "Electronics" ); // Version display.setTextSize(3); display.setCursor(0,70); display.println( "Version" ); display.setTextSize(2); display.setCursor(0,100); display.println( sver ); // Refresh display.refresh(); delay( 100 ); } // Display Date void isDisplayDate() { // Text Display Date // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Date display.setCursor(0,5); display.println( sDate ); // Time display.setCursor(0,30); display.println( sTime ); // Refresh display.refresh(); delay( 100 ); }
getRTCDS3231.ino
// DS3231 Precision RTC // Setup RTC void setupRTC() { // DS3231 Precision RTC RTC.begin(); if (! RTC.begin()) { while (1); } DateTime now = RTC.now(); if (RTC.lostPower()) { // Following line sets the RTC to the date & time this sketch was compiled RTC.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // August 2, 2021 at 13:53:0 you would call: // RTC.adjust(DateTime(2021, 8, 2, 14, 11, 0)); } } // timeRTC void timeRTC() { // DS3231 Precision RTC sDate = ""; sTime = ""; // Date Time DateTime now = RTC.now(); // sData sDate += String(now.year(), DEC); sDate += "/"; sDate += String(now.month(), DEC); sDate += "/"; sDate += String(now.day(), DEC); // sTime sTime += String(now.hour(), DEC); sTime += ":"; sTime += String(now.minute(), DEC); sTime += ":"; sTime += String(now.second(), DEC); }
setup.ino
// Setup void setup() { // Give display time to power on delay(100); // Set up I2C bus Wire.begin(); // SHARP Display Start & Clear the Display display.begin(); // Clear Display display.clearDisplay(); // Display UID isDisplayUID(); // Setup RTC setupRTC(); delay( 5000 ); }
People can contact us: https://www.donluc.com/?page_id=1927
Technology Experience
- Single-Board Microcontrollers (PIC, Arduino, Raspberry Pi,Espressif, etc…)
- IoT
- Robotics
- Research & Development (R & D)
- Desktop Applications (Windows, OSX, Linux, Multi-OS, Multi-Tier, etc…)
- Mobile Applications (Android, iOS, Blackberry, Windows Mobile, Windows CE, etc…)
- Web Applications (LAMP, Scripting, Java, ASP, ASP.NET, RoR, Wakanda, etc…)
- Social Media Programming & Integration (Facebook, Twitter, YouTube, Pinterest, etc…)
- Content Management Systems (WordPress, Drupal, Joomla, Moodle, etc…)
- Bulletin Boards (phpBB, SMF, Vanilla, jobberBase, etc…)
- eCommerce (WooCommerce, OSCommerce, ZenCart, PayPal Shopping Cart, etc…)
Instructor
- PIC Microcontrollers
- Arduino
- Raspberry Pi
- Espressif
- Robotics
- DOS, Windows, OSX, Linux, iOS, Android, Multi-OS
- Linux-Apache-PHP-MySQL
Follow Us
J. Luc Paquin – Curriculum Vitae – 2021 English & Español
https://www.jlpconsultants.com/CV/LucPaquinCVEngMk2021c.pdf
https://www.jlpconsultants.com/CV/LucPaquinCVEspMk2021c.pdf
Web: https://www.donluc.com/
Web: https://www.jlpconsultants.com/
Web: https://www.donluc.com/DLE/
Web: https://www.donluc.com/DLHackster/
Web: https://www.hackster.io/neosteam-labs
Web: https://zoom.us/
Patreon: https://www.patreon.com/DonLucElectronics
Facebook: https://www.facebook.com/neosteam.labs.9/
YouTube: https://www.youtube.com/channel/UC5eRjrGn1CqkkGfZy0jxEdA
Twitter: https://twitter.com/labs_steam
Pinterest: https://www.pinterest.com/NeoSteamLabs/
Instagram: https://www.instagram.com/neosteamlabs/
Don Luc
Project #19: Time – DS3231 Precision RTC – Mk01
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#DonLucElectronics #DonLuc #Time #DS3231PrecisionRTC #Arduino #ESP32 #SparkFunThingPlusESP32WROOM #Project #Programming #Electronics #Microcontrollers #Consultant #VideoBlog
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DS3231 Precision RTC FeatherWing
A Feather board without ambition is a Feather board without FeatherWings. This is the DS3231 Precision RTC FeatherWing: it adds an extremely accurate I2C-integrated Real Time Clock (RTC) with a Temperature Compensated Crystal Oscillator (TCXO) to any Feather main board. This RTC is the most precise you can get in a small, low power package. Most RTCs use an external 32kHz timing crystal that is used to keep time with low current draw. And that’s all well and good, but those crystals have slight drift, particularly when the temperature changes. This RTC is in a beefy package because the crystal is inside the chip. And right next to the integrated crystal is a temperature sensor. That sensor compensates for the frequency changes by adding or removing clock ticks so that the timekeeping stays on schedule.
SparkFun Micro OLED Breakout (Qwiic)
The SparkFun Qwiic Micro OLED Breakout is a Qwiic-enabled version of our popular Micro OLED display. The small monochrome, blue-on-black OLED screen presents incredibly clear images for your viewing pleasure. The OLED display is crisp, and you can fit a deceivingly large amount of graphics on there. This breakout is perfect for adding graphics to your next project and displaying diagnostic information without resorting to a serial output, all with the ease of use of our own Qwiic Connect System.
DL2108Mk01
1 x SparkFun Thing Plus – ESP32 WROOM
1 x SparkFun Micro OLED Breakout (Qwiic)
1 x DS3231 Precision RTC FeatherWing
1 x CR1220 3V Lithium Coin Cell Battery
1 x Terminal Block Breakout FeatherWing
1 x Qwiic Cable – 50mm
1 x Lithium Ion Battery – 850mAh
1 x Half-Size Breadboard
1 x SparkFun Cerberus USB Cable
SparkFun Thing Plus – ESP32 WROOM
DIS – Qwiic
SDA – Digital 23
SDL – Digital 22
VIN – +3.3V
GND – GND
DL2108Mk01p.ino
/* ***** Don Luc Electronics © ***** Software Version Information Project #19: Time - DS3231 Precision RTC - Mk01 08-01 DL2108Mk01p.ino 1 x SparkFun Thing Plus - ESP32 WROOM 1 x SparkFun Micro OLED Breakout (Qwiic) 1 x DS3231 Precision RTC FeatherWing 1 x CR1220 3V Lithium Coin Cell Battery 1 x Terminal Block Breakout FeatherWing 1 x Qwiic Cable - 50mm 1 x Lithium Ion Battery - 850mAh 1 x SparkFun Cerberus USB Cable */ // Include the Library Code #include <Wire.h> // OLED #include <SFE_MicroOLED.h> // Date and time DS3231 RTC #include <RTClib.h> // OLED // DC Jumper #define DC_JUMPER 1 // Optional - Connect RST on display to pin 9 on Arduino #define PIN_RESET 9 MicroOLED oled(PIN_RESET, DC_JUMPER); // Set this to 1000 to get _about_ 1 second timing const int CLOCK_SPEED = 1000; // Last Draw unsigned long lastDraw = 0; // Date and time functions using a DS3231 RTC RTC_DS3231 RTC; String sDate; String sTime; // Software Version Information // Version String sver = "19-01"; void loop() { // Check if we need to update date, time if (lastDraw + CLOCK_SPEED < millis()) { // Last Draw lastDraw = millis(); // Dates and Time timeRTC(); // is OLED isOLED(); } }
getOLED.ino
// OLED // Setup OLED void setupOLED(){ // Initialize the OLED oled.begin(); // Clear the display's internal memory oled.clear(PAGE); // Clear the library's display buffer oled.clear(ALL); // Display what's in the buffer oled.display(); } // isOLED void isOLED(){ // Clear the buffer oled.clear(PAGE); // Set font to type 0 oled.setFontType(0); // Date // Set cursor to top-left oled.setCursor(0, 18); oled.print( sDate ); // Time // Set cursor to top-left oled.setCursor(0, 32); oled.print( sTime ); // Draw the memory buffer oled.display(); }
getRTCDS3231.ino
// DS3231 Precision RTC // Setup RTC void setupRTC() { // DS3231 Precision RTC RTC.begin(); if (! RTC.begin()) { while (1); } DateTime now = RTC.now(); if (RTC.lostPower()) { // Following line sets the RTC to the date & time this sketch was compiled RTC.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // August 2, 2021 at 13:53:0 you would call: // RTC.adjust(DateTime(2021, 8, 2, 14, 11, 0)); } } // timeRTC void timeRTC() { // DS3231 Precision RTC sDate = ""; sTime = ""; // Date Time DateTime now = RTC.now(); // sData sDate += String(now.year(), DEC); sDate += "/"; sDate += String(now.month(), DEC); sDate += "/"; sDate += String(now.day(), DEC); // sTime sTime += String(now.hour(), DEC); sTime += ":"; sTime += String(now.minute(), DEC); sTime += ":"; sTime += String(now.second(), DEC); }
setup.ino
// Setup void setup() { // Give display time to power on delay(100); // Set up I2C bus Wire.begin(); // Initialize the OLED setupOLED(); // Setup RTC setupRTC(); }
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People can contact us: https://www.donluc.com/?page_id=1927
Technology Experience
- Single-Board Microcontrollers (PIC, Arduino, Raspberry Pi,Espressif, etc…)
- IoT
- Robotics
- Research & Development (R & D)
- Desktop Applications (Windows, OSX, Linux, Multi-OS, Multi-Tier, etc…)
- Mobile Applications (Android, iOS, Blackberry, Windows Mobile, Windows CE, etc…)
- Web Applications (LAMP, Scripting, Java, ASP, ASP.NET, RoR, Wakanda, etc…)
- Social Media Programming & Integration (Facebook, Twitter, YouTube, Pinterest, etc…)
- Content Management Systems (WordPress, Drupal, Joomla, Moodle, etc…)
- Bulletin Boards (phpBB, SMF, Vanilla, jobberBase, etc…)
- eCommerce (WooCommerce, OSCommerce, ZenCart, PayPal Shopping Cart, etc…)
Instructor
- PIC Microcontrollers
- Arduino
- Raspberry Pi
- Espressif
- Robotics
- DOS, Windows, OSX, Linux, iOS, Android, Multi-OS
- Linux-Apache-PHP-MySQL
Follow Us
J. Luc Paquin – Curriculum Vitae – 2021 English & Español
https://www.jlpconsultants.com/CV/LucPaquinCVEngMk2021c.pdf
https://www.jlpconsultants.com/CV/LucPaquinCVEspMk2021c.pdf
Web: https://www.donluc.com/
Web: https://www.jlpconsultants.com/
Web: https://www.donluc.com/DLE/
Web: https://www.donluc.com/DLHackster/
Web: https://www.hackster.io/neosteam-labs
Web: https://zoom.us/
Patreon: https://www.patreon.com/DonLucElectronics
Facebook: https://www.facebook.com/neosteam.labs.9/
YouTube: https://www.youtube.com/channel/UC5eRjrGn1CqkkGfZy0jxEdA
Twitter: https://twitter.com/labs_steam
Pinterest: https://www.pinterest.com/NeoSteamLabs/
Instagram: https://www.instagram.com/neosteamlabs/
Don Luc
Project #16: Sound – Dayton Audio RS75T-8 – Mk20
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#DonLucElectronics #DonLuc #Sound #Arduino #ESP32 #SparkFunThingPlusESP32WROOM #SparkFunQwiicMP3 #DaytonAudioRS75T #Project #Programming #Electronics #Microcontrollers #Consultant #VideoBlog
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Dayton Audio RS75T-8 3″ Reference Full-Range Driver Truncated Frame
The Dayton Audio Reference Series sets a new standard of value in high-performance loudspeaker drivers. Incorporating a low-distortion motor system with a copper ring, a copper cap, and an aluminum phase plug, the RS75T-8 can outperform “boutique” drivers that cost several times the price. The driver’s truncated frame makes it ideal for line arrays and ultra-compact MTM designs requiring minimal driver-to-driver spacing. Its low-distortion characteristics and smooth response provide exceptional clarity, detail, and dynamics. Features a black anodized cone, heavy-duty 4-hole cast frame, low-loss rubber surround, and gold terminals.
DL2107Mk02
1 x SparkFun Thing Plus – ESP32 WROOM
1 x SparkFun Qwiic MP3 Trigger
1 x microSD Card – 2GB
1 x Panel Mount 10K potentiometer
1 x Knob
1 x Slide Switch
2 x Rocker Switch – SPST (Round)
1 x Qwiic Cable – 50mm
1 x Dayton Audio Reference 3″ Full-Range Drive
1 x Lithium Ion Battery – 850mAh
1 x JST Jumper 2 Wire Assembly
2 x Screw Terminals 5mm Pitch (2-Pin)
1 x Acrylic Blue 5.75in x 3.75in x 1/8in
1 x Acrylic Purple 5.75in x 3.75in x 1/8in
24 x Screw – 4-40
4 x Nut – Nylon Locknut 4-40
6 x Standoff – Metal 4-40 – 3/8″
8 x Standoff – Metal 4-40 – 1″
18 x Wire Solid Core – 22 AWG
1 x Adafruit Perma-Prote Half-Size Breadboard
1 x SparkFun Cerberus USB Cable
SparkFun Thing Plus – ESP32 WROOM
PO1 – Analog A0
SW0 – Digital 21
SW1 – Digital 17
VIN – +3.3V
GND – GND
DL2107Mk02p.ino
/* ***** Don Luc Electronics © ***** Software Version Information #16 - Sound - Dayton Audio RS75T-8 - Mk20 07-02 DL2107Mk02p.ino 1 x SparkFun Thing Plus - ESP32 WROOM 1 x SparkFun Qwiic MP3 Trigger 1 x microSD Card - 2GB 1 x Panel Mount 10K potentiometer 1 x Knob 1 x Slide Switch 2 x Rocker Switch - SPST (Round) 1 x Qwiic Cable - 50mm 1 x Dayton Audio Reference 3" Full-Range Drive 1 x Lithium Ion Battery - 850mAh 1 x JST Jumper 2 Wire Assembly 2 x Screw Terminals 5mm Pitch (2-Pin) 1 x Acrylic Blue 5.75in x 3.75in x 1/8in 1 x Acrylic Purple 5.75in x 3.75in x 1/8in 24 x Screw - 4-40 4 x Nut - Nylon Locknut 4-40 6 x Standoff - Metal 4-40 - 3/8" 8 x Standoff - Metal 4-40 - 1" 18 x Wire Solid Core - 22 AWG 1 x Adafruit Perma-Prote Half-Size Breadboard 1 x SparkFun Cerberus USB Cable */ // Include the Library Code // Wire communicate with I2C / TWI devices #include <Wire.h> // SparkFun MP3 Trigger #include "SparkFun_Qwiic_MP3_Trigger_Arduino_Library.h" // SparkFun MP3 Trigger MP3TRIGGER mp3; int iSongCount = 0; int x = 0; // Volume int iVolume = A0; int iVolumeLevel = 0; // EQ Setting Normal byte bEQSetting = 0; // Play Next const int iPlayNext = 21; // Variable for reading the iPlayNext status int iPlayNextState = 0; // Play Previous const int iPlayPrevious = 17; // Variable for reading the iPlayPrevious status int iPlayPreviousState = 0; // Software Version Information String sver = "16-20"; void loop() { if (mp3.isPlaying() == false) { if ( x > iSongCount ) { x = 0; } else { x = x + 1; } // Play Track mp3.playTrack( x ); } else { // Volume isVolume(); // Play Next isPlayNext(); // Play Previous isPlayPrevious(); } }
getMP3.ino
// MP3 // Setup MP3 void isSetupMP3(){ // Check to see if Qwiic MP3 is present on the bus if (mp3.begin() == false) { // Qwiic MP3 failed to respond. Please check wiring and possibly the I2C address. Freezing... while (1); } if (mp3.hasCard() == false) { // Qwiic MP3 is missing its SD card. Freezing... while (1); } // Song Count iSongCount = mp3.getSongCount(); // EQ Setting Classic bEQSetting = mp3.getEQ(); // Initialize the iPlayNext pinMode( iPlayNext, INPUT); // Initialize the iPlayPrevious pinMode( iPlayPrevious, INPUT); } // Volume void isVolume() { // Volume iVolumeLevel = analogRead( iVolume ); // (0-1023 for 10 bits or 0-4095 for 12 bits) iVolumeLevel = map(iVolumeLevel, 0, 4095, 0, 31); // Volume can be 0 (off) to 31 (max) mp3.setVolume( iVolumeLevel ); } // Play Next void isPlayNext() { // Read the state of the iPlayNext value iPlayNextState = digitalRead( iPlayNext ); if ( iPlayNextState == HIGH ) { mp3.stop(); if ( x > iSongCount ) { x = 0; } else { x = x + 1; } // Play Track mp3.playTrack( x ); } } // Play Previous void isPlayPrevious() { // Read the state of the iPlayPrevious value iPlayPreviousState = digitalRead( iPlayPrevious ); if ( iPlayPreviousState == HIGH ) { mp3.stop(); if ( x > iSongCount ) { x = 0; } else { x = x - 1; } // Play Track mp3.playTrack( x ); } }
setup.ino
// Setup void setup() { // Wire communicate with I2C / TWI devices Wire.begin(); // SparkFun MP3 Trigger Setup isSetupMP3(); }
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People can contact us: https://www.donluc.com/?page_id=1927
Technology Experience
- Single-Board Microcontrollers (PIC, Arduino, Raspberry Pi,Espressif, etc…)
- Robotics
- Research & Development (R & D)
- Desktop Applications (Windows, OSX, Linux, Multi-OS, Multi-Tier, etc…)
- Mobile Applications (Android, iOS, Blackberry, Windows Mobile, Windows CE, etc…)
- Web Applications (LAMP, Scripting, Java, ASP, ASP.NET, RoR, Wakanda, etc…)
- Social Media Programming & Integration (Facebook, Twitter, YouTube, Pinterest, etc…)
- Content Management Systems (WordPress, Drupal, Joomla, Moodle, etc…)
- Bulletin Boards (phpBB, SMF, Vanilla, jobberBase, etc…)
- eCommerce (WooCommerce, OSCommerce, ZenCart, PayPal Shopping Cart, etc…)
Instructor
- PIC Microcontrollers
- Arduino
- Raspberry Pi
- Espressif
- Robotics
- DOS, Windows, OSX, Linux, iOS, Android, Multi-OS
- Linux-Apache-PHP-MySQL
Follow Us
J. Luc Paquin – Curriculum Vitae – 2021 English & Español
https://www.jlpconsultants.com/CV/LucPaquinCVEngMk2021c.pdf
https://www.jlpconsultants.com/CV/LucPaquinCVEspMk2021c.pdf
Web: https://www.donluc.com/
Web: http://www.jlpconsultants.com/
Web: https://www.donluc.com/DLE/
Web: https://www.donluc.com/DLHackster/
Web: https://www.hackster.io/neosteam-labs
Web: https://zoom.us/
Patreon: https://www.patreon.com/DonLucElectronics
Facebook: https://www.facebook.com/neosteam.labs.9/
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Don Luc
Project #16: Sound – SparkFun Thing Plus ESP32 WROOM – Mk19
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#DonLucElectronics #DonLuc #Sound #Arduino #ESP32 #SparkFunThingPlusESP32WROOM #SparkFunQwiicMP3 #Project #Programming #Electronics #Microcontrollers #Consultant #VideoBlog
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SparkFun Thing Plus – ESP32 WROOM
The SparkFun ESP32 Thing Plus is the next step to get started with Espressif IoT ideations while still enjoying all the amenities of the original ESP32 Thing. Espressif’s ESP32 WROOM is a powerful WiFi and Bluetooth MCU module that targets a wide variety of applications. At the core of this module is the ESP32-D0WDQ6 chip which is designed to be both scalable and adaptive. To make the Thing Plus even easier to use, we’ve moved a few pins around to make the board Feather compatible and it utilizes our handy Qwiic Connect System which means no soldering or shields are required to connect it to the rest of your system. A JST connector to plug in a LiPo battery.
