| In this article we look at another absolute pressure sensor – this time its the LPS22HB The LPS22HB is an ultra-compact piezoresistive absolute pressure sensor which functions as a digital output barometer. The device comprises a sensing element and an IC interface which communicates through I2C or SPI from the sensing element to the application. The sensing element, which detects absolute pressure, consists of a suspended membrane manufactured using a dedicated process developed by ST.
The LPS22HB is available in a full-mold, holed LGA package (HLGA). It is guaranteed to operate over a temperature range extending from -40 °C to +85 °C. The package is holed to allow external pressure to reach the sensing element. Features- 260 to 1260 hPa absolute pressure range
- Current consumption down to 3 μA
- High overpressure capability: 20x full-scale
- Embedded temperature compensation
- 24-bit pressure data output
- 16-bit temperature data output
- ODR from 1 Hz to 75 Hz
- SPI and I²C interfaces
- Embedded FIFO
- Interrupt functions: Data Ready, FIFO flags, pressure thresholds
- Supply voltage: 1.7 to 3.6 V
- High shock survivability: 22,000 g
Parts Required Schematic/Connection  arduino and LPS22HB Code ExampleThis uses the library from hhttps://github.com/adrien3d/IO_LPS22HB /***************************************************************************
This is a library for the LPS22HB Absolute Digital Barometer
Designed to work with all kinds of LPS22HB Breakout Boards
These sensors use I2C, 2 pins are required to interface, as this :
VDD to 3.3V DC
SCL to A5
SDA to A4
GND to common groud
Written by Adrien Chapelet for IoThings
***************************************************************************/
#include <Wire.h>
#include "IO_LPS22HB.h"
IO_LPS22HB lps22hb;
void setup()
{
Serial.begin(9600);
Serial.println("IoThings LPS22HB Arduino Test");
lps22hb.begin(0x5D);
byte who_am_i = lps22hb.whoAmI();
Serial.print("Who Am I? 0x");
Serial.print(who_am_i, HEX);
Serial.println(" (expected: 0xB1)");
if (who_am_i != LPS22HB_WHO_AM_I_VALUE) {
Serial.println("Error while retrieving WHO_AM_I byte...");
while (true) {
// loop forever
}
}
}
void loop()
{
Serial.print("P=");
Serial.print(lps22hb.readPressure());
Serial.print(" mbar, T=");
Serial.print(lps22hb.readTemperature());
Serial.println("C");
delay(300);
} OutputOpen the serial monitor and you should see something like this IoThings LPS22HB Arduino Test
Who Am I? 0xB1 (expected: 0xB1)
P=982.52 mbar, T=18.21C
P=982.56 mbar, T=18.25C
P=982.51 mbar, T=18.26C
P=982.52 mbar, T=18.27C
P=982.54 mbar, T=18.27C
P=982.55 mbar, T=18.27C
P=982.51 mbar, T=18.26C
P=982.55 mbar, T=18.26C
P=982.55 mbar, T=18.26C Linkshttps://www.st.com/resource/en/datasheet/lps22hb.pdf In this article we look at a digital geomagnetic sensor – this time its the BMM150 BMM150 is a low power and low noise 3-axis digital geomagnetic sensor to be used in compass applications. The 12-pin wafer level chip scale package (WLCSP) with a footprint of 1.56 x 1.56 mm² and 0.60 mm height provides highest design flexibility to the developer of mobile devices. Applications like virtual reality or gaming on mobile devices such as mobile phones, tablet PCs or portable media players require 9-axis inertial sensing including magnetic heading information. Due to the stable performance over a large temperature range, the BMM150 is also especially suited for supporting drones in accurate heading. BMM150 can be used with an inertial measurement unit (IMU) consisting of a 3-axis accelerometer and a 3-axis gyroscope like Bosch Sensortec’s BMI055. Features| Parameter | Technical data |
|---|
| Package | CSWLP- (12 pin)
1.56×1.56×0.6 mm³
0.4 mm diagonal ball pitch | | Temperature range | -40°C … +85°C | | Digital interfaces | I²C and SPI
(2 interrupt pins) | | Resolution | 0.3μT | | Supply voltage | VDD: 1.62V to 3.6V
VDDIO: 1.2V to 3.6V | | Zero-B offset | ±50μT | | Non-linearity | <1% FS | | Magnetic range typ. | ±1300μT (x,y-axis)
±2500μT (z-axis) | | Average current consumption | 170 μA (low power preset)
