| In this example we look at a MICS 5524 gas module The MiCS-5524 is a robust MEMS sensor for indoor carbon monoxide and natural gas leakage detection; suitable also for indoor air quality monitoring; breath checker and early fire detection. Detectable gases • Carbon monoxide CO 1 – 1000ppm
• Ethanol C2H5OH 10 – 500ppm
• Hydrogen H2 1 – 1000ppm
• Ammonia NH3 1 – 500ppm
• Methane CH4 >1000ppm One thing to note is that this sensor is sensitive to multiple gasses, as you can see above – but does not know which gas it is Connection | Arduino Uno | MICS 5524 module | | 5v | 5v | | Gnd | Gnd | | A0 | A0 | | | | | | |
 arduino and mics5524 Parts ListHere are the parts I used Codevoid setup()
{
Serial.begin(9600);
Serial.println("MiCS-5524 demo!");
}
void loop()
{
int reading = analogRead(A0);
Serial.println(reading);
delay(100);
}OutputOPen the serial monitor, if you have a gas source such as alcohol then you could test this further MiCS-5524 demo!
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54 Serial plotter example 
Links In this example we look at the CJMCU-1010 module – this is based on the AT42QT101x The AT42QT101x Single Key capacitive touch controller family provides an easy way to add a touch key to any application. It implements advanced filtering algorithm to offer robust operation in noisy environment. Sensitivity and low power modes can be configured as well. The AT42QT1011 output will remain high as long as a touch is detected. No “Max On” time out. Additional Features - Number of Keys: One – configurable as either a single key or a proximity sensor
- Key outline sizes: 6 mm × 6 mm or larger (panel thickness dependent); widely different sizes and shapes possible
- Electrode design: Solid or ring electrode shapes
- PCB Layers required: One
- Electrode materials: Etched copper, silver, carbon, Indium Tin Oxide (ITO)
- Panel thickness: Up to 12 mm glass, 6 mm plastic (electrode size and Cs dependent)
- Key sensitivity: Settable via capacitor (Cs)
- Power consumption: 17 µA at 1.8 V typical
- Applications: Control panels, consumer appliances, IoT, proximity sensor applications, toys, lighting controls, mechanical switch or button replacement
Connection | Arduino Uno | CJMCU-1010 module | | 5v | Vcc | | Gnd | Gnd | | D2 | OUT | | | | | | |
Parts ListHere are the parts I used Codeconst int TOUCH_BUTTON_PIN = 2; // Input pin for touch state
const int LED_PIN = 13; // Pin number for LED
// Global Variables
int buttonState = 0; // Variable for reading button
void setup() {
// Configure button pin as input
pinMode(TOUCH_BUTTON_PIN, INPUT);
// Configure LED pin as output
pinMode(LED_PIN, OUTPUT);
}
void loop() {
// Read the state of the capacitive touch board
buttonState = digitalRead(TOUCH_BUTTON_PIN);
// If a touch is detected, turn on the LED
if (buttonState == HIGH) {
digitalWrite(LED_PIN, HIGH);
} else {
digitalWrite(LED_PIN, LOW);
}
}
Linkshttp://ww1.microchip.com/downloads/en/devicedoc/40001948a.pdf In this example we look at the ISL29125 RED, GREEN and BLUE color light sensor Here is some info about the sensor The ISL29125 is a low power, high sensitivity, RED, GREEN and BLUE color light sensor (RGB) with an I2 C (SMBus compatible) interface. Its state-of-the-art photodiode array provides an accurate RGB spectral response and excellent light source to light source variation (LS2LS). The ISL29125 is designed to reject IR in light sources allowing the device to operate in environments from sunlight to dark rooms. The integrating ADC rejects 50Hz and 60Hz flicker caused by artificial light sources. A selectable range allows the user to optimize sensitivity suitable for the specific application. In normal operation mode the device consumes 56µA, which reduces to 0.5µA in power-down mode. The ISL29125 supports hardware and software user programmable interrupt thresholds. The Interrupt persistency feature reduces false trigger notification. The device operates on supplies (VDD) from 2.25V to 3.63V, I2 C supply from 1.7V to 3.63V, and operating temperature across the -40°C to +85°C range. 