SparkFun Qwiic MP3 Trigger
Sometimes you just need an MP3 to play. The SparkFun Qwiic MP3 Trigger takes care of all the necessary requirements, all you need to do is send a simple I2C command and listen to whatever is on your micro SD card. The contents of the microSD card appears as a jump drive. Simply plug in the Qwiic MP3 Trigger and you’ll be transferring MP3s, no need for drivers and no need for WAV or Vorbis conversion. Your supplied speaker is boosted by a Class-D mono amplifier capable of outputting up to 1.4W making it capable of being incredibly loud. Volume is software selectable between 32 levels.
DL2107Mk01
1 x SparkFun Thing Plus – ESP32 WROOM
1 x SparkFun Qwiic MP3 Trigger
1 x microSD Card – 2GB
1 x Panel Mount 1K potentiometer
1 x Knob
1 x Qwiic Cable – 100mm
1 x Dayton Audio Reference 3″ Full-Range Drive
2 x Wire Stranded Core – 18 AWG
7 x Wire Solid Core – 22 AWG
1 x Full-Size Breadboard
1 x SparkFun Cerberus USB Cable
SparkFun Thing Plus – ESP32 WROOM
PO1 – Analog A0
SW0 – Digital 21
SW1 – Digital 17
VIN – +3.3V
GND – GND
DL2107Mk01p.ino
// ***** Don Luc Electronics © ***** // Software Version Information // #16 - Sound - SparkFun Thing Plus ESP32 WROOM - Mk19 // 07-01 // DL2107Mk01p.ino // 1 x SparkFun RedBoard Qwiic // 1 x SparkFun Qwiic MP3 Trigger // 1 x microSD Card - 2GB // 1 x Panel Mount 1K potentiometer // 1 x Knob // 1 x Qwiic Cable - 100mm // 1 x Dayton Audio Reference 3" Full-Range Drive // 2 x Wire Stranded Core - 18 AWG // 7 x Wire Solid Core - 22 AWG // 1 x Full-Size Breadboard // 1 x SparkFun Cerberus USB Cable // Include the Library Code // Wire communicate with I2C / TWI devices #include <Wire.h> // SparkFun MP3 Trigger #include "SparkFun_Qwiic_MP3_Trigger_Arduino_Library.h" // SparkFun MP3 Trigger MP3TRIGGER mp3; int iSongCount = 0; int x = 0; // Volume int iVolume = A0; int iVolumeLevel = 0; // EQ Setting Normal byte bEQSetting = 0; // Play Next const int iPlayNext = 21; // Variable for reading the iPlayNext status int iPlayNextState = 0; // Play Previous const int iPlayPrevious = 17; // Variable for reading the iPlayPrevious status int iPlayPreviousState = 0; // Software Version Information String sver = "16-19"; void loop() { if (mp3.isPlaying() == false) { if ( x > iSongCount ) { x = 0; } else { x = x + 1; } // Play Track mp3.playTrack( x ); } else { // Volume isVolume(); // Play Next isPlayNext(); // Play Previous isPlayPrevious(); } }
getMP3.ino
// MP3 // Setup MP3 void isSetupMP3(){ // Check to see if Qwiic MP3 is present on the bus if (mp3.begin() == false) { // Qwiic MP3 failed to respond. Please check wiring and possibly the I2C address. Freezing... while (1); } if (mp3.hasCard() == false) { // Qwiic MP3 is missing its SD card. Freezing... while (1); } // Song Count iSongCount = mp3.getSongCount(); // EQ Setting Classic bEQSetting = mp3.getEQ(); // Initialize the iPlayNext pinMode( iPlayNext, INPUT); // Initialize the iPlayPrevious pinMode( iPlayPrevious, INPUT); } // Volume void isVolume() { // Volume iVolumeLevel = analogRead( iVolume ); // (0-1023 for 10 bits or 0-4095 for 12 bits) iVolumeLevel = map(iVolumeLevel, 0, 4095, 0, 31); // Volume can be 0 (off) to 31 (max) mp3.setVolume( iVolumeLevel ); } // Play Next void isPlayNext() { // Read the state of the iPlayNext value iPlayNextState = digitalRead( iPlayNext ); if ( iPlayNextState == HIGH ) { mp3.stop(); if ( x > iSongCount ) { x = 0; } else { x = x + 1; } // Play Track mp3.playTrack( x ); } } // Play Previous void isPlayPrevious() { // Read the state of the iPlayPrevious value iPlayPreviousState = digitalRead( iPlayPrevious ); if ( iPlayPreviousState == HIGH ) { mp3.stop(); if ( x > iSongCount ) { x = 0; } else { x = x - 1; } // Play Track mp3.playTrack( x ); } }
setup.ino
// Setup void setup() { // Wire communicate with I2C / TWI devices Wire.begin(); // SparkFun MP3 Trigger Setup isSetupMP3(); }
——
People can contact us: https://www.donluc.com/?page_id=1927
Technology Experience
- Single-Board Microcontrollers (PIC, Arduino, Raspberry Pi,Espressif, etc…)
- Robotics
- Research & Development (R & D)
- Desktop Applications (Windows, OSX, Linux, Multi-OS, Multi-Tier, etc…)
- Mobile Applications (Android, iOS, Blackberry, Windows Mobile, Windows CE, etc…)
- Web Applications (LAMP, Scripting, Java, ASP, ASP.NET, RoR, Wakanda, etc…)
- Social Media Programming & Integration (Facebook, Twitter, YouTube, Pinterest, etc…)
- Content Management Systems (WordPress, Drupal, Joomla, Moodle, etc…)
- Bulletin Boards (phpBB, SMF, Vanilla, jobberBase, etc…)
- eCommerce (WooCommerce, OSCommerce, ZenCart, PayPal Shopping Cart, etc…)
Instructor
- PIC Microcontrollers
- Arduino
- Raspberry Pi
- Espressif
- Robotics
- DOS, Windows, OSX, Linux, iOS, Android, Multi-OS
- Linux-Apache-PHP-MySQL
Follow Us
J. Luc Paquin – Curriculum Vitae – 2021 English & Español
https://www.jlpconsultants.com/CV/LucPaquinCVEngMk2021c.pdf
https://www.jlpconsultants.com/CV/LucPaquinCVEspMk2021c.pdf
Web: https://www.donluc.com/
Web: http://www.jlpconsultants.com/
Web: https://www.donluc.com/DLE/
Web: https://www.donluc.com/DLHackster/
Web: https://www.hackster.io/neosteam-labs
Web: https://zoom.us/
Patreon: https://www.patreon.com/DonLucElectronics
Facebook: https://www.facebook.com/neosteam.labs.9/
YouTube: https://www.youtube.com/channel/UC5eRjrGn1CqkkGfZy0jxEdA
Twitter: https://twitter.com/labs_steam
Pinterest: https://www.pinterest.com/NeoSteamLabs/
Instagram: https://www.instagram.com/neosteamlabs/
Don Luc
Project #15: Environment – PIR Motion Sensor – Mk12
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#DonLuc #Environment #ESP32 #MQ #GPS #EMF #PIR #SparkFun #Adafruit #Pololu #Fritzing #Programming #Arduino #Consultant #Electronics #Microcontrollers #Vlog #Aphasia
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PIR Motion Sensor (JST)
SparkFun Item: SEN-13285
This is a simple to use motion sensor. Power it up and wait 1-2 seconds for the sensor to get a snapshot of the still room. If anything moves after that period, the ‘alarm’ pin will go low. The alarm pin is an open collector meaning you will need a pull up resistor on the alarm pin. The open drain setup allows multiple motion sensors to be connected on a single input pin. If any of the motion sensors go off, the input pin will be pulled low.
We’ve finally updated the connector! Gone is the old “odd” connector, now you will find a common 3-pin JST! This makes the PIR Sensor much more accessible for whatever your project may need. Red = Power, White = Ground, and Black = Alarm.
DL2006Mk02
1 x SparkFun Thing Plus – ESP32 WROOM
1 x Adafruit SHARP Memory Display
1 x SparkFun Environmental Combo Breakout – CCS811/BME280
1 x Adafruit Adalogger FeatherWing – RTC + SD
1 x SparkFun GPS Receiver – GP-20U7
1 x CR1220 12mm Lithium Battery
1 x 32Gb microSD Card
1 x Mountable Slide Switch
1 x SparkFun Rotary Switch – 10 Position
1 x Black Knob
1 x Breadboard Solderable
4 x Pololu Carrier for MQ Gas Sensors
1 x SparkFun Hydrogen Gas Sensor – MQ-8
1 x Pololu Carbon Monoxide & Flammable Gas Sensor – MQ-9
1 x SparkFun Carbon Monoxide Gas Sensor – MQ-7
1 x SparkFun Alcohol Gas Sensor – MQ-3
1 x Telescopic Antenna SMA – 300 MHz to 1.1 GHz (ANT700)
1 x SMA Connector
1 x Humidity and Temperature Sensor – RHT03
1 x PIR Motion Sensor (JST)
1 x Qwiic Cable – 100mm
1 x LED Green
11 x 1K Ohm
1 x 4.7K Ohm
2 x 10K Ohm
1 x 20k Ohm
1 x 200k Ohm
1 x 3.3m Ohm
12 x Jumper Wires 3in M/M
13 x Jumper Wires 6in M/M
20 x Wire Solid Core – 22 AWG
2 x Full-Size Breadboard
1 x SparkFun Cerberus USB Cable
1 x DC Power Supply
SparkFun Thing Plus – ESP32 WROOM
LEG – Digital 21
SCK – Digital 13
MOS – Digital 12
SSD – Digital 27
SDA – Digital 23
SCL – Digital 22
SD1 – Digital 33
SC2 – Digital 5
MO2 – Digital 18
MI2 – Digital 19
SS1 – Digital 16
ROT – Analog A1
MH1 – Analog A0
MC1 – Analog A2
MC2 – Analog A3
MA1 – Analog A4
EMF – Analog A5
GPS – Digital 14
RHT – Digital 15
PIR – Digital 17
VIN – +3.3V
GND – GND
DL2006Mk02p.ino
// ***** Don Luc Electronics © ***** // Software Version Information // Project #15: Environment - PIR Motion Sensor (JST) - Mk12 // 06-02 // DL2006Mk02p.ino 15-12 // EEPROM with Unique ID // 1 x SparkFun Thing Plus - ESP32 WROOM // 1 x Adafruit SHARP Memory Display // 1 x SparkFun Environmental Combo Breakout - CCS811/BME280 // 1 x Adafruit Adalogger FeatherWing - RTC + SD // 1 x SparkFun GPS Receiver - GP-20U7 // 1 x CR1220 12mm Lithium Battery // 1 x 32Gb microSD Card // 1 x Mountable Slide Switch // 1 x SparkFun Rotary Switch - 10 Position // 1 x Black Knob // 1 x Breadboard Solderable // 4 x Pololu Carrier for MQ Gas Sensors // 1 x SparkFun Hydrogen Gas Sensor - MQ-8 // 1 x Pololu Carbon Monoxide & Flammable Gas Sensor - MQ-9 // 1 x SparkFun Carbon Monoxide Gas Sensor - MQ-7 // 1 x SparkFun Alcohol Gas Sensor - MQ-3 // 1 x Telescopic Antenna SMA - 300 MHz to 1.1 GHz (ANT700) // 1 x SMA Connector // 1 x Humidity and Temperature Sensor - RHT03 // 1 x PIR Motion Sensor (JST) // 1 x Qwiic Cable - 100mm // 1 x LED Green // 11 x 1K Ohm // 1 x 4.7K Ohm // 2 x 10K Ohm // 1 x 20k Ohm // 1 x 200k Ohm // 1 x 3.3m Ohm // 12 x Jumper Wires 3in M/M // 13 x Jumper Wires 6in M/M // 20 x Wire Solid Core - 22 AWG // 2 x Full-Size Breadboard // 1 x SparkFun Cerberus USB Cable // 1 x DC Power Supply // Include the Library Code // EEPROM Library to Read and Write EEPROM with Unique ID for Unit #include "EEPROM.h" // Wire #include <Wire.h> // SHARP Memory Display #include <Adafruit_SharpMem.h> #include <Adafruit_GFX.h> // SparkFun CCS811 - eCO2 & tVOC #include <SparkFunCCS811.h> // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure #include <SparkFunBME280.h> // Date and Time #include "RTClib.h" // SD Card #include "FS.h" #include "SD.h" #include "SPI.h" // GPS Receiver #include <TinyGPS++.h> // Hardware Serial #include <HardwareSerial.h> // RHT Humidity and Temperature Sensor #include <SparkFun_RHT03.h> // LED Green int iLEDGreen = 21; // SHARP Memory Display // any pins can be used #define SHARP_SCK 13 #define SHARP_MOSI 12 #define SHARP_SS 27 // Set the size of the display here - 144x168 Adafruit_SharpMem display(SHARP_SCK, SHARP_MOSI, SHARP_SS, 144, 168); // The currently-available SHARP Memory Display (144x168 pixels) // requires > 4K of microcontroller RAM; it WILL NOT WORK on Arduino Uno // or other <4K "classic" devices! #define BLACK 0 #define WHITE 1 // 1/2 of lesser of display width or height int minorHalfSize; // SparkFun CCS811 - eCO2 & tVOC // Default I2C Address #define CCS811_ADDR 0x5B CCS811 myCCS811(CCS811_ADDR); float CCS811CO2 = 0; float CCS811TVOC = 0; // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure BME280 myBME280; float BMEtempC = 0; float BMEhumid = 0; float BMEaltitudeM = 0; float BMEpressure = 0; // Date and Time // PCF8523 Precision RTC RTC_PCF8523 rtc; String dateRTC = ""; String timeRTC = ""; // microSD Card const int chipSelect = 33; String zzzzzz = ""; // Mountable Slide Switch int iSS1 = 16; // State int iSS1State = 0; // ESP32 HardwareSerial HardwareSerial tGPS(2); // GPS Receiver #define gpsRXPIN 14 // This one is unused and doesnt have a conection #define gpsTXPIN 32 // The TinyGPS++ object TinyGPSPlus gps; float TargetLat; float TargetLon; int GPSStatus = 0; // Rotary Switch - 10 Position // Number 1 => 10 int iRotNum = A0; // iRotVal - Value int iRotVal = 0; // Number int z = 0; int x = 0; // Gas Sensors MQ // Hydrogen Gas Sensor - MQ-8 int iMQ8 = A1; int iMQ8Raw = 0; int iMQ8ppm = 0; // Two points are taken from the curve in datasheet // With these two points, a line is formed which is "approximately equivalent" to the original curve float H2Curve[3] = {2.3, 0.93,-1.44}; // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int iMQ9 = A2; int iMQ9Raw = 0; int iMQ9ppm = 0; // Carbon Monoxide Gas Sensor - MQ-7 int iMQ7 = A3; int iMQ7Raw = 0; int iMQ7ppm = 0; // Alcohol Gas Sensor - MQ-3 int iMQ3 = A4; int iMQ3Raw = 0; int iMQ3ppm = 0; // EMF Meter (Single Axis) int iEMF = A5; // Raise this number to increase data smoothing #define NUMREADINGS 15 // Raise this number to decrease sensitivity (up to 1023 max) int senseLimit = 15; // EMF Value int valEMF = 0; // Readings from the analog input int readings[ NUMREADINGS ]; // Index of the current reading int indexEMF = 0; // Running total int totalEMF = 0; // Final average of the probe reading int averageEMF = 0; int iEMFDis = 0; int iEMFRect = 0; // RHT Humidity and Temperature Sensor // RHT03 data pin Digital 15 const int RHT03_DATA_PIN = 15; // This creates a RTH03 object, which we'll use to interact with the sensor RHT03 rht; float latestHumidity; float latestTempC; float latestTempF; // PIR Motion // Motion detector const int iMotion = 17; // Proximity int proximity = LOW; String Det = ""; // Software Version Information String sver = "15-12"; // EEPROM Unique ID Information #define EEPROM_SIZE 64 String uid = ""; void loop() { // Receives NEMA data from GPS receiver isGPS(); // Date and Time isRTC(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure isBME280(); // SparkFun CCS811 - eCO2 & tVOC isCCS811(); // Gas Sensors MQ isGasSensor(); // EMF Meter (Single Axis) isEMF(); // RHT03 Humidity and Temperature Sensor isRHT03(); // isPIR Motion isPIR(); // Rotary Switch isRot(); // Slide Switch // Read the state of the iSS1 value iSS1State = digitalRead(iSS1); // If it is the Slide Switch State is HIGH if (iSS1State == HIGH) { // iLEDGreen digitalWrite(iLEDGreen, HIGH ); // microSD Card isSD(); } else { // iLEDGreen digitalWrite(iLEDGreen, LOW ); } delay( 1000 ); }
getBME280.ino
// SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure // isBME280 - Temperature, Humidity, Altitude and Barometric Pressure void isBME280(){ // Temperature Celsius BMEtempC = myBME280.readTempC(); // Humidity BMEhumid = myBME280.readFloatHumidity(); // Altitude Meters BMEaltitudeM = (myBME280.readFloatAltitudeMeters(), 2); // Barometric Pressure BMEpressure = myBME280.readFloatPressure(); }
getCCS811.ino
// CCS811 - eCO2 & tVOC // isCCS811 - eCO2 & tVOC void isCCS811(){ // This sends the temperature & humidity data to the CCS811 myCCS811.setEnvironmentalData(BMEhumid, BMEtempC); // Calling this function updates the global tVOC and eCO2 variables myCCS811.readAlgorithmResults(); // eCO2 Concentration CCS811CO2 = myCCS811.getCO2(); // tVOC Concentration CCS811TVOC = myCCS811.getTVOC(); }
getDisplay.ino