500 μA (normal mode) | | Interrupts | New data, magnetic threshold high / low |
Parts Required Schematic/Connection  arduino and BMM150 Code ExampleThis uses the library from https://github.com/Seeed-Studio/Grove_3_Axis_Compass_V2.0_BMM150 #include <Arduino.h>
#include <Wire.h>
// libraries
#include "bmm150.h"
#include "bmm150_defs.h"
BMM150 bmm = BMM150();
void setup()
{
Serial.begin(9600);
if(bmm.initialize() == BMM150_E_ID_NOT_CONFORM) {
Serial.println("Chip ID can not read!");
while(1);
} else {
Serial.println("Initialize done!");
}
}
void loop()
{
bmm150_mag_data value;
bmm.read_mag_data();
value.x = bmm.raw_mag_data.raw_datax;
value.y = bmm.raw_mag_data.raw_datay;
value.z = bmm.raw_mag_data.raw_dataz;
float xyHeading = atan2(value.x, value.y);
float zxHeading = atan2(value.z, value.x);
float heading = xyHeading;
if(heading < 0)
heading += 2*PI;
if(heading > 2*PI)
heading -= 2*PI;
float headingDegrees = heading * 180/M_PI;
float xyHeadingDegrees = xyHeading * 180 / M_PI;
float zxHeadingDegrees = zxHeading * 180 / M_PI;
Serial.print("Heading: ");
Serial.println(headingDegrees);
delay(100);
} OutputOpen the serial monitor and you should see something like this – the results would have been more interesting if I moved the sensor but I was checking the stability Heading: 261.09
Heading: 262.21
Heading: 261.05
Heading: 260.50
Heading: 260.42
Heading: 260.13
Heading: 260.81
Heading: 259.46 Linkshttps://ae-bst.resource.bosch.com/media/_tech/media/datasheets/BST-BMM150-DS001.pdf https://github.com/BoschSensortec/BMM150-Sensor-API In this article we look at a pressure sensor – this time its the LPS25H The LPS25H is an ultra-compact absolute piezoresistive pressure sensor. It includes a monolithic sensing element and an IC interface able to take the information from the sensing element and to provide a digital signal to the external world. The sensing element consists of a suspended membrane realized inside a single mono-silicon substrate. It is capable of detecting pressure and is manufactured using a dedicated process developed by ST.
The membrane is very small compared to the traditionally built silicon micromachined membranes. Membrane breakage is prevented by an intrinsic mechanical stopper.
The IC interface is manufactured using a standard CMOS process that allows a high level of integration to design a dedicated circuit which is trimmed to better match the sensing element characteristics.
The LPS25H is available in a cavity holed LGA package (HLGA). It is guaranteed to operate over a temperature range extending from -30 °C to +105 °C. The package is holed to allow external pressure to reach the sensing element. Features260 to 1260 mbar absolute pressure range
High-resolution mode: 1 Pa RMS
Low power consumption
Low-resolution mode: 4 μA
High-resolution mode: 25 μA
High overpressure capability: 20x full scale
Embedded temperature compensation
Embedded 24-bit ADC
Selectable ODR from 1 Hz to 25 Hz
SPI and I²C interfaces
Supply voltage: 1.7 to 3.6 V
High shock survivability: 10,000 g Parts Required Schematic/Connection  arduino and LPS25H Code ExampleThis uses the library from https://github.com/pololu/lps-arduino #include <Wire.h>
#include <LPS.h>
LPS ps;
void setup()
{
Serial.begin(9600);
Wire.begin();
if (!ps.init())
{
Serial.println("Failed to autodetect pressure sensor!");
while (1);
}
ps.enableDefault();
}
void loop()
{
float pressure = ps.readPressureMillibars();
float altitude = ps.pressureToAltitudeMeters(pressure);
float temperature = ps.readTemperatureC();
Serial.print("p: ");
Serial.print(pressure);
Serial.print(" mbar\ta: ");
Serial.print(altitude);
Serial.print(" m\tt: ");
Serial.print(temperature);
Serial.println(" deg C");
delay(100);
} OutputOpen the serial monitor and you should see something like this p: 987.37 mbar a: 217.67 m t: 22.88 deg C
p: 987.19 mbar a: 219.24 m t: 23.07 deg C
p: 987.31 mbar a: 218.22 m t: 23.26 deg C
p: 986.94 mbar a: 221.34 m t: 23.45 deg C
p: 986.80 mbar a: 222.55 m t: 23.79 deg C
p: 986.75 mbar a: 222.95 m t: 23.95 deg C
p: 986.67 mbar a: 223.69 m t: 24.11 deg C
