The MCP3421 ADC can be used for various high accuracy analog-to-digital data conversion applications where ease of use, low power consumption and small footprint are major considerations.The MCP3421 is a single channel low-noise, high accuracy delta-sigma A/D converter with differential inputs and up to 18 bits of resolution in a small SOT-23-6 package.
The on-board precision 2.048V reference voltage enables a differential input range of ±2.048V. The device uses a two-wire I2C™ compatible interface and operates from a single power supply ranging from 2.7V to 5.5V. The MCP3421 ADC performs conversions at rates of 3.75, 15, 60 or 240 samples per second with corresponding resolutions of 18, 16, 14 and 12 bits. The onboard programmable gain amplifier (PGA) provides gain up to 8x. The device has two conversion modes: Continuous mode and One-Shot mode. In One-Shot mode, the device enters a low current standby mode automatically after a conversion, greatly reducing power use.
// Include libraries this sketch will use#include <Wire.h>#include <MCP342X.h>// Instantiate objects used in this project
MCP342X myADC;int outputPin =6;void setup(){
Wire.begin();// join I2C bus
TWBR =12;// 400 kHz (maximum)
Serial.begin(9600);// Open serial connection to send info to the hostwhile(!Serial){}// wait for Serial comms to become ready
Serial.println("Starting up");
Serial.println("Testing device connection...");
Serial.println(myADC.testConnection()?"MCP342X connection successful":"MCP342X connection failed");
myADC.configure( MCP342X_MODE_CONTINUOUS |
MCP342X_CHANNEL_1 |
MCP342X_SIZE_16BIT |
MCP342X_GAIN_1X
);
Serial.println(myADC.getConfigRegShdw(), HEX);}// End of setup()void loop(){static int16_t result;for(int i=0; i<=255; i++){
myADC.startConversion();
analogWrite(outputPin, i);
myADC.getResult(&result);
Serial.print(i);
Serial.print(" ");
Serial.print(result);
Serial.print(" ");
Serial.println(result, HEX);}}// End of loop()
In this example we will connect a MMA8452Q accelerometer to an Arduino Uno
Lets look at some information about the sensor
The MMA8452Q is a smart, low-power, three-axis, capacitive, micromachined accelerometer with 12 bits of resolution. This accelerometer is packed with embedded functions with flexible user programmable options, configurable to two interrupt pins. Embedded interrupt functions allow for overall power savings relieving the host processor from continuously polling data.
The MMA8452Q has user selectable full scales of ±2 g/±4 g/±8 g with high-pass filtered data as well as non-filtered data available real-time. The device can be configured to generate inertial wakeup interrupt signals from any combination of the configurable embedded functions allowing the MMA8452Q to monitor events and remain in a low-power mode during periods of inactivity
// Distributed with a free-will license.// Use it any way you want, profit or free, provided it fits in the licenses of its associated works.// MMA8452Q// This code is designed to work with the MMA8452Q_I2CS I2C Mini Module available from ControlEverything.com.// https://www.controleverything.com/content/Accelorometer?sku=MMA8452Q_I2CS#tabs-0-product_tabset-2#include <Wire.h>// MMA8452Q I2C address is 0x1C(28)#define Addr 0x1Cvoid setup(){// Initialise I2C communication as MASTER
Wire.begin();// Initialise Serial Communication, set baud rate = 9600
Serial.begin(9600);// Start I2C Transmission
Wire.beginTransmission(Addr);// Select control register
Wire.write(0x2A);// StandBy mode
Wire.write(0x00);// Stop I2C Transmission
Wire.endTransmission();// Start I2C Transmission
Wire.beginTransmission(Addr);// Select control register
Wire.write(0x2A);// Active mode
Wire.write(0x01);// Stop I2C Transmission
Wire.endTransmission();// Start I2C Transmission
Wire.beginTransmission(Addr);// Select control register
Wire.write(0x0E);// Set range to +/- 2g
Wire.write(0x00);// Stop I2C Transmission
Wire.endTransmission();
delay(300);}void loop(){unsignedint data[7];// Request 7 bytes of data