// Display // SHARP Memory Display - UID void isDisplayUID() { // Text Display // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Don Luc Electronics display.setCursor(0,10); display.println( "Don Luc" ); display.setTextSize(2); display.setCursor(0,40); display.println( "Electronics" ); // Version display.setTextSize(3); display.setCursor(0,70); display.println( "Version" ); display.setTextSize(2); display.setCursor(0,100); display.println( sver ); // EEPROM Unique ID display.setTextSize(1); display.setCursor(0,130); display.println( "EEPROM Unique ID" ); display.setTextSize(2); display.setCursor(0,145); display.println( uid ); // Refresh display.refresh(); delay( 100 ); } // Display Environmental void isDisplayEnvironmental(){ // Text Display Environmental // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(1); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,0); display.println( "Temperature Celsius" ); display.setCursor(0,10); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,20); display.println( "Humidity" ); display.setCursor(0,30); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,40); display.println( "Altitude Meters" ); display.setCursor(0,50); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,60); display.println( "Barometric Pressure" ); display.setCursor(0,70); display.print( BMEpressure ); display.println( " Pa" ); // eCO2 Concentration display.setCursor(0,80); display.println( "eCO2 Concentration" ); display.setCursor(0,90); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,100); display.println( "tVOC Concentration" ); display.setCursor(0,110); display.print( CCS811TVOC ); display.println( " ppb" ); // Date display.setCursor(0,120); display.println( dateRTC ); // Time display.setCursor(0,130); display.println( timeRTC ); // GPS Status display.setCursor(0,140); display.println( GPSStatus ); // Target Latitude display.setCursor(0,150); display.println( TargetLat ); // Target Longitude display.setCursor(0,160); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display Date void isDisplayDate() { // Text Display Date // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Date display.setCursor(0,5); display.println( dateRTC ); // Time display.setCursor(0,30); display.println( timeRTC ); // GPS Status display.setCursor(0,60); display.print( "GPS: " ); display.println( GPSStatus ); // Target Latitude display.setCursor(0,80); display.println( "Latitude" ); display.setCursor(0,100); display.println( TargetLat ); // Target Longitude display.setCursor(0,120); display.println( "Longitude" ); display.setCursor(0,140); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display BME280 void isDisplayBME280() { // Text Display BME280 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,10); display.println( "Temperature" ); display.setCursor(0,30); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,50); display.println( "Humidity" ); display.setCursor(0,70); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,90); display.println( "Altitude M" ); display.setCursor(0,110); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,130); display.println( "Barometric" ); display.setCursor(0,150); display.print( BMEpressure ); display.println( "Pa" ); // Refresh display.refresh(); delay( 100 ); } // Display CCS811 - eCO2 & tVOC void isDisplayCCS811() { // Text Display CCS811 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // eCO2 Concentration display.setCursor(0,10); display.println( "eCO2" ); display.setCursor(0,30); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,60); display.println( "tVOC" ); display.setCursor(0,80); display.print( CCS811TVOC ); display.println( " ppb" ); // Refresh display.refresh(); delay( 100 ); } // Display Gas Sensors MQ void isDisplayMQ() { // Text Display MQ // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Gas Sensors MQ display.setCursor(0,10); display.println( "Gas H2 MQ8" ); display.setCursor(0,30); display.print( iMQ8ppm ); display.println( " ppm" ); display.setCursor(0,50); display.println( "Gas CO MQ9" ); display.setCursor(0,70); display.print( iMQ9ppm ); display.println( " ppm" ); display.setCursor(0,90); display.println( "Gas CO MQ7" ); display.setCursor(0,110); display.print( iMQ7ppm ); display.println( " ppm" ); display.setCursor(0,130); display.println( "BAC MQ3" ); display.setCursor(0,150); display.print( iMQ3ppm ); display.println( "%" ); // Refresh display.refresh(); delay( 100 ); } // EMF Meter (Single Axis) void isDisplayEMF() { // Text Display EMF Meter // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // EMF Meter display.setCursor(0,10); display.println( "EMF Meter" ); display.setCursor(0,30); display.print( "EMF: " ); display.println( averageEMF ); display.setCursor(0,50); display.println( iEMFDis ); display.setCursor(0,70); display.setTextSize(1); display.println( "0 1 2 3 4 5 6 7 8 9 10" ); display.setCursor(0,90); display.drawRect(0, 90, iEMFRect , display.height(), BLACK); display.fillRect(0, 90, iEMFRect , display.height(), BLACK); // Refresh display.refresh(); delay( 100 ); } // Display PIR Motion void isDisplayPIR() { // Text Display PIR // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // PIR Motion display.setCursor(0,10); display.println( "PIR Motion" ); display.setCursor(0,30); display.println( Det ); // Refresh display.refresh(); delay( 100 ); } // Display RHT void isDisplayRHT() { // Text Display RHT // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Temperature display.setCursor(0,10); display.println( "Temp C" ); display.setCursor(0,30); display.print( latestTempC ); display.println( "C" ); // Temp F display.setCursor(0,60); display.println( "Temp F" ); display.setCursor(0,80); display.print( latestTempF ); display.println( "F" ); // Humidity display.setCursor(0,110); display.println( "Humidity" ); display.setCursor(0,130); display.print( latestHumidity ); display.println( " %" ); // Refresh display.refresh(); delay( 100 ); } // Display Z void isDisplayZ() { // Text Display Z // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Z display.setCursor(0,10); display.print( "Z: " ); display.println( z ); // Refresh display.refresh(); delay( 100 ); }
getEEPROM.ino
// EEPROM // isUID EEPROM Unique ID void isUID() { // Is Unit ID uid = ""; for (int x = 0; x < 5; x++) { uid = uid + char(EEPROM.read(x)); } }
getEMF.ino
// EMF Meter (Single Axis) // Setup EMF Meter void isSetupEMF() { // EMF Meter (Single Axis) pinMode( iEMF, OUTPUT ); for (int i = 0; i < NUMREADINGS; i++){ readings[ i ] = 0; // Initialize all the readings to 0 } } // EMF Meter void isEMF() { // Probe EMF Meter // Take a reading from the probe valEMF = analogRead( iEMF ); // If the reading isn't zero, proceed if( valEMF >= 1 ){ // Turn any reading higher than the senseLimit value into the senseLimit value valEMF = constrain( valEMF, 1, senseLimit ); // Remap the constrained value within a 1 to 1023 range valEMF = map( valEMF, 1, senseLimit, 1, 1023 ); // Subtract the last reading totalEMF -= readings[ indexEMF ]; // Read from the sensor readings[ indexEMF ] = valEMF; // Add the reading to the total totalEMF += readings[ indexEMF ]; // Advance to the next index indexEMF = ( indexEMF + 1 ); // If we're at the end of the array... if ( indexEMF >= NUMREADINGS ) { // Wrap around to the beginning indexEMF = 0; } // Calculate the average averageEMF = totalEMF / NUMREADINGS; iEMFDis = averageEMF; iEMFRect = map( averageEMF, 1, 1023, 1, 144 ); } else { averageEMF = 0; } }
getGPS.ino
// GPS Receiver // Setup GPS void setupGPS() { // Setup GPS tGPS.begin( 9600 , SERIAL_8N1, gpsRXPIN, gpsTXPIN ); } // isGPS void isGPS(){ // Receives NEMA data from GPS receiver // This sketch displays information every time a new sentence is correctly encoded. while ( tGPS.available() > 0) if (gps.encode( tGPS.read() )) { displayInfo(); } if (millis() > 5000 && gps.charsProcessed() < 10) { while(true); } } // GPS Vector Pointer Target void displayInfo(){ // Location if (gps.location.isValid()) { TargetLat = gps.location.lat(); TargetLon = gps.location.lng(); GPSStatus = 2; } else { GPSStatus = 0; } }
getGasSensorMQ.ino
// Gas Sensors MQ // Gas Sensor void isGasSensor() { // Read in analog value from each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8Raw = analogRead( iMQ8 ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9Raw = analogRead( iMQ9 ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7Raw = analogRead( iMQ7 ); // Alcohol Gas Sensor - MQ-3 iMQ3Raw = analogRead( iMQ3 ); // Caclulate the PPM of each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8ppm = isMQ8( iMQ8Raw ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9ppm = isMQ9( iMQ9Raw ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7ppm = isMQ7( iMQ7Raw ); // Alcohol Gas Sensor - MQ-3 iMQ3ppm = isMQ3( iMQ3Raw ); } // Hydrogen Gas Sensor - MQ-8 - PPM int isMQ8(double rawValue) { // RvRo double RvRo = rawValue * (3.3 / 1023); return (pow(4.7,( ((log(RvRo)-H2Curve[1])/H2Curve[2]) + H2Curve[0]))); } // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int isMQ9(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double ppm = 3.027*exp(1.0698*( RvRo )); return ppm; } // Carbon Monoxide Gas Sensor - MQ-7 int isMQ7(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double ppm = 3.027*exp(1.0698*( RvRo )); return ppm; } // Alcohol Gas Sensor - MQ-3 int isMQ3(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double bac = RvRo * 0.21; return bac; }
getPIR.ino
// PIR Motion // Setup PIR void setupPIR() { // Setup PIR Montion pinMode(iMotion, INPUT_PULLUP); } // isPIR Motion void isPIR() { // Proximity proximity = digitalRead(iMotion); if (proximity == LOW) { // PIR Motion Sensor's LOW, Motion is detected Det = "Motion Yes"; } else { // PIR Motion Sensor's HIGH Det = "No"; } }
getRHT.ino
// RHT03 Humidity and Temperature Sensor // setup RTH03 Humidity and Temperature Sensor void setupRTH03() { // RHT03 Humidity and Temperature Sensor // Call rht.begin() to initialize the sensor and our data pin rht.begin(RHT03_DATA_PIN); } // RHT03 Humidity and Temperature Sensor void isRHT03(){ // Call rht.update() to get new humidity and temperature values from the sensor. int updateRet = rht.update(); // The humidity(), tempC(), and tempF() functions can be called -- after // a successful update() -- to get the last humidity and temperature value latestHumidity = rht.humidity(); latestTempC = rht.tempC(); latestTempF = rht.tempF(); }
getRTC.ino
// Date & Time // PCF8523 Precision RTC void setupRTC() { // Date & Time // pcf8523 Precision RTC if (! rtc.begin()) { while (1); } if (! rtc.initialized()) { // Following line sets the RTC to the date & time this sketch was compiled rtc.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // January 21, 2014 at 3am you would call: // rtc.adjust(DateTime(2018, 9, 29, 12, 17, 0)); } } // Date and Time RTC void isRTC () { // Date and Time dateRTC = ""; timeRTC = ""; DateTime now = rtc.now(); // Date dateRTC = now.year(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.month(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.day(), DEC; // Time timeRTC = now.hour(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.minute(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.second(), DEC; }
getRot.ino
// Rotary Switch // isRot - iRotVal - Value void isRot() { // Rotary Switch z = analogRead( iRotNum ); x = map(z, 0, 4095, 0, 9); iRotVal = map(z, 0, 4095, 0, 10); // Range Value switch ( iRotVal ) { case 0: // Display Environmental isDisplayEnvironmental(); break; case 1: // Display Date isDisplayDate(); break; case 2: // Display BME280 isDisplayBME280(); break; case 3: // RHT03 Humidity and Temperature Sensor isDisplayRHT(); break; case 4: // Display CCS811 - eCO2 & tVOC isDisplayCCS811(); break; case 5: // Display Gas Sensors MQ isDisplayMQ(); break; case 6: // EMF Meter (Single Axis) isDisplayEMF(); break; case 7: // Display PIR Motion isDisplayPIR(); break; case 8: // Display UID isDisplayUID(); break; case 9: // Z isDisplayZ(); break; } }
getSD.ino
// microSD Card // microSD Setup void setupSD() { // microSD Card pinMode( chipSelect , OUTPUT ); if(!SD.begin( chipSelect )){ ; return; } uint8_t cardType = SD.cardType(); if(cardType == CARD_NONE){ ; return; } //Serial.print("SD Card Type: "); if(cardType == CARD_MMC){ ; } else if(cardType == CARD_SD){ ; } else if(cardType == CARD_SDHC){ ; } else { ; } uint64_t cardSize = SD.cardSize() / (1024 * 1024); } // microSD Card void isSD() { zzzzzz = ""; // EEPROM Unique ID|Version|Date|Time|GPS Status|Target Latitude|Target Longitude|Temperature Celsius|Humidity|Altitude Meters|Barometric Pressure|Latest Temp C|Latest Temp F|Latest Humidity|eCO2 Concentration|tVOC Concentration|H2 Gas Sensor MQ-8|CO Gas Sensor MQ-9|CO Gas Sensor MQ-7|Alcohol Gas Sensor MQ-3|EMF Meter (Single Axis)|PIR Motion zzzzzz = uid + "|" + sver + "|" + dateRTC + "|" + timeRTC + "|" + GPSStatus + "|" + TargetLat + "|" + TargetLon + "|" + BMEtempC + "|" + BMEhumid + "|" + BMEaltitudeM + "|" + BMEpressure + "|" + latestTempC + "|" + latestTempF + "|" + latestHumidity + "|" + CCS811CO2 + "|" + CCS811TVOC + "|" + iMQ8ppm + "|" + iMQ9ppm + "|" + iMQ7ppm + "|" + iMQ9ppm + "|" + iMQ3ppm + "|" + averageEMF + "|" + Det + "|\r"; char msg[zzzzzz.length() + 1]; zzzzzz.toCharArray(msg, zzzzzz.length() + 1); appendFile(SD, "/espdata.txt", msg ); } // List Dir void listDir(fs::FS &fs, const char * dirname, uint8_t levels){ dirname; File root = fs.open(dirname); if(!root){ return; } if(!root.isDirectory()){ return; } File file = root.openNextFile(); while(file){ if(file.isDirectory()){ file.name(); if(levels){ listDir(fs, file.name(), levels -1); } } else { file.name(); file.size(); } file = root.openNextFile(); } } // Write File void writeFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_WRITE); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); } // Append File void appendFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_APPEND); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); }
setup.ino
// Setup void setup() { // EEPROM Size EEPROM.begin(EEPROM_SIZE); // EEPROM Unique ID isUID(); // GPS Receiver // Setup GPS setupGPS(); // SHARP Display Start & Clear the Display display.begin(); // Clear Display display.clearDisplay(); // Display UID isDisplayUID(); // Wire - Inialize I2C Hardware Wire.begin(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure myBME280.begin(); // CCS811 - eCO2 & tVOC myCCS811.begin(); // Initialize the LED Green pinMode(iLEDGreen, OUTPUT); // Date & Time RTC // PCF8523 Precision RTC setupRTC(); // Date & Time isRTC(); // microSD Card setupSD(); // Slide Switch pinMode(iSS1, INPUT); // EMF Meter (Single Axis) - Setup isSetupEMF(); // RHT03 Humidity and Temperature Sensor // setup RTH03 Humidity and Temperature Sensor setupRTH03(); // PIR Motion // Setup PIR setupPIR(); delay( 5000 ); }
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Don Luc
Project #15: Environment – Humidity and Temperature Sensor – RHT03 – Mk11
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#DonLuc #Environment #ESP32 #MQ #GPS #EMF #SparkFun #Adafruit #Pololu #Fritzing #Programming #Arduino #Consultant #Electronics #Microcontrollers #Vlog #Aphasia
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Humidity and Temperature Sensor – RHT03
SparkFun Item: SEN-10167
The RHT03 is a low cost humidity and temperature sensor with a single wire digital interface. The sensor is calibrated and doesn’t require extra components so you can get right to measuring relative humidity and temperature.