FEATURES- 56µA operating current, 0.5µA shutdown current
- Selectable range (Via I2C)
- I2C (SMBus compatible) output
- ADC resolution 16 bits
- Programmable interrupt windows
- Two optical sensitivity ranges
- Range 0 = 5.7m lux to 375 lux
- Range 1 = 0.152 lux to 10,000 lux
- Operating power supply 2.25 to 3.63V
- I2C power supply 1.7V to 3.63V
- 6 Ld ODFN (1.65×1.65×0.7mm) package
Connection | Arduino Uno | CJMCU-0401 module | | 3v3 | Vcc | | Gnd | Gnd | | A4 – SDA | SDA | | A5 – SCL | SCL | | | | |
Parts ListHere are the parts I used CodeThis example requires the https://github.com/sparkfun/SparkFun_ISL29125_Breakout_Arduino_Library #include <Wire.h>
#include "SparkFunISL29125.h"
// Declare sensor object
SFE_ISL29125 RGB_sensor;
void setup()
{
// Initialize serial communication
Serial.begin(115200);
// Initialize the ISL29125 with simple configuration so it starts sampling
if (RGB_sensor.init())
{
Serial.println("Sensor Initialization Successful\n\r");
}
}
// Read sensor values for each color and print them to serial monitor
void loop()
{
// Read sensor values (16 bit integers)
unsigned int red = RGB_sensor.readRed();
unsigned int green = RGB_sensor.readGreen();
unsigned int blue = RGB_sensor.readBlue();
// Print out readings, change HEX to DEC if you prefer decimal output
Serial.print("Red: "); Serial.println(red,HEX);
Serial.print("Green: "); Serial.println(green,HEX);
Serial.print("Blue: "); Serial.println(blue,HEX);
Serial.println();
delay(2000);
}
OutputOpen the serial monitor – this is what you should expect to see Links In this example we look at the CJMCU-0401, this is the module in question its a 4-bit Button Capacitive Touch Proximity Sensor With Self-locking Function
 Description: CJMCU-0401 is a touch IC designed with capacitive sensing principle.
Its stable sensing method can be applied to a variety of electronic products, the panel dielectric can be completely insulated material,
designed to replace the traditional mechanical structure switch or ordinary buttons.
Provides four touch inputs and four direct output pins and four LED indicators. Features: 1. Operating voltage: 2.0V ~ 5.5V
2. The highest power consumption is 11.5uA, low power mode is only 4uA ( in 3V and no load)
3. External configuration pin is set to multiple modes
4. High reliability, the chip built-in debounce circuit, which can effectively prevent external noise interference caused by the malfunction
5. Can be used for glass, ceramics, plastics and other media surface
6. With automatic calibration function, when no keys are touched, the system recalibration cycle is about 4.0 Sec The CJMCU-0401 uses a CT8224 Connection | Arduino Uno | CJMCU-0401 module | | 5v | Vcc | | Gnd | Gnd | | D4 | Out1 | | D5 | Out2 | | D6 | Out3 | | D7 | Out4 |
Parts ListHere are the parts I used CodeThis example does not require any libraries const int Pins[4] = {4, 5, 6, 7};
void setup()
{
Serial.begin(9600);
for (int i = 0; i < 4; i++)
{
pinMode(Pins[i], INPUT_PULLUP);
}
}
void loop()
{
boolean sensorVal = false;
// Set sensorValue to 'true' if any pin reads HIGH
for (int i = 0; i < 4 && sensorVal == false; i++)
{
sensorVal = digitalRead(Pins[i]);
//print out the value of the pushbutton
Serial.print("Pin ");
Serial.print(Pins[i]);
Serial.print(": ");
Serial.println(sensorVal);
}
// Set the LED to opposite of 'sensorValue' (on unless at least one pin reads HIGH)
delay(250);
} OutputOpen the serial monitor – this is what you should expect to see Pin 4: 0
Pin 5: 0
Pin 6: 0
Pin 7: 1
Pin 4: 0
Pin 5: 0
Pin 6: 0
Pin 7: 1
Pin 4: 0
Pin 5: 0
Pin 6: 0
Pin 7: 1
Pin 4: 0
Pin 5: 0
Pin 6: 1
Pin 4: 0
Pin 5: 1
Pin 4: 0
Pin 5: 1
Pin 4: 1
Pin 4: 1
Pin 4: 1
Pin 4: 1
Pin 4: 1
Pin 4: 1
Pin 4: 1
Pin 4: 0
Pin 5: 0
Pin 6: 0
Pin 7: 0 Linksdatasheet | Subscribe to Arduinolearning via Email |