p: 986.59 mbar a: 224.32 m t: 24.40 deg C
p: 986.55 mbar a: 224.63 m t: 24.54 deg C
p: 986.43 mbar a: 225.68 m t: 24.68 deg C
p: 986.39 mbar a: 226.02 m t: 24.95 deg C
p: 986.51 mbar a: 225.01 m t: 25.07 deg C
p: 986.47 mbar a: 225.35 m t: 25.20 deg C Linkshttps://www.st.com/resource/en/datasheet/lps25h.pdf In this article we look at a BH1745NUC Luminance and Colour Sensor and connect it to an Arduino The BH1745NUC is digital color sensor IC with I²C bus interface. This IC senses Red, Green and Blue light (RGB) and converts them to digital values. The high sensitivity, wide dynamic range and excellent Ircut characteristics makes this IC the most suitable to obtain the illuminance and color temperature of ambient light for adjusting LCD backlight of TV, mobile phone and tablet PC. It is possible to detect very wide range light intensity. (0.005 – 40k lx) Specifications: VCC Voltage Range: 2.3V to 3.6V
Maximum Sensitivity: 0.005Lx/step
Current Consumption: 130μA (Typ)
Standby Mode Current: 0.8μA (Typ)
Operating Temperature Range: -40°C to +85°C Features The High Sensitivity and Wide Dynamic Range (0.005 – 40k lx)
Supports Low Transmittance (Dark) Window
Correspond to I²C Bus Interface
Low Current by Power Down Function
Rejecting 50Hz/60Hz Light Noise
Correspond to 1.8V Logic Interface
Programmable Interrupt Function
It is possible to select 2 type of I²C bus slave address (ADDR =’L’: “0111000”, ADDR =’H’: “0111001”) Here is a typical module that I used 
Parts RequiredI connected a sensor shield to an Arduino and then the sensor via connecting wire Schematic/ConnectionBe careful as I used a CJMCU-1745 – the sensor is rated at 2.3V to 3.6V. So use the 3.3v out | Arduino | Sensor | | 3.3v | VIN | | Gnd | Gnd | | SDA | SDA | | SCL | SCL |
Code Example This is a controleverything example – they have code examples for various platforms #include <Wire.h>
// I2C address of the BH1745NUC
#define Addr 0x38
void 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 mode control register1
Wire.write(0x41);
// Set RGBC measurement time 160 msec
Wire.write(0x00);
// Stop I2C Transmission
Wire.endTransmission();
// Start I2C Transmission
Wire.beginTransmission(Addr);
// Select mode control register2
Wire.write(0x42);
// Set measurement mode is active, gain = 1x
Wire.write(0x90);
// Stop I2C Transmission
Wire.endTransmission();
// Start I2C Transmission
Wire.beginTransmission(Addr);
// Select mode control register3
Wire.write(0x44);
// Set default value
Wire.write(0x02);
// Stop I2C Transmission
Wire.endTransmission();
delay(300);
}
void loop()
{
unsigned int data[8];
for(int i = 0; i < 8; i++)
{
// Start I2C Transmission
Wire.beginTransmission(Addr);
// Select data register
Wire.write((80+i));
// Stop I2C Transmission
Wire.endTransmission();
// Request 1 byte of data from the device
Wire.requestFrom(Addr, 1);
// Read 8 bytes of data
// Red lsb, Red msb, Green lsb, Green msb, Blue lsb, Blue msb
// cData lsb, cData msb
if(Wire.available() == 1)
{
data[i] = Wire.read();
}
delay(300);
}
// Convert the data
int red = ((data[1] & 0xFF) * 256) + (data[0] & 0xFF);
int green = ((data[3] & 0xFF) * 256) + (data[2] & 0xFF);
int blue = ((data[5] & 0xFF) * 256) + (data[4] & 0xFF);
int cData = ((data[7] & 0xFF) * 256) + (data[6] & 0xFF);
// Output data to serial monitor
Serial.print("Red Color luminance : ");
Serial.println(red);
Serial.print("Green Color luminance : ");
Serial.println(green);
Serial.print("Blue Color luminance : ");
Serial.println(blue);
Serial.print("Clear Data Color luminance : ");
Serial.println(cData);
} OutputOpen the serial monitor and you should see something like the following Red Color luminance : 46
Green Color luminance : 54
Blue Color luminance : 25
Clear Data Color luminance : 7
Red Color luminance : 44
Green Color luminance : 54
Blue Color luminance : 25
Clear Data Color luminance : 8
Red Color luminance : 45
Green Color luminance : 48
Blue Color luminance : 21
Clear Data Color luminance : 9 Place different colored objects beside the sensor and check the values | Subscribe to Arduinolearning via Email |