DL2006Mk01
1 x SparkFun Thing Plus – ESP32 WROOM
1 x Adafruit SHARP Memory Display
1 x SparkFun Environmental Combo Breakout – CCS811/BME280
1 x Adafruit Adalogger FeatherWing – RTC + SD
1 x SparkFun GPS Receiver – GP-20U7
1 x CR1220 12mm Lithium Battery
1 x 32Gb microSD Card
1 x Mountable Slide Switch
1 x SparkFun Rotary Switch – 10 Position
1 x Black Knob
1 x Breadboard Solderable
4 x Pololu Carrier for MQ Gas Sensors
1 x SparkFun Hydrogen Gas Sensor – MQ-8
1 x Pololu Carbon Monoxide & Flammable Gas Sensor – MQ-9
1 x SparkFun Carbon Monoxide Gas Sensor – MQ-7
1 x SparkFun Alcohol Gas Sensor – MQ-3
1 x Telescopic Antenna SMA – 300 MHz to 1.1 GHz (ANT700)
1 x SMA Connector
1 x Humidity and Temperature Sensor – RHT03
1 x Qwiic Cable – 100mm
1 x LED Green
11 x 1K Ohm
1 x 4.7K Ohm
2 x 10K Ohm
1 x 20k Ohm
1 x 200k Ohm
1 x 3.3m Ohm
10 x Jumper Wires 3in M/M
12 x Jumper Wires 6in M/M
20 x Wire Solid Core – 22 AWG
2 x Full-Size Breadboard
1 x SparkFun Cerberus USB Cable
1 x DC Power Supply
SparkFun Thing Plus – ESP32 WROOM
LEG – Digital 21
SCK – Digital 13
MOS – Digital 12
SSD – Digital 27
SDA – Digital 23
SCL – Digital 22
SD1 – Digital 33
SC2 – Digital 5
MO2 – Digital 18
MI2 – Digital 19
SS1 – Digital 16
ROT – Analog A1
MH1 – Analog A0
MC1 – Analog A2
MC2 – Analog A3
MA1 – Analog A4
EMF – Analog A5
GPS – Digital 14
RHT – Digital 15
VIN – +3.3V
GND – GND
DL2006Mk01p.ino
// ***** Don Luc Electronics © ***** // Software Version Information // Project #15: Environment - Humidity and Temperature Sensor - RHT03 - Mk11 // 06-01 // DL2006Mk01p.ino 15-11 // EEPROM with Unique ID // 1 x SparkFun Thing Plus - ESP32 WROOM // 1 x Adafruit SHARP Memory Display // 1 x SparkFun Environmental Combo Breakout - CCS811/BME280 // 1 x Adafruit Adalogger FeatherWing - RTC + SD // 1 x SparkFun GPS Receiver - GP-20U7 // 1 x CR1220 12mm Lithium Battery // 1 x 32Gb microSD Card // 1 x Mountable Slide Switch // 1 x SparkFun Rotary Switch - 10 Position // 1 x Black Knob // 1 x Breadboard Solderable // 4 x Pololu Carrier for MQ Gas Sensors // 1 x SparkFun Hydrogen Gas Sensor - MQ-8 // 1 x Pololu Carbon Monoxide & Flammable Gas Sensor - MQ-9 // 1 x SparkFun Carbon Monoxide Gas Sensor - MQ-7 // 1 x SparkFun Alcohol Gas Sensor - MQ-3 // 1 x Telescopic Antenna SMA - 300 MHz to 1.1 GHz (ANT700) // 1 x SMA Connector // 1 x Humidity and Temperature Sensor - RHT03 // 1 x Qwiic Cable - 100mm // 1 x LED Green // 11 x 1K Ohm // 1 x 4.7K Ohm // 2 x 10K Ohm // 1 x 20k Ohm // 1 x 200k Ohm // 1 x 3.3m Ohm // 10 x Jumper Wires 3in M/M // 12 x Jumper Wires 6in M/M // 20 x Wire Solid Core - 22 AWG // 2 x Full-Size Breadboard // 1 x SparkFun Cerberus USB Cable // 1 x DC Power Supply // Include the Library Code // EEPROM Library to Read and Write EEPROM with Unique ID for Unit #include "EEPROM.h" // Wire #include <Wire.h> // SHARP Memory Display #include <Adafruit_SharpMem.h> #include <Adafruit_GFX.h> // SparkFun CCS811 - eCO2 & tVOC #include <SparkFunCCS811.h> // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure #include <SparkFunBME280.h> // Date and Time #include "RTClib.h" // SD Card #include "FS.h" #include "SD.h" #include "SPI.h" // GPS Receiver #include <TinyGPS++.h> // Hardware Serial #include <HardwareSerial.h> // RHT Humidity and Temperature Sensor #include <SparkFun_RHT03.h> // LED Green int iLEDGreen = 21; // SHARP Memory Display // any pins can be used #define SHARP_SCK 13 #define SHARP_MOSI 12 #define SHARP_SS 27 // Set the size of the display here - 144x168 Adafruit_SharpMem display(SHARP_SCK, SHARP_MOSI, SHARP_SS, 144, 168); // The currently-available SHARP Memory Display (144x168 pixels) // requires > 4K of microcontroller RAM; it WILL NOT WORK on Arduino Uno // or other <4K "classic" devices! #define BLACK 0 #define WHITE 1 // 1/2 of lesser of display width or height int minorHalfSize; // SparkFun CCS811 - eCO2 & tVOC // Default I2C Address #define CCS811_ADDR 0x5B CCS811 myCCS811(CCS811_ADDR); float CCS811CO2 = 0; float CCS811TVOC = 0; // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure BME280 myBME280; float BMEtempC = 0; float BMEhumid = 0; float BMEaltitudeM = 0; float BMEpressure = 0; // Date and Time // PCF8523 Precision RTC RTC_PCF8523 rtc; String dateRTC = ""; String timeRTC = ""; // microSD Card const int chipSelect = 33; String zzzzzz = ""; // Mountable Slide Switch int iSS1 = 16; // State int iSS1State = 0; // ESP32 HardwareSerial HardwareSerial tGPS(2); // GPS Receiver #define gpsRXPIN 14 // This one is unused and doesnt have a conection #define gpsTXPIN 32 // The TinyGPS++ object TinyGPSPlus gps; float TargetLat; float TargetLon; int GPSStatus = 0; // Rotary Switch - 10 Position // Number 1 => 10 int iRotNum = A0; // iRotVal - Value int iRotVal = 0; // Number int z = 0; int x = 0; // Gas Sensors MQ // Hydrogen Gas Sensor - MQ-8 int iMQ8 = A1; int iMQ8Raw = 0; int iMQ8ppm = 0; // Two points are taken from the curve in datasheet // With these two points, a line is formed which is "approximately equivalent" to the original curve float H2Curve[3] = {2.3, 0.93,-1.44}; // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int iMQ9 = A2; int iMQ9Raw = 0; int iMQ9ppm = 0; // Carbon Monoxide Gas Sensor - MQ-7 int iMQ7 = A3; int iMQ7Raw = 0; int iMQ7ppm = 0; // Alcohol Gas Sensor - MQ-3 int iMQ3 = A4; int iMQ3Raw = 0; int iMQ3ppm = 0; // EMF Meter (Single Axis) int iEMF = A5; // Raise this number to increase data smoothing #define NUMREADINGS 15 // Raise this number to decrease sensitivity (up to 1023 max) int senseLimit = 15; // EMF Value int valEMF = 0; // Readings from the analog input int readings[ NUMREADINGS ]; // Index of the current reading int indexEMF = 0; // Running total int totalEMF = 0; // Final average of the probe reading int averageEMF = 0; int iEMFDis = 0; int iEMFRect = 0; // RHT Humidity and Temperature Sensor // RHT03 data pin Digital 15 const int RHT03_DATA_PIN = 15; // This creates a RTH03 object, which we'll use to interact with the sensor RHT03 rht; float latestHumidity; float latestTempC; float latestTempF; // Software Version Information String sver = "15-11"; // EEPROM Unique ID Information #define EEPROM_SIZE 64 String uid = ""; void loop() { // Receives NEMA data from GPS receiver isGPS(); // Date and Time isRTC(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure isBME280(); // SparkFun CCS811 - eCO2 & tVOC isCCS811(); // Gas Sensors MQ isGasSensor(); // EMF Meter (Single Axis) isEMF(); // RHT03 Humidity and Temperature Sensor isRHT03(); // Rotary Switch isRot(); // Slide Switch // Read the state of the iSS1 value iSS1State = digitalRead(iSS1); // If it is the Slide Switch State is HIGH if (iSS1State == HIGH) { // iLEDGreen digitalWrite(iLEDGreen, HIGH ); // microSD Card isSD(); } else { // iLEDGreen digitalWrite(iLEDGreen, LOW ); } delay( 1000 ); }
getBME280.ino
// SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure // isBME280 - Temperature, Humidity, Altitude and Barometric Pressure void isBME280(){ // Temperature Celsius BMEtempC = myBME280.readTempC(); // Humidity BMEhumid = myBME280.readFloatHumidity(); // Altitude Meters BMEaltitudeM = (myBME280.readFloatAltitudeMeters(), 2); // Barometric Pressure BMEpressure = myBME280.readFloatPressure(); }
getCCS811.ino
// CCS811 - eCO2 & tVOC // isCCS811 - eCO2 & tVOC void isCCS811(){ // This sends the temperature & humidity data to the CCS811 myCCS811.setEnvironmentalData(BMEhumid, BMEtempC); // Calling this function updates the global tVOC and eCO2 variables myCCS811.readAlgorithmResults(); // eCO2 Concentration CCS811CO2 = myCCS811.getCO2(); // tVOC Concentration CCS811TVOC = myCCS811.getTVOC(); }
getDisplay.ino
// Display // SHARP Memory Display - UID void isDisplayUID() { // Text Display // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Don Luc Electronics display.setCursor(0,10); display.println( "Don Luc" ); display.setTextSize(2); display.setCursor(0,40); display.println( "Electronics" ); // Version display.setTextSize(3); display.setCursor(0,70); display.println( "Version" ); display.setTextSize(2); display.setCursor(0,100); display.println( sver ); // EEPROM Unique ID display.setTextSize(1); display.setCursor(0,130); display.println( "EEPROM Unique ID" ); display.setTextSize(2); display.setCursor(0,145); display.println( uid ); // Refresh display.refresh(); delay( 100 ); } // Display Environmental void isDisplayEnvironmental(){ // Text Display Environmental // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(1); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,0); display.println( "Temperature Celsius" ); display.setCursor(0,10); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,20); display.println( "Humidity" ); display.setCursor(0,30); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,40); display.println( "Altitude Meters" ); display.setCursor(0,50); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,60); display.println( "Barometric Pressure" ); display.setCursor(0,70); display.print( BMEpressure ); display.println( " Pa" ); // eCO2 Concentration display.setCursor(0,80); display.println( "eCO2 Concentration" ); display.setCursor(0,90); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,100); display.println( "tVOC Concentration" ); display.setCursor(0,110); display.print( CCS811TVOC ); display.println( " ppb" ); // Date display.setCursor(0,120); display.println( dateRTC ); // Time display.setCursor(0,130); display.println( timeRTC ); // GPS Status display.setCursor(0,140); display.println( GPSStatus ); // Target Latitude display.setCursor(0,150); display.println( TargetLat ); // Target Longitude display.setCursor(0,160); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display Date void isDisplayDate() { // Text Display Date // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Date display.setCursor(0,5); display.println( dateRTC ); // Time display.setCursor(0,30); display.println( timeRTC ); // GPS Status display.setCursor(0,60); display.print( "GPS: " ); display.println( GPSStatus ); // Target Latitude display.setCursor(0,80); display.println( "Latitude" ); display.setCursor(0,100); display.println( TargetLat ); // Target Longitude display.setCursor(0,120); display.println( "Longitude" ); display.setCursor(0,140); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display BME280 void isDisplayBME280() { // Text Display BME280 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,10); display.println( "Temperature" ); display.setCursor(0,30); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,50); display.println( "Humidity" ); display.setCursor(0,70); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,90); display.println( "Altitude M" ); display.setCursor(0,110); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,130); display.println( "Barometric" ); display.setCursor(0,150); display.print( BMEpressure ); display.println( "Pa" ); // Refresh display.refresh(); delay( 100 ); } // Display CCS811 - eCO2 & tVOC void isDisplayCCS811() { // Text Display CCS811 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // eCO2 Concentration display.setCursor(0,10); display.println( "eCO2" ); display.setCursor(0,30); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,60); display.println( "tVOC" ); display.setCursor(0,80); display.print( CCS811TVOC ); display.println( " ppb" ); // Refresh display.refresh(); delay( 100 ); } // Display Gas Sensors MQ void isDisplayMQ() { // Text Display MQ // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Gas Sensors MQ display.setCursor(0,10); display.println( "Gas H2 MQ8" ); display.setCursor(0,30); display.print( iMQ8ppm ); display.println( " ppm" ); display.setCursor(0,50); display.println( "Gas CO MQ9" ); display.setCursor(0,70); display.print( iMQ9ppm ); display.println( " ppm" ); display.setCursor(0,90); display.println( "Gas CO MQ7" ); display.setCursor(0,110); display.print( iMQ7ppm ); display.println( " ppm" ); display.setCursor(0,130); display.println( "BAC MQ3" ); display.setCursor(0,150); display.print( iMQ3ppm ); display.println( "%" ); // Refresh display.refresh(); delay( 100 ); } // EMF Meter (Single Axis) void isDisplayEMF() { // Text Display EMF Meter // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // EMF Meter display.setCursor(0,10); display.println( "EMF Meter" ); display.setCursor(0,30); display.print( "EMF: " ); display.println( averageEMF ); display.setCursor(0,50); display.println( iEMFDis ); display.setCursor(0,70); display.setTextSize(1); display.println( "0 1 2 3 4 5 6 7 8 9 10" ); display.setCursor(0,90); display.drawRect(0, 90, iEMFRect , display.height(), BLACK); display.fillRect(0, 90, iEMFRect , display.height(), BLACK); // Refresh display.refresh(); delay( 100 ); } // Display RHT void isDisplayRHT() { // Text Display RHT // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Temperature display.setCursor(0,10); display.println( "Temp C" ); display.setCursor(0,30); display.print( latestTempC ); display.println( "C" ); // Temp F display.setCursor(0,60); display.println( "Temp F" ); display.setCursor(0,80); display.print( latestTempF ); display.println( "F" ); // Humidity display.setCursor(0,110); display.println( "Humidity" ); display.setCursor(0,130); display.print( latestHumidity ); display.println( " %" ); // Refresh display.refresh(); delay( 100 ); } // Display Z void isDisplayZ() { // Text Display Z // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Z display.setCursor(0,10); display.print( "Z: " ); display.println( z ); // Refresh display.refresh(); delay( 100 ); }
getEEPROM.ino
// EEPROM // isUID EEPROM Unique ID void isUID() { // Is Unit ID uid = ""; for (int x = 0; x < 5; x++) { uid = uid + char(EEPROM.read(x)); } }
getEMF.ino
// EMF Meter (Single Axis) // Setup EMF Meter void isSetupEMF() { // EMF Meter (Single Axis) pinMode( iEMF, OUTPUT ); for (int i = 0; i < NUMREADINGS; i++){ readings[ i ] = 0; // Initialize all the readings to 0 } } // EMF Meter void isEMF() { // Probe EMF Meter // Take a reading from the probe valEMF = analogRead( iEMF ); // If the reading isn't zero, proceed if( valEMF >= 1 ){ // Turn any reading higher than the senseLimit value into the senseLimit value valEMF = constrain( valEMF, 1, senseLimit ); // Remap the constrained value within a 1 to 1023 range valEMF = map( valEMF, 1, senseLimit, 1, 1023 ); // Subtract the last reading totalEMF -= readings[ indexEMF ]; // Read from the sensor readings[ indexEMF ] = valEMF; // Add the reading to the total totalEMF += readings[ indexEMF ]; // Advance to the next index indexEMF = ( indexEMF + 1 ); // If we're at the end of the array... if ( indexEMF >= NUMREADINGS ) { // Wrap around to the beginning indexEMF = 0; } // Calculate the average averageEMF = totalEMF / NUMREADINGS; iEMFDis = averageEMF; iEMFRect = map( averageEMF, 1, 1023, 1, 144 ); } else { averageEMF = 0; } }
getGPS.ino
// GPS Receiver // Setup GPS void setupGPS() { // Setup GPS tGPS.begin( 9600 , SERIAL_8N1, gpsRXPIN, gpsTXPIN ); } // isGPS void isGPS(){ // Receives NEMA data from GPS receiver // This sketch displays information every time a new sentence is correctly encoded. while ( tGPS.available() > 0) if (gps.encode( tGPS.read() )) { displayInfo(); } if (millis() > 5000 && gps.charsProcessed() < 10) { while(true); } } // GPS Vector Pointer Target void displayInfo(){ // Location if (gps.location.isValid()) { TargetLat = gps.location.lat(); TargetLon = gps.location.lng(); GPSStatus = 2; } else { GPSStatus = 0; } }
getGasSensorMQ.ino