Wire.requestFrom(Addr, 7);// Read 7 bytes of data// staus, xAccl lsb, xAccl msb, yAccl lsb, yAccl msb, zAccl lsb, zAccl msbif(Wire.available()== 7){
data[0]= Wire.read();
data[1]= Wire.read();
data[2]= Wire.read();
data[3]= Wire.read();
data[4]= Wire.read();
data[5]= Wire.read();
data[6]= Wire.read();}// Convert the data to 12-bitsint xAccl =((data[1]* 256)+ data[2])/16;if(xAccl > 2047){
xAccl -=4096;}int yAccl =((data[3]* 256)+ data[4])/16;if(yAccl > 2047){
yAccl -=4096;}int zAccl =((data[5]* 256)+ data[6])/16;if(zAccl > 2047){
zAccl -=4096;}// Output data to serial monitor
Serial.print("Acceleration in X-Axis : ");
Serial.println(xAccl);
Serial.print("Acceleration in Y-Axis : ");
Serial.println(yAccl);
Serial.print("Acceleration in Z-Axis : ");
Serial.println(zAccl);
delay(500);}
Output
Open the serial monitor – this is what you should expect to see
Acceleration in X-Axis : -186
Acceleration in Y-Axis : 330
Acceleration in Z-Axis : 125
Acceleration in X-Axis : -784
Acceleration in Y-Axis : 426
Acceleration in Z-Axis : 76
Acceleration in X-Axis : -225
Acceleration in Y-Axis : 890
Acceleration in Z-Axis : -273
Acceleration in X-Axis : -199
Acceleration in Y-Axis : 1053
Acceleration in Z-Axis : -260
The ADS1115 device is a precision, low-power, 16-bit, I2C-compatible, analog-to-digital converters (ADCs) offered in an ultra-small, leadless, X2QFN-10 package, and a VSSOP-10 package. The device incorporates a low-drift voltage reference and an oscillator. The converter also incorporates a programmable gain amplifier and a digital comparator. These features, along with a wide operating supply range, make the converter well suited for power- and space-constrained, sensor measurement applications.
The ADS1115 perform conversions at data rates up to 860 samples per second (SPS). The PGA offers input ranges from ±256 mV to ±6.144 V, allowing precise large- and small-signal measurements. The converter features an input multiplexer that allows two differential or four single-ended input measurements. Use the digital comparator in the ADS1115 for under- and overvoltage detection.
The ADS1115 operates in either continuous-conversion mode or single-shot mode. The devices are automatically powered down after one conversion in single-shot mode; therefore, power consumption is significantly reduced during idle periods.
ADS1115 Features
Wide Supply Range: 2.0 V to 5.5 V
Low Current Consumption: 150 µA
(Continuous-Conversion Mode)
Programmable Data Rate: 8 SPS to 860 SPS
Single-Cycle Settling
Internal Low-Drift Voltage Reference
Internal Oscillator
I2C Interface: Four Pin-Selectable Addresses
Four Single-Ended or Two Differential Inputs
Programmable Comparator
Operating Temperature Range: –40°C to +125°C
Open the serial monitor and you should see something like this
AIN0: 17707
AIN1: -1
AIN2: 26295
AIN3: -1
AIN0: 17702
AIN1: -1
AIN2: 26291
AIN3: -1
AIN0: 17706
AIN1: -1
AIN2: 26289
AIN3: -1
AIN0: 17700
AIN1: -1
AIN2: 26349
AIN3: -1
Video
In this video we compile and program the Arduino and show you the output. We also show a layout and schematic in fritzing, we tied the A0 to A3 to various voltages, at the end we removed these so the input is ‘floating’
In this example we will connect a CCS811 gas sensor to an arduino, lets look at the sensor
CCS811 is a low-power digital gas sensor solution, which integrates a gas sensor solution for detecting low levels of VOCs typically found indoors, with a microcontroller unit (MCU) and an Analog-to-Digital converter to monitor the local environment and provide an indication of the indoor air quality via an equivalent CO2 or TVOC output over a standard I2C digital interface.
Features
Integrated MCU
On-board processing
Standard digital interface
Optimised low power modes
IAQ threshold alarms
Programmable baseline
2.7mm x 4.0mm LGA package
Low component count
Proven technology platform
In this video we import the library, we compile and program the Arduino and then we open the serial monitor. The higher reading is when I blew on the sensor