// Gas Sensors MQ // Gas Sensor void isGasSensor() { // Read in analog value from each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8Raw = analogRead( iMQ8 ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9Raw = analogRead( iMQ9 ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7Raw = analogRead( iMQ7 ); // Alcohol Gas Sensor - MQ-3 iMQ3Raw = analogRead( iMQ3 ); // Caclulate the PPM of each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8ppm = isMQ8( iMQ8Raw ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9ppm = isMQ9( iMQ9Raw ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7ppm = isMQ7( iMQ7Raw ); // Alcohol Gas Sensor - MQ-3 iMQ3ppm = isMQ3( iMQ3Raw ); } // Hydrogen Gas Sensor - MQ-8 - PPM int isMQ8(double rawValue) { // RvRo double RvRo = rawValue * (3.3 / 1023); return (pow(4.7,( ((log(RvRo)-H2Curve[1])/H2Curve[2]) + H2Curve[0]))); } // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int isMQ9(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double ppm = 3.027*exp(1.0698*( RvRo )); return ppm; } // Carbon Monoxide Gas Sensor - MQ-7 int isMQ7(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double ppm = 3.027*exp(1.0698*( RvRo )); return ppm; } // Alcohol Gas Sensor - MQ-3 int isMQ3(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double bac = RvRo * 0.21; return bac; }
getRHT.ino
// RHT03 Humidity and Temperature Sensor // setup RTH03 Humidity and Temperature Sensor void setupRTH03() { // RHT03 Humidity and Temperature Sensor // Call rht.begin() to initialize the sensor and our data pin rht.begin(RHT03_DATA_PIN); } // RHT03 Humidity and Temperature Sensor void isRHT03(){ // Call rht.update() to get new humidity and temperature values from the sensor. int updateRet = rht.update(); // The humidity(), tempC(), and tempF() functions can be called -- after // a successful update() -- to get the last humidity and temperature value latestHumidity = rht.humidity(); latestTempC = rht.tempC(); latestTempF = rht.tempF(); }
getRTC.ino
// Date & Time // PCF8523 Precision RTC void setupRTC() { // Date & Time // pcf8523 Precision RTC if (! rtc.begin()) { while (1); } if (! rtc.initialized()) { // Following line sets the RTC to the date & time this sketch was compiled rtc.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // January 21, 2014 at 3am you would call: // rtc.adjust(DateTime(2018, 9, 29, 12, 17, 0)); } } // Date and Time RTC void isRTC () { // Date and Time dateRTC = ""; timeRTC = ""; DateTime now = rtc.now(); // Date dateRTC = now.year(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.month(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.day(), DEC; // Time timeRTC = now.hour(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.minute(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.second(), DEC; }
getRot.ino
// Rotary Switch // isRot - iRotVal - Value void isRot() { // Rotary Switch z = analogRead( iRotNum ); x = map(z, 0, 4095, 0, 9); iRotVal = map(z, 0, 4095, 0, 10); // Range Value switch ( iRotVal ) { case 0: // Display Environmental isDisplayEnvironmental(); break; case 1: // Display Date isDisplayDate(); break; case 2: // Display BME280 isDisplayBME280(); break; case 3: // RHT03 Humidity and Temperature Sensor isDisplayRHT(); break; case 4: // Display CCS811 - eCO2 & tVOC isDisplayCCS811(); break; case 5: // Display Gas Sensors MQ isDisplayMQ(); break; case 6: // EMF Meter (Single Axis) isDisplayEMF(); break; case 7: // Display UID isDisplayUID(); break; case 8: // Z isDisplayZ(); break; case 9: // Z isDisplayZ(); break; } }
getSD.ino
// microSD Card // microSD Setup void setupSD() { // microSD Card pinMode( chipSelect , OUTPUT ); if(!SD.begin( chipSelect )){ ; return; } uint8_t cardType = SD.cardType(); if(cardType == CARD_NONE){ ; return; } //Serial.print("SD Card Type: "); if(cardType == CARD_MMC){ ; } else if(cardType == CARD_SD){ ; } else if(cardType == CARD_SDHC){ ; } else { ; } uint64_t cardSize = SD.cardSize() / (1024 * 1024); } // microSD Card void isSD() { zzzzzz = ""; // EEPROM Unique ID|Version|Date|Time|GPS Status|Target Latitude|Target Longitude|Temperature Celsius|Humidity|Altitude Meters|Barometric Pressure|Latest Temp C|Latest Temp F|Latest Humidity|eCO2 Concentration|tVOC Concentration|H2 Gas Sensor MQ-8|CO Gas Sensor MQ-9|CO Gas Sensor MQ-7|Alcohol Gas Sensor MQ-3|EMF Meter (Single Axis) zzzzzz = uid + "|" + sver + "|" + dateRTC + "|" + timeRTC + "|" + GPSStatus + "|" + TargetLat + "|" + TargetLon + "|" + BMEtempC + "|" + BMEhumid + "|" + BMEaltitudeM + "|" + BMEpressure + "|" + latestTempC + "|" + latestTempF + "|" + latestHumidity + "|" + CCS811CO2 + "|" + CCS811TVOC + "|" + iMQ8ppm + "|" + iMQ9ppm + "|" + iMQ7ppm + "|" + iMQ9ppm + "|" + iMQ3ppm + "|" + averageEMF + "|\r"; char msg[zzzzzz.length() + 1]; zzzzzz.toCharArray(msg, zzzzzz.length() + 1); appendFile(SD, "/espdata.txt", msg ); } // List Dir void listDir(fs::FS &fs, const char * dirname, uint8_t levels){ dirname; File root = fs.open(dirname); if(!root){ return; } if(!root.isDirectory()){ return; } File file = root.openNextFile(); while(file){ if(file.isDirectory()){ file.name(); if(levels){ listDir(fs, file.name(), levels -1); } } else { file.name(); file.size(); } file = root.openNextFile(); } } // Write File void writeFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_WRITE); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); } // Append File void appendFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_APPEND); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); }
setup.ino
// Setup void setup() { // EEPROM Size EEPROM.begin(EEPROM_SIZE); // EEPROM Unique ID isUID(); // GPS Receiver // Setup GPS setupGPS(); // SHARP Display Start & Clear the Display display.begin(); // Clear Display display.clearDisplay(); // Display UID isDisplayUID(); // Wire - Inialize I2C Hardware Wire.begin(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure myBME280.begin(); // CCS811 - eCO2 & tVOC myCCS811.begin(); // Initialize the LED Green pinMode(iLEDGreen, OUTPUT); // Date & Time RTC // PCF8523 Precision RTC setupRTC(); // Date & Time isRTC(); // microSD Card setupSD(); // Slide Switch pinMode(iSS1, INPUT); // EMF Meter (Single Axis) - Setup isSetupEMF(); // RHT03 Humidity and Temperature Sensor // setup RTH03 Humidity and Temperature Sensor setupRTH03(); delay( 5000 ); }
Technology Experience
- Single-Board Microcontrollers (Arduino, Raspberry Pi,Espressif, etc…)
- Robotics
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- Content Management Systems (WordPress, Drupal, Joomla, Moodle, etc…)
- Bulletin Boards (phpBB, SMF, Vanilla, jobberBase, etc…)
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Instructor
- Arduino
- Raspberry Pi
- Espressif
- Robotics
- DOS, Windows, OSX, Linux, iOS, Android, Multi-OS
- Linux-Apache-PHP-MySQL
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Don Luc
Project #15: Environment – EMF Meters – Mk10
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#DonLuc #Environment #Microcontrollers #EMF #ESP32 #MQ #GPS #SparkFun #Adafruit #Pololu #Fritzing #Programming #Arduino #Electronics #Consultant #Vlog #Aphasia
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DL2005Mk012
1 x SparkFun Thing Plus – ESP32 WROOM
1 x Adafruit SHARP Memory Display
1 x SparkFun Environmental Combo Breakout – CCS811/BME280
1 x Adafruit Adalogger FeatherWing – RTC + SD
1 x SparkFun GPS Receiver – GP-20U7
1 x CR1220 12mm Lithium Battery
1 x 32Gb microSD Card
1 x Mountable Slide Switch
1 x SparkFun Rotary Switch – 10 Position
1 x Black Knob
1 x Breadboard Solderable
4 x Pololu Carrier for MQ Gas Sensors
1 x SparkFun Hydrogen Gas Sensor – MQ-8
1 x Pololu Carbon Monoxide & Flammable Gas Sensor – MQ-9
1 x SparkFun Carbon Monoxide Gas Sensor – MQ-7
1 x SparkFun Alcohol Gas Sensor – MQ-3
1 x Telescopic Antenna SMA – 300 MHz to 1.1 GHz (ANT700)
1 x SMA Connector
1 x Qwiic Cable – 100mm
1 x LED Green
11 x 1K Ohm
1 x 4.7K Ohm
2 x 10K Ohm
1 x 20k Ohm
1 x 200k Ohm
1 x 3.3m Ohm
10 x Jumper Wires 3in M/M
10 x Jumper Wires 6in M/M
18 x Wire Solid Core – 22 AWG
2 x Full-Size Breadboard
1 x SparkFun Cerberus USB Cable
1 x DC Power Supply
SparkFun Thing Plus – ESP32 WROOM
LEG – Digital 21
SCK – Digital 13
MOS – Digital 12
SSD – Digital 27
SDA – Digital 23
SCL – Digital 22
SD1 – Digital 33
SC2 – Digital 5
MO2 – Digital 18
MI2 – Digital 19
SS1 – Digital 16
ROT – Analog A1
MH1 – Analog A0
MC1 – Analog A2
MC2 – Analog A3
MA1 – Analog A4
EMF – Analog A5
GPS – Digital 14
VIN – +3.3V
GND – GND
DL2005Mk12p.ino
// ***** Don Luc Electronics © ***** // Software Version Information // Project #15: Environment - EMF Meters - Mk10 // 05-12 // DL2005Mk12p.ino 15-10 // EEPROM with Unique ID // 1 x SparkFun Thing Plus - ESP32 WROOM // 1 x Adafruit SHARP Memory Display // 1 x SparkFun Environmental Combo Breakout - CCS811/BME280 // 1 x Adafruit Adalogger FeatherWing - RTC + SD // 1 x SparkFun GPS Receiver - GP-20U7 // 1 x CR1220 12mm Lithium Battery // 1 x 32Gb microSD Card // 1 x Mountable Slide Switch // 1 x SparkFun Rotary Switch - 10 Position // 1 x Black Knob // 1 x Breadboard Solderable // 4 x Pololu Carrier for MQ Gas Sensors // 1 x Pololu Carbon Monoxide & Flammable Gas Sensor - MQ-9 // 1 x SparkFun Hydrogen Gas Sensor - MQ-8 // 1 x SparkFun Carbon Monoxide Gas Sensor - MQ-7 // 1 x SparkFun Alcohol Gas Sensor - MQ-3 // 1 x Telescopic Antenna SMA - 300 MHz to 1.1 GHz (ANT700) // 1 x SMA Connector // 1 x Qwiic Cable - 100mm // 1 x LED Green // 11 x 1K Ohm // 1 x 4.7K Ohm // 1 x 10K Ohm // 1 x 20K Ohm // 1 x 200k Ohm // 1 x 3.3m Ohm // 10 x Jumper Wires 3in M/M // 10 x Jumper Wires 6in M/M // 18 x Wire Solid Core - 22 AWG // 2 x Full-Size Breadboard // 1 x SparkFun Cerberus USB Cable // 1 x DC Power Supply // Include the Library Code // EEPROM Library to Read and Write EEPROM with Unique ID for Unit #include "EEPROM.h" // Wire #include <Wire.h> // SHARP Memory Display #include <Adafruit_SharpMem.h> #include <Adafruit_GFX.h> // SparkFun CCS811 - eCO2 & tVOC #include <SparkFunCCS811.h> // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure #include <SparkFunBME280.h> // Date and Time #include "RTClib.h" // SD Card #include "FS.h" #include "SD.h" #include "SPI.h" // GPS Receiver #include <TinyGPS++.h> // Hardware Serial #include <HardwareSerial.h> // LED Green int iLEDGreen = 21; // SHARP Memory Display // any pins can be used #define SHARP_SCK 13 #define SHARP_MOSI 12 #define SHARP_SS 27 // Set the size of the display here - 144x168 Adafruit_SharpMem display(SHARP_SCK, SHARP_MOSI, SHARP_SS, 144, 168); // The currently-available SHARP Memory Display (144x168 pixels) // requires > 4K of microcontroller RAM; it WILL NOT WORK on Arduino Uno // or other <4K "classic" devices! #define BLACK 0 #define WHITE 1 // 1/2 of lesser of display width or height int minorHalfSize; // SparkFun CCS811 - eCO2 & tVOC // Default I2C Address #define CCS811_ADDR 0x5B CCS811 myCCS811(CCS811_ADDR); float CCS811CO2 = 0; float CCS811TVOC = 0; // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure BME280 myBME280; float BMEtempC = 0; float BMEhumid = 0; float BMEaltitudeM = 0; float BMEpressure = 0; // Date and Time // PCF8523 Precision RTC RTC_PCF8523 rtc; String dateRTC = ""; String timeRTC = ""; // microSD Card const int chipSelect = 33; String zzzzzz = ""; // Mountable Slide Switch int iSS1 = 16; // State int iSS1State = 0; // ESP32 HardwareSerial HardwareSerial tGPS(2); // GPS Receiver #define gpsRXPIN 14 // This one is unused and doesnt have a conection #define gpsTXPIN 32 // The TinyGPS++ object TinyGPSPlus gps; float TargetLat; float TargetLon; int GPSStatus = 0; // Rotary Switch - 10 Position // Number 1 => 10 int iRotNum = A0; // iRotVal - Value int iRotVal = 0; // Number int z = 0; int x = 0; // Gas Sensors MQ // Hydrogen Gas Sensor - MQ-8 int iMQ8 = A1; int iMQ8Raw = 0; int iMQ8ppm = 0; // Two points are taken from the curve in datasheet // With these two points, a line is formed which is "approximately equivalent" to the original curve float H2Curve[3] = {2.3, 0.93,-1.44}; // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int iMQ9 = A2; int iMQ9Raw = 0; int iMQ9ppm = 0; // Carbon Monoxide Gas Sensor - MQ-7 int iMQ7 = A3; int iMQ7Raw = 0; int iMQ7ppm = 0; // Alcohol Gas Sensor - MQ-3 int iMQ3 = A4; int iMQ3Raw = 0; int iMQ3ppm = 0; // EMF Meter (Single Axis) int iEMF = A5; // Raise this number to increase data smoothing #define NUMREADINGS 15 // Raise this number to decrease sensitivity (up to 1023 max) int senseLimit = 15; // EMF Value int valEMF = 0; // Readings from the analog input int readings[ NUMREADINGS ]; // Index of the current reading int indexEMF = 0; // Running total int totalEMF = 0; // Final average of the probe reading int averageEMF = 0; int iEMFDis = 0; int iEMFRect = 0; // Software Version Information String sver = "15-10"; // EEPROM Unique ID Information #define EEPROM_SIZE 64 String uid = ""; void loop() { // Receives NEMA data from GPS receiver isGPS(); // Date and Time isRTC(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure isBME280(); // SparkFun CCS811 - eCO2 & tVOC isCCS811(); // Gas Sensors MQ isGasSensor(); // EMF Meter (Single Axis) isEMF(); // Rotary Switch isRot(); // Slide Switch // Read the state of the iSS1 value iSS1State = digitalRead(iSS1); // If it is the Slide Switch State is HIGH if (iSS1State == HIGH) { // iLEDGreen digitalWrite(iLEDGreen, HIGH ); // microSD Card isSD(); } else { // iLEDGreen digitalWrite(iLEDGreen, LOW ); } delay( 1000 ); }
getBME280.ino
// SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure // isBME280 - Temperature, Humidity, Altitude and Barometric Pressure void isBME280(){ // Temperature Celsius BMEtempC = myBME280.readTempC(); // Humidity BMEhumid = myBME280.readFloatHumidity(); // Altitude Meters BMEaltitudeM = (myBME280.readFloatAltitudeMeters(), 2); // Barometric Pressure BMEpressure = myBME280.readFloatPressure(); }
getCCS811.ino
// CCS811 - eCO2 & tVOC // isCCS811 - eCO2 & tVOC void isCCS811(){ // This sends the temperature & humidity data to the CCS811 myCCS811.setEnvironmentalData(BMEhumid, BMEtempC); // Calling this function updates the global tVOC and eCO2 variables myCCS811.readAlgorithmResults(); // eCO2 Concentration CCS811CO2 = myCCS811.getCO2(); // tVOC Concentration CCS811TVOC = myCCS811.getTVOC(); }
getDisplay.ino
// Display // SHARP Memory Display - UID void isDisplayUID() { // Text Display // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Don Luc Electronics display.setCursor(0,10); display.println( "Don Luc" ); display.setTextSize(2); display.setCursor(0,40); display.println( "Electronics" ); // Version display.setTextSize(3); display.setCursor(0,70); display.println( "Version" ); display.setTextSize(2); display.setCursor(0,100); display.println( sver ); // EEPROM Unique ID display.setTextSize(1); display.setCursor(0,130); display.println( "EEPROM Unique ID" ); display.setTextSize(2); display.setCursor(0,145); display.println( uid ); // Refresh display.refresh(); delay( 100 ); } // Display Environmental void isDisplayEnvironmental(){ // Text Display Environmental // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(1); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,0); display.println( "Temperature Celsius" ); display.setCursor(0,10); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,20); display.println( "Humidity" ); display.setCursor(0,30); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,40); display.println( "Altitude Meters" ); display.setCursor(0,50); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,60); display.println( "Barometric Pressure" ); display.setCursor(0,70); display.print( BMEpressure ); display.println( " Pa" ); // eCO2 Concentration display.setCursor(0,80); display.println( "eCO2 Concentration" ); display.setCursor(0,90); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,100); display.println( "tVOC Concentration" ); display.setCursor(0,110); display.print( CCS811TVOC ); display.println( " ppb" ); // Date display.setCursor(0,120); display.println( dateRTC ); // Time display.setCursor(0,130); display.println( timeRTC ); // GPS Status display.setCursor(0,140); display.println( GPSStatus ); // Target Latitude display.setCursor(0,150); display.println( TargetLat ); // Target Longitude display.setCursor(0,160); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display Date void isDisplayDate() { // Text Display Date // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Date display.setCursor(0,5); display.println( dateRTC ); // Time display.setCursor(0,30); display.println( timeRTC ); // GPS Status display.setCursor(0,60); display.print( "GPS: " ); display.println( GPSStatus ); // Target Latitude display.setCursor(0,80); display.println( "Latitude" ); display.setCursor(0,100); display.println( TargetLat ); // Target Longitude display.setCursor(0,120); display.println( "Longitude" ); display.setCursor(0,140); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display BME280 void isDisplayBME280() { // Text Display BME280 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,10); display.println( "Temperature" ); display.setCursor(0,30); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,50); display.println( "Humidity" ); display.setCursor(0,70); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,90); display.println( "Altitude M" ); display.setCursor(0,110); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,130); display.println( "Barometric" ); display.setCursor(0,150); display.print( BMEpressure ); display.println( "Pa" ); // Refresh display.refresh(); delay( 100 ); } // Display CCS811 - eCO2 & tVOC void isDisplayCCS811() { // Text Display CCS811 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // eCO2 Concentration display.setCursor(0,10); display.println( "eCO2" ); display.setCursor(0,30); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,60); display.println( "tVOC" ); display.setCursor(0,80); display.print( CCS811TVOC ); display.println( " ppb" ); // Refresh display.refresh(); delay( 100 ); } // Display Gas Sensors MQ void isDisplayMQ() { // Text Display MQ // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Gas Sensors MQ display.setCursor(0,10); display.println( "Gas Sensors" ); display.setCursor(0,30); display.println( "Gas H2 MQ8" ); display.setCursor(0,50); display.print( iMQ8ppm ); display.println( " ppm" ); display.setCursor(0,70); display.println( "Gas CO MQ9" ); display.setCursor(0,90); display.print( iMQ9ppm ); display.println( " ppm" ); display.setCursor(0,110); display.println( "Gas CO MQ7" ); display.setCursor(0,130); display.print( iMQ7ppm ); display.println( " ppm" ); display.setCursor(0,150); display.println( "BAC MQ3" ); display.setCursor(0,170); display.print( iMQ3ppm ); display.println( "%" ); // Refresh display.refresh(); delay( 100 ); } // EMF Meter (Single Axis) void isDisplayEMF() { // Text Display EMF Meter // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // EMF Meter display.setCursor(0,10); display.println( "EMF Meter" ); display.setCursor(0,30); display.print( "EMF: " ); display.println( averageEMF ); display.setCursor(0,50); display.println( iEMFDis ); display.setCursor(0,70); display.setTextSize(1); display.println( "0 1 2 3 4 5 6 7 8 9 10" ); display.setCursor(0,90); display.drawRect(0, 90, iEMFRect , display.height(), BLACK); display.fillRect(0, 90, iEMFRect , display.height(), BLACK); // Refresh display.refresh(); delay( 100 ); } // Display Z void isDisplayZ() { // Text Display Z // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Z display.setCursor(0,10); display.print( "Z: " ); display.println( z ); // Refresh display.refresh(); delay( 100 ); }
getEEPROM.ino
// EEPROM // isUID EEPROM Unique ID void isUID() { // Is Unit ID uid = ""; for (int x = 0; x < 5; x++) { uid = uid + char(EEPROM.read(x)); } }
getEMF.ino
// EMF Meter (Single Axis) // Setup EMF Meter void isSetupEMF() { // EMF Meter (Single Axis) pinMode( iEMF, OUTPUT ); for (int i = 0; i < NUMREADINGS; i++){ readings[ i ] = 0; // Initialize all the readings to 0 } } // EMF Meter void isEMF() { // Probe EMF Meter // Take a reading from the probe valEMF = analogRead( iEMF ); // If the reading isn't zero, proceed if( valEMF >= 1 ){ // Turn any reading higher than the senseLimit value into the senseLimit value valEMF = constrain( valEMF, 1, senseLimit ); // Remap the constrained value within a 1 to 1023 range valEMF = map( valEMF, 1, senseLimit, 1, 1023 ); // Subtract the last reading totalEMF -= readings[ indexEMF ]; // Read from the sensor readings[ indexEMF ] = valEMF; // Add the reading to the total totalEMF += readings[ indexEMF ]; // Advance to the next index indexEMF = ( indexEMF + 1 ); // If we're at the end of the array... if ( indexEMF >= NUMREADINGS ) { // Wrap around to the beginning indexEMF = 0; } // Calculate the average averageEMF = totalEMF / NUMREADINGS; iEMFDis = averageEMF; iEMFRect = map( averageEMF, 1, 1023, 1, 144 ); } else { averageEMF = 0; } }
getGPS.ino
// GPS Receiver // Setup GPS void setupGPS() { // Setup GPS tGPS.begin( 9600 , SERIAL_8N1, gpsRXPIN, gpsTXPIN ); } // isGPS void isGPS(){ // Receives NEMA data from GPS receiver // This sketch displays information every time a new sentence is correctly encoded. while ( tGPS.available() > 0) if (gps.encode( tGPS.read() )) { displayInfo(); } if (millis() > 5000 && gps.charsProcessed() < 10) { while(true); } } // GPS Vector Pointer Target void displayInfo(){ // Location if (gps.location.isValid()) { TargetLat = gps.location.lat(); TargetLon = gps.location.lng(); GPSStatus = 2; } else { GPSStatus = 0; } }
getGasSensorMQ.ino
// Gas Sensors MQ // Gas Sensor void isGasSensor() { // Read in analog value from each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8Raw = analogRead( iMQ8 ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9Raw = analogRead( iMQ9 ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7Raw = analogRead( iMQ7 ); // Alcohol Gas Sensor - MQ-3 iMQ3Raw = analogRead( iMQ3 ); // Caclulate the PPM of each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8ppm = isMQ8( iMQ8Raw ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9ppm = isMQ9( iMQ9Raw ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7ppm = isMQ7( iMQ7Raw ); // Alcohol Gas Sensor - MQ-3 iMQ3ppm = isMQ3( iMQ3Raw ); } // Hydrogen Gas Sensor - MQ-8 - PPM int isMQ8(double rawValue) { // RvRo double RvRo = rawValue * (3.3 / 1023); return (pow(4.7,( ((log(RvRo)-H2Curve[1])/H2Curve[2]) + H2Curve[0]))); } // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int isMQ9(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double ppm = 3.027*exp(1.0698*( RvRo )); return ppm; } // Carbon Monoxide Gas Sensor - MQ-7 int isMQ7(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double ppm = 3.027*exp(1.0698*( RvRo )); return ppm; } // Alcohol Gas Sensor - MQ-3 int isMQ3(double rawValue) { double RvRo = rawValue * 3.3 / 4095; double bac = RvRo * 0.21; return bac; }
getRTC.ino
// Date & Time // PCF8523 Precision RTC void setupRTC() { // Date & Time // pcf8523 Precision RTC if (! rtc.begin()) { while (1); } if (! rtc.initialized()) { // Following line sets the RTC to the date & time this sketch was compiled rtc.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // January 21, 2014 at 3am you would call: // rtc.adjust(DateTime(2018, 9, 29, 12, 17, 0)); } } // Date and Time RTC void isRTC () { // Date and Time dateRTC = ""; timeRTC = ""; DateTime now = rtc.now(); // Date dateRTC = now.year(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.month(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.day(), DEC; // Time timeRTC = now.hour(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.minute(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.second(), DEC; }
getRot.ino
// Rotary Switch // isRot - iRotVal - Value void isRot() { // Rotary Switch z = analogRead( iRotNum ); x = map(z, 0, 4095, 0, 9); iRotVal = map(z, 0, 4095, 0, 10); // Range Value switch ( iRotVal ) { case 0: // Display Environmental isDisplayEnvironmental(); break; case 1: // Display Date isDisplayDate(); break; case 2: // Display BME280 isDisplayBME280(); break; case 3: // Display CCS811 - eCO2 & tVOC isDisplayCCS811(); break; case 4: // Display Gas Sensors MQ isDisplayMQ(); break; case 5: // EMF Meter (Single Axis) isDisplayEMF(); break; case 6: // Display UID isDisplayUID(); break; case 7: // Z isDisplayZ(); break; case 8: // Z isDisplayZ(); break; case 9: // Z isDisplayZ(); break; } }
getSD.ino
// microSD Card // microSD Setup void setupSD() { // microSD Card pinMode( chipSelect , OUTPUT ); if(!SD.begin( chipSelect )){ ; return; } uint8_t cardType = SD.cardType(); if(cardType == CARD_NONE){ ; return; } //Serial.print("SD Card Type: "); if(cardType == CARD_MMC){ ; } else if(cardType == CARD_SD){ ; } else if(cardType == CARD_SDHC){ ; } else { ; } uint64_t cardSize = SD.cardSize() / (1024 * 1024); } // microSD Card void isSD() { zzzzzz = ""; // EEPROM Unique ID|Version|Date|Time|GPS Status|Target Latitude|Target Longitude|Temperature Celsius|Humidity|Altitude Meters|Barometric Pressure|eCO2 Concentration|tVOC Concentration|H2 Gas Sensor MQ-8|CO Gas Sensor MQ-9|CO Gas Sensor MQ-7|Alcohol Gas Sensor MQ-3|EMF Meter (Single Axis) zzzzzz = uid + "|" + sver + "|" + dateRTC + "|" + timeRTC + "|" + GPSStatus + "|" + TargetLat + "|" + TargetLon + "|" + BMEtempC + "|" + BMEhumid + "|" + BMEaltitudeM + "|" + BMEpressure + "|" + CCS811CO2 + "|" + CCS811TVOC + "|" + iMQ8ppm + "|" + iMQ9ppm + "|" + iMQ7ppm + "|" + iMQ9ppm + "|" + iMQ3ppm + "|" + averageEMF + "|\r"; char msg[zzzzzz.length() + 1]; zzzzzz.toCharArray(msg, zzzzzz.length() + 1); appendFile(SD, "/espdata.txt", msg ); } // List Dir void listDir(fs::FS &fs, const char * dirname, uint8_t levels){ dirname; File root = fs.open(dirname); if(!root){ return; } if(!root.isDirectory()){ return; } File file = root.openNextFile(); while(file){ if(file.isDirectory()){ file.name(); if(levels){ listDir(fs, file.name(), levels -1); } } else { file.name(); file.size(); } file = root.openNextFile(); } } // Write File void writeFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_WRITE); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); } // Append File void appendFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_APPEND); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); }
setup.ino
// Setup void setup() { // EEPROM Size EEPROM.begin(EEPROM_SIZE); // EEPROM Unique ID isUID(); // GPS Receiver // Setup GPS setupGPS(); // SHARP Display Start & Clear the Display display.begin(); // Clear Display display.clearDisplay(); // Display UID isDisplayUID(); // Wire - Inialize I2C Hardware Wire.begin(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure myBME280.begin(); // CCS811 - eCO2 & tVOC myCCS811.begin(); // Initialize the LED Green pinMode(iLEDGreen, OUTPUT); // Date & Time RTC // PCF8523 Precision RTC setupRTC(); // Date & Time isRTC(); // microSD Card setupSD(); // Slide Switch pinMode(iSS1, INPUT); // EMF Meter (Single Axis) - Setup isSetupEMF(); delay( 5000 ); }
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Don Luc
Project #15: Environment – SparkFun Alcohol Gas Sensor – MQ-3 – Mk09
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#DonLuc #Environment #Microcontrollers #ESP32 #MQ #GPS #SparkFun #Adafruit #Pololu #Fritzing #Programming #Arduino #Electronics #Consultant #Vlog #Aphasia
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DL2005Mk010
1 x SparkFun Thing Plus – ESP32 WROOM
1 x Adafruit SHARP Memory Display
1 x SparkFun Environmental Combo Breakout – CCS811/BME280
1 x Adafruit Adalogger FeatherWing – RTC + SD
1 x SparkFun GPS Receiver – GP-20U7
1 x CR1220 12mm Lithium Battery
1 x 32Gb microSD Card
1 x Mountable Slide Switch
1 x SparkFun Rotary Switch – 10 Position
1 x Black Knob
1 x Breadboard Solderable
4 x Pololu Carrier for MQ Gas Sensors
1 x SparkFun Hydrogen Gas Sensor – MQ-8
1 x Pololu Carbon Monoxide & Flammable Gas Sensor – MQ-9
1 x SparkFun Carbon Monoxide Gas Sensor – MQ-7
1 x SparkFun Alcohol Gas Sensor – MQ-3
1 x Qwiic Cable – 100mm
1 x LED Green
11 x 1K Ohm
1 x 4.7K Ohm
2 x 10K Ohm
1 x 20k Ohm
1 x 220k Ohm
10 x Jumper Wires 3in M/M
10 x Jumper Wires 6in M/M
16 x Wire Solid Core – 22 AWG
2 x Full-Size Breadboard
1 x SparkFun Cerberus USB Cable
1 x DC Power Supply
SparkFun Thing Plus – ESP32 WROOM
LEG – Digital 21
SCK – Digital 13
MOS – Digital 12
SSD – Digital 27
SDA – Digital 23
SCL – Digital 22
SD1 – Digital 33
SC2 – Digital 5
MO2 – Digital 18
MI2 – Digital 19
SS1 – Digital 16
ROT – Analog A1
MH1 – Analog A0
MC1 – Analog A2
MC2 – Analog A3
MA1 – Analog A4
GPS – Digital 14
VIN – +3.3V
GND – GND
DL2005Mk10p.ino
// ***** Don Luc Electronics © ***** // Software Version Information // Project #15: Environment - SparkFun Alcohol Gas Sensor - MQ-3 - Mk09 // 05-09 // DL2005Mk10p.ino 15-09 // EEPROM with Unique ID // 1 x SparkFun Thing Plus - ESP32 WROOM // 1 x Adafruit SHARP Memory Display // 1 x SparkFun Environmental Combo Breakout - CCS811/BME280 // 1 x Adafruit Adalogger FeatherWing - RTC + SD // 1 x SparkFun GPS Receiver - GP-20U7 // 1 x CR1220 12mm Lithium Battery // 1 x 32Gb microSD Card // 1 x Mountable Slide Switch // 1 x SparkFun Rotary Switch - 10 Position // 1 x Black Knob // 1 x Breadboard Solderable // 4 x Pololu Carrier for MQ Gas Sensors // 1 x Pololu Carbon Monoxide & Flammable Gas Sensor - MQ-9 // 1 x SparkFun Hydrogen Gas Sensor - MQ-8 // 1 x SparkFun Carbon Monoxide Gas Sensor - MQ-7 // 1 x SparkFun Alcohol Gas Sensor - MQ-3 // 1 x Qwiic Cable - 100mm // 1 x LED Green // 11 x 1K Ohm // 1 x 4.7K Ohm // 1 x 10K Ohm // 1 x 20K Ohm // 1 x 220k Ohm // 10 x Jumper Wires 3in M/M // 10 x Jumper Wires 6in M/M // 16 x Wire Solid Core - 22 AWG // 2 x Full-Size Breadboard // 1 x SparkFun Cerberus USB Cable // 1 x DC Power Supply // Include the Library Code // EEPROM Library to Read and Write EEPROM with Unique ID for Unit #include "EEPROM.h" // Wire #include <Wire.h> // SHARP Memory Display #include <Adafruit_SharpMem.h> #include <Adafruit_GFX.h> // SparkFun CCS811 - eCO2 & tVOC #include <SparkFunCCS811.h> // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure #include <SparkFunBME280.h> // Date and Time #include "RTClib.h" // SD Card #include "FS.h" #include "SD.h" #include "SPI.h" // GPS Receiver #include <TinyGPS++.h> // Hardware Serial #include <HardwareSerial.h> // LED Green int iLEDGreen = 21; // SHARP Memory Display // any pins can be used #define SHARP_SCK 13 #define SHARP_MOSI 12 #define SHARP_SS 27 // Set the size of the display here - 144x168 Adafruit_SharpMem display(SHARP_SCK, SHARP_MOSI, SHARP_SS, 144, 168); // The currently-available SHARP Memory Display (144x168 pixels) // requires > 4K of microcontroller RAM; it WILL NOT WORK on Arduino Uno // or other <4K "classic" devices! #define BLACK 0 #define WHITE 1 // 1/2 of lesser of display width or height int minorHalfSize; // SparkFun CCS811 - eCO2 & tVOC // Default I2C Address #define CCS811_ADDR 0x5B CCS811 myCCS811(CCS811_ADDR); float CCS811CO2 = 0; float CCS811TVOC = 0; // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure BME280 myBME280; float BMEtempC = 0; float BMEhumid = 0; float BMEaltitudeM = 0; float BMEpressure = 0; // Date and Time // PCF8523 Precision RTC RTC_PCF8523 rtc; String dateRTC = ""; String timeRTC = ""; // microSD Card const int chipSelect = 33; String zzzzzz = ""; // Mountable Slide Switch int iSS1 = 16; // State int iSS1State = 0; // ESP32 HardwareSerial HardwareSerial tGPS(2); // GPS Receiver #define gpsRXPIN 14 // This one is unused and doesnt have a conection #define gpsTXPIN 32 // The TinyGPS++ object TinyGPSPlus gps; float TargetLat; float TargetLon; int GPSStatus = 0; // Rotary Switch - 10 Position // Number 1 => 10 int iRotNum = A0; // iRotVal - Value int iRotVal = 0; // Number int z = 0; int x = 0; // Gas Sensors MQ // Hydrogen Gas Sensor - MQ-8 int iMQ8 = A1; int iMQ8Raw = 0; int iMQ8ppm = 0; // Two points are taken from the curve in datasheet // With these two points, a line is formed which is "approximately equivalent" to the original curve float H2Curve[3] = {2.3, 0.93,-1.44}; // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int iMQ9 = A2; int iMQ9Raw = 0; int iMQ9ppm = 0; // Carbon Monoxide Gas Sensor - MQ-7 int iMQ7 = A3; int iMQ7Raw = 0; int iMQ7ppm = 0; // Alcohol Gas Sensor - MQ-3 int iMQ3 = A4; int iMQ3Raw = 0; int iMQ3ppm = 0; // Software Version Information String sver = "15-09"; // EEPROM Unique ID Information #define EEPROM_SIZE 64 String uid = ""; void loop() { // Receives NEMA data from GPS receiver isGPS(); // Date and Time isRTC(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure isBME280(); // SparkFun CCS811 - eCO2 & tVOC isCCS811(); // Gas Sensors MQ isGasSensor(); // Rotary Switch isRot(); // Slide Switch // Read the state of the iSS1 value iSS1State = digitalRead(iSS1); // If it is the Slide Switch State is HIGH if (iSS1State == HIGH) { // iLEDGreen digitalWrite(iLEDGreen, HIGH ); // microSD Card isSD(); } else { // iLEDGreen digitalWrite(iLEDGreen, LOW ); } delay( 1000 ); }
getBME280.ino
// SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure // isBME280 - Humidity, Temperature, Altitude and Barometric Pressure void isBME280(){ // Temperature Celsius BMEtempC = myBME280.readTempC(); // Humidity BMEhumid = myBME280.readFloatHumidity(); // Altitude Meters BMEaltitudeM = (myBME280.readFloatAltitudeMeters(), 2); // Barometric Pressure BMEpressure = myBME280.readFloatPressure(); }
getCCS811.ino
// CCS811 - eCO2 & tVOC // isCCS811 - eCO2 & tVOC void isCCS811(){ // This sends the temperature & humidity data to the CCS811 myCCS811.setEnvironmentalData(BMEhumid, BMEtempC); // Calling this function updates the global tVOC and eCO2 variables myCCS811.readAlgorithmResults(); // eCO2 Concentration CCS811CO2 = myCCS811.getCO2(); // tVOC Concentration CCS811TVOC = myCCS811.getTVOC(); }
getDisplay.ino
// Display // SHARP Memory Display - UID void isDisplayUID() { // Text Display // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Don Luc Electronics display.setCursor(0,10); display.println( "Don Luc" ); display.setTextSize(2); display.setCursor(0,40); display.println( "Electronics" ); // Version display.setTextSize(3); display.setCursor(0,70); display.println( "Version" ); display.setTextSize(2); display.setCursor(0,100); display.println( sver ); // EEPROM Unique ID display.setTextSize(1); display.setCursor(0,130); display.println( "EEPROM Unique ID" ); display.setTextSize(2); display.setCursor(0,145); display.println( uid ); // Refresh display.refresh(); delay( 100 ); } // Display Environmental void isDisplayEnvironmental(){ // Text Display Environmental // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(1); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,0); display.println( "Temperature Celsius" ); display.setCursor(0,10); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,20); display.println( "Humidity" ); display.setCursor(0,30); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,40); display.println( "Altitude Meters" ); display.setCursor(0,50); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,60); display.println( "Barometric Pressure" ); display.setCursor(0,70); display.print( BMEpressure ); display.println( " Pa" ); // eCO2 Concentration display.setCursor(0,80); display.println( "eCO2 Concentration" ); display.setCursor(0,90); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,100); display.println( "tVOC Concentration" ); display.setCursor(0,110); display.print( CCS811TVOC ); display.println( " ppb" ); // Date display.setCursor(0,120); display.println( dateRTC ); // Time display.setCursor(0,130); display.println( timeRTC ); // GPS Status display.setCursor(0,140); display.println( GPSStatus ); // Target Latitude display.setCursor(0,150); display.println( TargetLat ); // Target Longitude display.setCursor(0,160); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display Date void isDisplayDate() { // Text Display Date // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Date display.setCursor(0,5); display.println( dateRTC ); // Time display.setCursor(0,30); display.println( timeRTC ); // GPS Status display.setCursor(0,60); display.print( "GPS: " ); display.println( GPSStatus ); // Target Latitude display.setCursor(0,80); display.println( "Latitude" ); display.setCursor(0,100); display.println( TargetLat ); // Target Longitude display.setCursor(0,120); display.println( "Longitude" ); display.setCursor(0,140); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display BME280 void isDisplayBME280() { // Text Display BME280 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,10); display.println( "Temperature" ); display.setCursor(0,30); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,50); display.println( "Humidity" ); display.setCursor(0,70); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,90); display.println( "Altitude M" ); display.setCursor(0,110); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,130); display.println( "Barometric" ); display.setCursor(0,150); display.print( BMEpressure ); display.println( "Pa" ); // Refresh display.refresh(); delay( 100 ); } // Display CCS811 - eCO2 & tVOC void isDisplayCCS811() { // Text Display CCS811 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // eCO2 Concentration display.setCursor(0,10); display.println( "eCO2" ); display.setCursor(0,30); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,60); display.println( "tVOC" ); display.setCursor(0,80); display.print( CCS811TVOC ); display.println( " ppb" ); // Refresh display.refresh(); delay( 100 ); } // Display Gas Sensors MQ void isDisplayMQ() { // Text Display MQ // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Gas Sensors MQ display.setCursor(0,10); display.println( "Gas H2 MQ8" ); display.setCursor(0,30); display.print( iMQ8ppm ); display.println( " ppm" ); display.setCursor(0,50); display.println( "Gas CO MQ9" ); display.setCursor(0,70); display.print( iMQ9ppm ); display.println( " ppm" ); display.setCursor(0,90); display.println( "Gas CO MQ7" ); display.setCursor(0,110); display.print( iMQ7ppm ); display.println( " ppm" ); display.setCursor(0,130); display.println( "BAC MQ3" ); display.setCursor(0,150); display.print( iMQ3ppm ); display.println( "%" ); // Refresh display.refresh(); delay( 100 ); } // Display Z void isDisplayZ() { // Text Display Z // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Z display.setCursor(0,10); display.print( "Z: " ); display.println( z ); // Refresh display.refresh(); delay( 100 ); }
getEEPROM.ino
// EEPROM // isUID EEPROM Unique ID void isUID() { // Is Unit ID uid = ""; for (int x = 0; x < 5; x++) { uid = uid + char(EEPROM.read(x)); } }
getGPS.ino
// GPS Receiver // Setup GPS void setupGPS() { // Setup GPS tGPS.begin( 9600 , SERIAL_8N1, gpsRXPIN, gpsTXPIN ); } // isGPS void isGPS(){ // Receives NEMA data from GPS receiver // This sketch displays information every time a new sentence is correctly encoded. while ( tGPS.available() > 0) if (gps.encode( tGPS.read() )) { displayInfo(); } if (millis() > 5000 && gps.charsProcessed() < 10) { while(true); } } // GPS Vector Pointer Target void displayInfo(){ // Location if (gps.location.isValid()) { TargetLat = gps.location.lat(); TargetLon = gps.location.lng(); GPSStatus = 2; } else { GPSStatus = 0; } }
getGasSensorMQ.ino
// Gas Sensors MQ // Gas Sensor void isGasSensor() { // Read in analog value from each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8Raw = analogRead( iMQ8 ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9Raw = analogRead( iMQ9 ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7Raw = analogRead( iMQ7 ); // Alcohol Gas Sensor - MQ-3 iMQ3Raw = analogRead( iMQ3 ); // Caclulate the PPM of each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8ppm = isMQ8( iMQ8Raw ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9ppm = isMQ9( iMQ9Raw ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7ppm = isMQ7( iMQ7Raw ); // Alcohol Gas Sensor - MQ-3 iMQ3ppm = isMQ3( iMQ3Raw ); } // Hydrogen Gas Sensor - MQ-8 - PPM int isMQ8(double rawValue) { // RvRo double RvRo = rawValue * (3.3 / 1023); return (pow(4.7,( ((log(RvRo)-H2Curve[1])/H2Curve[2]) + H2Curve[0]))); } // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int isMQ9(double rawValue) { double RvRo = rawValue * (3.3 / 4095); double ppm = 3.027*exp(1.0698*( RvRo )); return ppm; } // Carbon Monoxide Gas Sensor - MQ-7 int isMQ7(double rawValue) { double RvRo = rawValue * (3.3 / 4095); double ppm = 3.027*exp(1.0698*( RvRo )); return ppm; } // Alcohol Gas Sensor - MQ-3 int isMQ3(double rawValue) { double RvRo = rawValue * (3.3 / 4095); double bac = RvRo * 0.21; return bac; }
getRTC.ino
// Date & Time // PCF8523 Precision RTC void setupRTC() { // Date & Time // pcf8523 Precision RTC if (! rtc.begin()) { while (1); } if (! rtc.initialized()) { // Following line sets the RTC to the date & time this sketch was compiled rtc.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // January 21, 2014 at 3am you would call: // rtc.adjust(DateTime(2018, 9, 29, 12, 17, 0)); } } // Date and Time RTC void isRTC () { // Date and Time dateRTC = ""; timeRTC = ""; DateTime now = rtc.now(); // Date dateRTC = now.year(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.month(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.day(), DEC; // Time timeRTC = now.hour(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.minute(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.second(), DEC; }
getRot.ino
// Rotary Switch // isRot - iRotVal - Value void isRot() { // Rotary Switch z = analogRead( iRotNum ); x = map(z, 0, 4095, 0, 9); iRotVal = map(z, 0, 4095, 0, 10); // Range Value switch ( iRotVal ) { case 0: // Display Environmental isDisplayEnvironmental(); break; case 1: // Display Date isDisplayDate(); break; case 2: // Display BME280 isDisplayBME280(); break; case 3: // Display CCS811 - eCO2 & tVOC isDisplayCCS811(); break; case 4: // Display Gas Sensors MQ isDisplayMQ(); break; case 5: // Display UID isDisplayUID(); break; case 6: // Z isDisplayZ(); break; case 7: // Z isDisplayZ(); break; case 8: // Z isDisplayZ(); break; case 9: // Z isDisplayZ(); break; } }
getSD.ino
// microSD Card // microSD Setup void setupSD() { // microSD Card pinMode( chipSelect , OUTPUT ); if(!SD.begin( chipSelect )){ ; return; } uint8_t cardType = SD.cardType(); if(cardType == CARD_NONE){ ; return; } //Serial.print("SD Card Type: "); if(cardType == CARD_MMC){ ; } else if(cardType == CARD_SD){ ; } else if(cardType == CARD_SDHC){ ; } else { ; } uint64_t cardSize = SD.cardSize() / (1024 * 1024); } // microSD Card void isSD() { zzzzzz = ""; // EEPROM Unique ID|Version|Date|Time|GPS Status|Target Latitude|Target Longitude|Temperature Celsius|Humidity|Altitude Meters|Barometric Pressure|eCO2 Concentration|tVOC Concentration|H2 Gas Sensor MQ-8|CO Gas Sensor MQ-9|CO Gas Sensor MQ-7|Alcohol Gas Sensor MQ-3 zzzzzz = uid + "|" + sver + "|" + dateRTC + "|" + timeRTC + "|" + GPSStatus + "|" + TargetLat + "|" + TargetLon + "|" + BMEtempC + "|" + BMEhumid + "|" + BMEaltitudeM + "|" + BMEpressure + "|" + CCS811CO2 + "|" + CCS811TVOC + "|" + iMQ8ppm + "|" + iMQ9ppm + "|" + iMQ7ppm + "|" + iMQ9ppm + "|" + iMQ3ppm + "|\r"; char msg[zzzzzz.length() + 1]; zzzzzz.toCharArray(msg, zzzzzz.length() + 1); appendFile(SD, "/espdata.txt", msg ); } // List Dir void listDir(fs::FS &fs, const char * dirname, uint8_t levels){ dirname; File root = fs.open(dirname); if(!root){ return; } if(!root.isDirectory()){ return; } File file = root.openNextFile(); while(file){ if(file.isDirectory()){ file.name(); if(levels){ listDir(fs, file.name(), levels -1); } } else { file.name(); file.size(); } file = root.openNextFile(); } } // Write File void writeFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_WRITE); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); } // Append File void appendFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_APPEND); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); }
setup.ino
// Setup void setup() { // EEPROM Size EEPROM.begin(EEPROM_SIZE); // EEPROM Unique ID isUID(); // GPS Receiver // Setup GPS setupGPS(); // SHARP Display Start & Clear the Display display.begin(); // Clear Display display.clearDisplay(); // Display UID isDisplayUID(); // Wire - Inialize I2C Hardware Wire.begin(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure myBME280.begin(); // CCS811 - eCO2 & tVOC myCCS811.begin(); // Initialize the LED Green pinMode(iLEDGreen, OUTPUT); // Date & Time RTC // PCF8523 Precision RTC setupRTC(); // Date & Time isRTC(); // microSD Card setupSD(); // Slide Switch pinMode(iSS1, INPUT); delay( 5000 ); }
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Don Luc
Project #15: Environment – SparkFun Carbon Monoxide Gas Sensor – MQ-7 – Mk08
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#DonLuc #Environment #Microcontrollers #ESP32 #MQ-X #GPS #SparkFun #Adafruit #Pololu #Fritzing #Programming #Arduino #Electronics #Consultant #Vlog #Aphasia
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DL2005Mk08
1 x SparkFun Thing Plus – ESP32 WROOM
1 x Adafruit SHARP Memory Display
1 x SparkFun Environmental Combo Breakout – CCS811/BME280
1 x Adafruit Adalogger FeatherWing – RTC + SD
1 x SparkFun GPS Receiver – GP-20U7
1 x CR1220 12mm Lithium Battery
1 x 32Gb microSD Card
1 x Mountable Slide Switch
1 x SparkFun Rotary Switch – 10 Position
1 x Black Knob
1 x Breadboard Solderable
3 x Pololu Carrier for MQ Gas Sensors
1 x SparkFun Hydrogen Gas Sensor – MQ-8
1 x Pololu Carbon Monoxide & Flammable Gas Sensor – MQ-9
1 x SparkFun Carbon Monoxide Gas Sensor – MQ-7
1 x Qwiic Cable – 100mm
1 x LED Green
11 x 1K Ohm
1 x 4.7K Ohm
2 x 10K Ohm
1 x 20k Ohm
8 x Jumper Wires 3in M/M
9 x Jumper Wires 6in M/M
16 x Wire Solid Core – 22 AWG
2 x Full-Size Breadboard
1 x SparkFun Cerberus USB Cable
1 x DC Power Supply
SparkFun Thing Plus – ESP32 WROOM
LEG – Digital 21
SCK – Digital 13
MOS – Digital 12
SSD – Digital 27
SDA – Digital 23
SCL – Digital 22
SD1 – Digital 33
SC2 – Digital 5
MO2 – Digital 18
MI2 – Digital 19
SS1 – Digital 16
ROT – Analog A0
MH1 – Analog A1
MC1 – Analog A2
MC2 – Analog A3
GPS – Digital 14
VIN – +3.3V
GND – GND
DL2005Mk08p.ino
// ***** Don Luc Electronics © ***** // Software Version Information // Project #15: Environment - SparkFun Carbon Monoxide Gas Sensor - MQ-7 - Mk08 // 05-08 // DL2005Mk08p.ino 15-08 // EEPROM with Unique ID // 1 x SparkFun Thing Plus - ESP32 WROOM // 1 x Adafruit SHARP Memory Display // 1 x SparkFun Environmental Combo Breakout - CCS811/BME280 // 1 x Adafruit Adalogger FeatherWing - RTC + SD // 1 x SparkFun GPS Receiver - GP-20U7 // 1 x CR1220 12mm Lithium Battery // 1 x 32Gb microSD Card // 1 x Mountable Slide Switch // 1 x SparkFun Rotary Switch - 10 Position // 1 x Black Knob // 1 x Breadboard Solderable // 3 x Pololu Carrier for MQ Gas Sensors // 1 x Pololu Carbon Monoxide & Flammable Gas Sensor - MQ-9 // 1 x SparkFun Hydrogen Gas Sensor - MQ-8 // 1 x SparkFun Carbon Monoxide Gas Sensor - MQ-7 // 1 x Qwiic Cable - 100mm // 1 x LED Green // 11 x 1K Ohm // 1 x 4.7K Ohm // 1 x 10K Ohm // 1 x 20K Ohm // 8 x Jumper Wires 3in M/M // 9 x Jumper Wires 6in M/M // 16 x Wire Solid Core - 22 AWG // 2 x Full-Size Breadboard // 1 x SparkFun Cerberus USB Cable // 1 x DC Power Supply // Include the Library Code // EEPROM Library to Read and Write EEPROM with Unique ID for Unit #include "EEPROM.h" // Wire #include <Wire.h> // SHARP Memory Display #include <Adafruit_SharpMem.h> #include <Adafruit_GFX.h> // SparkFun CCS811 - eCO2 & tVOC #include <SparkFunCCS811.h> // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure #include <SparkFunBME280.h> // Date and Time #include "RTClib.h" // SD Card #include "FS.h" #include "SD.h" #include "SPI.h" // GPS Receiver #include <TinyGPS++.h> // Hardware Serial #include <HardwareSerial.h> // LED Green int iLEDGreen = 21; // SHARP Memory Display // any pins can be used #define SHARP_SCK 13 #define SHARP_MOSI 12 #define SHARP_SS 27 // Set the size of the display here - 144x168 Adafruit_SharpMem display(SHARP_SCK, SHARP_MOSI, SHARP_SS, 144, 168); // The currently-available SHARP Memory Display (144x168 pixels) // requires > 4K of microcontroller RAM; it WILL NOT WORK on Arduino Uno // or other <4K "classic" devices! #define BLACK 0 #define WHITE 1 // 1/2 of lesser of display width or height int minorHalfSize; // SparkFun CCS811 - eCO2 & tVOC // Default I2C Address #define CCS811_ADDR 0x5B CCS811 myCCS811(CCS811_ADDR); float CCS811CO2 = 0; float CCS811TVOC = 0; // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure BME280 myBME280; float BMEtempC = 0; float BMEhumid = 0; float BMEaltitudeM = 0; float BMEpressure = 0; // Date and Time // PCF8523 Precision RTC RTC_PCF8523 rtc; String dateRTC = ""; String timeRTC = ""; // microSD Card const int chipSelect = 33; String zzzzzz = ""; // Mountable Slide Switch int iSS1 = 16; // State int iSS1State = 0; // ESP32 HardwareSerial HardwareSerial tGPS(2); // GPS Receiver #define gpsRXPIN 14 // This one is unused and doesnt have a conection #define gpsTXPIN 32 // The TinyGPS++ object TinyGPSPlus gps; float TargetLat; float TargetLon; int GPSStatus = 0; // Rotary Switch - 10 Position // Number 1 => 10 int iRotNum = A0; // iRotVal - Value int iRotVal = 0; // Number int z = 0; int x = 0; // Gas Sensors MQ // Hydrogen Gas Sensor - MQ-8 int iMQ8 = A1; int iMQ8Raw = 0; int iMQ8ppm = 0; // Two points are taken from the curve in datasheet // With these two points, a line is formed which is "approximately equivalent" to the original curve float H2Curve[3] = {2.3, 0.93,-1.44}; // Carbon Monoxide & Flammable Gas Sensor - MQ-9 int iMQ9 = A2; int iMQ9Raw = 0; int iMQ9ppm = 0; // Carbon Monoxide Gas Sensor - MQ-7 int iMQ7 = A3; int iMQ7Raw = 0; int iMQ7ppm = 0; // Software Version Information String sver = "15-08"; // EEPROM Unique ID Information #define EEPROM_SIZE 64 String uid = ""; void loop() { // Receives NEMA data from GPS receiver isGPS(); // Date and Time isRTC(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure isBME280(); // SparkFun CCS811 - eCO2 & tVOC isCCS811(); // Gas Sensors MQ isGasSensor(); // Rotary Switch isRot(); // Slide Switch // Read the state of the iSS1 value iSS1State = digitalRead(iSS1); // If it is the Slide Switch State is HIGH if (iSS1State == HIGH) { // iLEDGreen digitalWrite(iLEDGreen, HIGH ); // microSD Card isSD(); } else { // iLEDGreen digitalWrite(iLEDGreen, LOW ); } delay( 1000 ); }
getBME280.ino
// SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure // isBME280 - Humidity, Temperature, Altitude and Barometric Pressure void isBME280(){ // Temperature Celsius BMEtempC = myBME280.readTempC(); // Humidity BMEhumid = myBME280.readFloatHumidity(); // Altitude Meters BMEaltitudeM = (myBME280.readFloatAltitudeMeters(), 2); // Barometric Pressure BMEpressure = myBME280.readFloatPressure(); }
getCCS811.ino
// CCS811 - eCO2 & tVOC // isCCS811 - eCO2 & tVOC void isCCS811(){ // This sends the temperature & humidity data to the CCS811 myCCS811.setEnvironmentalData(BMEhumid, BMEtempC); // Calling this function updates the global tVOC and eCO2 variables myCCS811.readAlgorithmResults(); // eCO2 Concentration CCS811CO2 = myCCS811.getCO2(); // tVOC Concentration CCS811TVOC = myCCS811.getTVOC(); }
getDisplay.ino
// Display // SHARP Memory Display - UID void isDisplayUID() { // Text Display // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Don Luc Electronics display.setCursor(0,10); display.println( "Don Luc" ); display.setTextSize(2); display.setCursor(0,40); display.println( "Electronics" ); // Version display.setTextSize(3); display.setCursor(0,70); display.println( "Version" ); display.setTextSize(2); display.setCursor(0,100); display.println( sver ); // EEPROM Unique ID display.setTextSize(1); display.setCursor(0,130); display.println( "EEPROM Unique ID" ); display.setTextSize(2); display.setCursor(0,145); display.println( uid ); // Refresh display.refresh(); delay( 100 ); } // Display Environmental void isDisplayEnvironmental(){ // Text Display Environmental // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(1); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,0); display.println( "Temperature Celsius" ); display.setCursor(0,10); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,20); display.println( "Humidity" ); display.setCursor(0,30); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,40); display.println( "Altitude Meters" ); display.setCursor(0,50); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,60); display.println( "Barometric Pressure" ); display.setCursor(0,70); display.print( BMEpressure ); display.println( " Pa" ); // eCO2 Concentration display.setCursor(0,80); display.println( "eCO2 Concentration" ); display.setCursor(0,90); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,100); display.println( "tVOC Concentration" ); display.setCursor(0,110); display.print( CCS811TVOC ); display.println( " ppb" ); // Date display.setCursor(0,120); display.println( dateRTC ); // Time display.setCursor(0,130); display.println( timeRTC ); // GPS Status display.setCursor(0,140); display.println( GPSStatus ); // Target Latitude display.setCursor(0,150); display.println( TargetLat ); // Target Longitude display.setCursor(0,160); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display Date void isDisplayDate() { // Text Display Date // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Date display.setCursor(0,5); display.println( dateRTC ); // Time display.setCursor(0,30); display.println( timeRTC ); // GPS Status display.setCursor(0,60); display.print( "GPS: " ); display.println( GPSStatus ); // Target Latitude display.setCursor(0,80); display.println( "Latitude" ); display.setCursor(0,100); display.println( TargetLat ); // Target Longitude display.setCursor(0,120); display.println( "Longitude" ); display.setCursor(0,140); display.println( TargetLon ); // Refresh display.refresh(); delay( 100 ); } // Display BME280 void isDisplayBME280() { // Text Display BME280 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Temperature Celsius display.setCursor(0,10); display.println( "Temperature" ); display.setCursor(0,30); display.print( BMEtempC ); display.println( " C" ); // Humidity display.setCursor(0,50); display.println( "Humidity" ); display.setCursor(0,70); display.print( BMEhumid ); display.println( "%" ); // Altitude Meters display.setCursor(0,90); display.println( "Altitude M" ); display.setCursor(0,110); display.print( BMEaltitudeM ); display.println( " m" ); // Pressure display.setCursor(0,130); display.println( "Barometric" ); display.setCursor(0,150); display.print( BMEpressure ); display.println( "Pa" ); // Refresh display.refresh(); delay( 100 ); } // Display CCS811 - eCO2 & tVOC void isDisplayCCS811() { // Text Display CCS811 // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // eCO2 Concentration display.setCursor(0,10); display.println( "eCO2" ); display.setCursor(0,30); display.print( CCS811CO2 ); display.println( " ppm" ); // tVOC Concentration display.setCursor(0,60); display.println( "tVOC" ); display.setCursor(0,80); display.print( CCS811TVOC ); display.println( " ppb" ); // Refresh display.refresh(); delay( 100 ); } // Display Gas Sensors MQ void isDisplayMQ() { // Text Display MQ // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(2); display.setTextColor(BLACK); // Gas Sensors MQ display.setCursor(0,10); display.println( "Gas Sensors" ); display.setCursor(0,30); display.println( "Gas H2 MQ8" ); display.setCursor(0,50); display.print( iMQ8ppm ); display.println( " ppm" ); display.setCursor(0,70); display.println( "Gas CO MQ9" ); display.setCursor(0,90); display.print( iMQ9ppm ); display.println( " ppm" ); display.setCursor(0,110); display.println( "Gas CO MQ7" ); display.setCursor(0,130); display.print( iMQ7ppm ); display.println( " ppm" ); // Refresh display.refresh(); delay( 100 ); } // Display Z void isDisplayZ() { // Text Display Z // Clear Display display.clearDisplay(); display.setRotation(4); display.setTextSize(3); display.setTextColor(BLACK); // Z display.setCursor(0,10); display.print( "Z: " ); display.println( z ); // Refresh display.refresh(); delay( 100 ); }
getEEPROM.ino
// EEPROM // isUID EEPROM Unique ID void isUID() { // Is Unit ID uid = ""; for (int x = 0; x < 5; x++) { uid = uid + char(EEPROM.read(x)); } }
getGPS.ino
// GPS Receiver // Setup GPS void setupGPS() { // Setup GPS tGPS.begin( 9600 , SERIAL_8N1, gpsRXPIN, gpsTXPIN ); } // isGPS void isGPS(){ // Receives NEMA data from GPS receiver // This sketch displays information every time a new sentence is correctly encoded. while ( tGPS.available() > 0) if (gps.encode( tGPS.read() )) { displayInfo(); } if (millis() > 5000 && gps.charsProcessed() < 10) { while(true); } } // GPS Vector Pointer Target void displayInfo(){ // Location if (gps.location.isValid()) { TargetLat = gps.location.lat(); TargetLon = gps.location.lng(); GPSStatus = 2; } else { GPSStatus = 0; } }
getGasSensorMQ.ino
// Gas Sensors MQ // Gas Sensor void isGasSensor() { // Read in analog value from each gas sensors // Hydrogen Gas Sensor - MQ-8 iMQ8Raw = analogRead( iMQ8 ); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 iMQ9Raw = analogRead( iMQ9 ); // Carbon Monoxide Gas Sensor - MQ-7 iMQ7Raw = analogRead( iMQ7 ); // Caclulate the PPM of each gas sensors // Hydrogen Gas Sensor - MQ-8 isMQ8(); // Carbon Monoxide & Flammable Gas Sensor - MQ-9 isMQ9(); // Carbon Monoxide Gas Sensor - MQ-7 isMQ7(); } // Hydrogen Gas Sensor - MQ-8 - PPM void isMQ8() { double RvRo = iMQ8Raw * (3.3 / 1023); iMQ8ppm = (pow(4.7,( ((log(RvRo)-H2Curve[1])/H2Curve[2]) + H2Curve[0]))); } // Carbon Monoxide & Flammable Gas Sensor - MQ-9 void isMQ9() { double RvRo = iMQ9Raw * (3.3 / 4095); iMQ9ppm = 3.027*exp(1.0698*( RvRo )); } // Carbon Monoxide Gas Sensor - MQ-7 int isMQ7() { double RvRo = iMQ7Raw * (3.3 / 4095); iMQ7ppm = 3.027*exp(1.0698*( RvRo )); }
getRTC.ino
// Date & Time // PCF8523 Precision RTC void setupRTC() { // Date & Time // pcf8523 Precision RTC if (! rtc.begin()) { while (1); } if (! rtc.initialized()) { // Following line sets the RTC to the date & time this sketch was compiled rtc.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // January 21, 2014 at 3am you would call: // rtc.adjust(DateTime(2018, 9, 29, 12, 17, 0)); } } // Date and Time RTC void isRTC () { // Date and Time dateRTC = ""; timeRTC = ""; DateTime now = rtc.now(); // Date dateRTC = now.year(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.month(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.day(), DEC; // Time timeRTC = now.hour(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.minute(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.second(), DEC; }
getRot.ino
// Rotary Switch // isRot - iRotVal - Value void isRot() { // Rotary Switch z = analogRead( iRotNum ); x = map(z, 0, 4095, 0, 9); iRotVal = map(z, 0, 4095, 0, 10); // Range Value switch ( iRotVal ) { case 0: // Display Environmental isDisplayEnvironmental(); break; case 1: // Display Date isDisplayDate(); break; case 2: // Display BME280 isDisplayBME280(); break; case 3: // Display CCS811 - eCO2 & tVOC isDisplayCCS811(); break; case 4: // Display Gas Sensors MQ isDisplayMQ(); break; case 5: // Display UID isDisplayUID(); break; case 6: // Z isDisplayZ(); break; case 7: // Z isDisplayZ(); break; case 8: // Z isDisplayZ(); break; case 9: // Z isDisplayZ(); break; } }
getSD.ino
// microSD Card // microSD Setup void setupSD() { // microSD Card pinMode( chipSelect , OUTPUT ); if(!SD.begin( chipSelect )){ ; return; } uint8_t cardType = SD.cardType(); if(cardType == CARD_NONE){ ; return; } //Serial.print("SD Card Type: "); if(cardType == CARD_MMC){ ; } else if(cardType == CARD_SD){ ; } else if(cardType == CARD_SDHC){ ; } else { ; } uint64_t cardSize = SD.cardSize() / (1024 * 1024); } // microSD Card void isSD() { zzzzzz = ""; // EEPROM Unique ID|Version|Date|Time|GPS Status|Target Latitude|Target Longitude|Temperature Celsius|Humidity|Altitude Meters|Barometric Pressure|eCO2 Concentration|tVOC Concentration|H2 Gas Sensor MQ-8|CO Gas Sensor MQ-9|CO Gas Sensor MQ-7 zzzzzz = uid + "|" + sver + "|" + dateRTC + "|" + timeRTC + "|" + GPSStatus + "|" + TargetLat + "|" + TargetLon + "|" + BMEtempC + "|" + BMEhumid + "|" + BMEaltitudeM + "|" + BMEpressure + "|" + CCS811CO2 + "|" + CCS811TVOC + "|" + iMQ8ppm + "|" + iMQ9ppm + "|" + iMQ7ppm + "|\r"; char msg[zzzzzz.length() + 1]; zzzzzz.toCharArray(msg, zzzzzz.length() + 1); appendFile(SD, "/espdata.txt", msg ); } // List Dir void listDir(fs::FS &fs, const char * dirname, uint8_t levels){ dirname; File root = fs.open(dirname); if(!root){ return; } if(!root.isDirectory()){ return; } File file = root.openNextFile(); while(file){ if(file.isDirectory()){ file.name(); if(levels){ listDir(fs, file.name(), levels -1); } } else { file.name(); file.size(); } file = root.openNextFile(); } } // Write File void writeFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_WRITE); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); } // Append File void appendFile(fs::FS &fs, const char * path, const char * message){ path; File file = fs.open(path, FILE_APPEND); if(!file){ return; } if(file.print(message)){ ; } else { ; } file.close(); }
setup.ino
// Setup void setup() { // EEPROM Size EEPROM.begin(EEPROM_SIZE); // EEPROM Unique ID isUID(); // GPS Receiver // Setup GPS setupGPS(); // SHARP Display Start & Clear the Display display.begin(); // Clear Display display.clearDisplay(); // Display UID isDisplayUID(); // Wire - Inialize I2C Hardware Wire.begin(); // SparkFun BME280 - Humidity, Temperature, Altitude and Barometric Pressure myBME280.begin(); // CCS811 - eCO2 & tVOC myCCS811.begin(); // Initialize the LED Green pinMode(iLEDGreen, OUTPUT); // Date & Time RTC // PCF8523 Precision RTC setupRTC(); // Date & Time isRTC(); // microSD Card setupSD(); // Slide Switch pinMode(iSS1, INPUT); delay( 5000 ); }
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