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The MPU-9250 is the company’s second generation 9-axis MotionTracking device for smartphones, tablets, wearable sensors, and other consumer markets. The MPU-9250, delivered in a 3x3x1mm QFN package, is the world’s smallest 9-axis MotionTracking device and incorporates the latest InvenSense design innovations, enabling dramatically reduced chip size and power consumption, while at the same time improving performance and cost.
The MPU-9250 MotionTracking device sets a new benchmark for 9-axis performance with power consumption only 9.3µA and a size that is 44% smaller than the company’s first-generation device. Gyro noise performance is 3x better, and compass full scale range is over 4x better than competitive offerings.
The MPU-9250 is a System in Package (SiP) that combines two chips: the MPU-6500, which contains a 3-axis gyroscope, a 3-axis accelerometer, and an onboard Digital Motion Processor™ (DMP™) capable of processing complex MotionFusion algorithms; and the AK8963, the market leading 3-axis digital compass. The MPU-9250 supports InvenSense’s market proven MotionFusion. A single design can support the MPU-9250 or MPU-6500, providing customers the flexibility to support either device in different product SKUs.
Improvements include supporting the accelerometer low power mode with as little as 6.4µA of and it provides improved compass data resolution of 16-bits (0.15 µT per LSB). The full scale measurement range of ±4800µT helps alleviate compass placement challenges on complex pcb’s
Schematic
Code
I found the code below on the internet – link below
#include <Wire.h>
#include <TimerOne.h>
#define MPU9250_ADDRESS 0x68
#define MAG_ADDRESS 0x0C
#define GYRO_FULL_SCALE_250_DPS 0x00
#define GYRO_FULL_SCALE_500_DPS 0x08
#define GYRO_FULL_SCALE_1000_DPS 0x10
#define GYRO_FULL_SCALE_2000_DPS 0x18
#define ACC_FULL_SCALE_2_G 0x00
#define ACC_FULL_SCALE_4_G 0x08
#define ACC_FULL_SCALE_8_G 0x10
#define ACC_FULL_SCALE_16_G 0x18
// This function read Nbytes bytes from I2C device at address Address.
// Put read bytes starting at register Register in the Data array.
void I2Cread(uint8_t Address, uint8_t Register, uint8_t Nbytes, uint8_t* Data)
{
// Set register address
Wire.beginTransmission(Address);
Wire.write(Register);
Wire.endTransmission();
// Read Nbytes
Wire.requestFrom(Address, Nbytes);
uint8_t index=0;
while (Wire.available())
Data[index++]=Wire.read();
}
// Write a byte (Data) in device (Address) at register (Register)
void I2CwriteByte(uint8_t Address, uint8_t Register, uint8_t Data)
{
// Set register address
Wire.beginTransmission(Address);
Wire.write(Register);
Wire.write(Data);
Wire.endTransmission();
}
// Initial time
long int ti;
volatile bool intFlag=false;
// Initializations
void setup()
{
// Arduino initializations
Wire.begin();
Serial.begin(115200);
// Set accelerometers low pass filter at 5Hz
I2CwriteByte(MPU9250_ADDRESS,29,0x06);
// Set gyroscope low pass filter at 5Hz
I2CwriteByte(MPU9250_ADDRESS,26,0x06);
// Configure gyroscope range
I2CwriteByte(MPU9250_ADDRESS,27,GYRO_FULL_SCALE_1000_DPS);
// Configure accelerometers range
I2CwriteByte(MPU9250_ADDRESS,28,ACC_FULL_SCALE_4_G);
// Set by pass mode for the magnetometers
I2CwriteByte(MPU9250_ADDRESS,0x37,0x02);
// Request continuous magnetometer measurements in 16 bits
I2CwriteByte(MAG_ADDRESS,0x0A,0x16);
pinMode(13, OUTPUT);
Timer1.initialize(10000); // initialize timer1, and set a 1/2 second period
Timer1.attachInterrupt(callback); // attaches callback() as a timer overflow interrupt
// Store initial time
ti=millis();
}
// Counter
long int cpt=0;
void callback()
{
intFlag=true;
digitalWrite(13, digitalRead(13) ^ 1);
}
// Main loop, read and display data
void loop()
{
while (!intFlag);
intFlag=false;
// Display time
Serial.print (millis()-ti,DEC);
Serial.print ("\t");
// _______________
// ::: Counter :::
// Display data counter
// Serial.print (cpt++,DEC);
// Serial.print ("\t");
// ____________________________________
// ::: accelerometer and gyroscope :::
// Read accelerometer and gyroscope
uint8_t Buf[14];
I2Cread(MPU9250_ADDRESS,0x3B,14,Buf);
// Create 16 bits values from 8 bits data
// Accelerometer
int16_t ax=-(Buf[0]<<8 | Buf[1]);
int16_t ay=-(Buf[2]<<8 | Buf[3]);
int16_t az=Buf[4]<<8 | Buf[5];
// Gyroscope
int16_t gx=-(Buf[8]<<8 | Buf[9]);
int16_t gy=-(Buf[10]<<8 | Buf[11]);
int16_t gz=Buf[12]<<8 | Buf[13];
// Display values
// Accelerometer
Serial.print (ax,DEC);
Serial.print ("\t");
Serial.print (ay,DEC);
Serial.print ("\t");
Serial.print (az,DEC);
Serial.print ("\t");
// Gyroscope
Serial.print (gx,DEC);
Serial.print ("\t");
Serial.print (gy,DEC);
Serial.print ("\t");
Serial.print (gz,DEC);
Serial.print ("\t");
// _____________________
// ::: Magnetometer :::
// Read register Status 1 and wait for the DRDY: Data Ready
uint8_t ST1;
do
{
I2Cread(MAG_ADDRESS,0x02,1,&ST1);
}
while (!(ST1&0x01));
// Read magnetometer data
uint8_t Mag[7];
I2Cread(MAG_ADDRESS,0x03,7,Mag);
// Create 16 bits values from 8 bits data
// Magnetometer
int16_t mx=-(Mag[3]<<8 | Mag[2]);
int16_t my=-(Mag[1]<<8 | Mag[0]);
int16_t mz=-(Mag[5]<<8 | Mag[4]);
// Magnetometer
Serial.print (mx+200,DEC);
Serial.print ("\t");
Serial.print (my-70,DEC);
Serial.print ("\t");
Serial.print (mz-700,DEC);
Serial.print ("\t");
// End of line
Serial.println("");
// delay(100);
}
Links
Code above – http://www.lucidarme.me/?p=5057
Good examples – https://github.com/kriswiner/MPU9250
Datasheet – https://www.invensense.com/wp-content/uploads/2015/02/PS-MPU-9250A-01-v1.1.pdf
MPU-9250 9-axis sensor module I2C/SPI Communications Thriaxis gyroscope + triaxial accelerometer+triaxial magnetic field
The MMA7361L is a low power, low profile capacitive micromachined accelerometer featuring signal conditioning, a 1-pole low pass filter, temperature compensation, self test, 0g-Detect which detects linear freefall, and g-Select which allows for the selection between 2 sensitivities. Zero-g offset and sensitivity are factory set and require no external devices. The MMA7361L includes a Sleep Mode that makes it ideal for handheld battery powered electronics.
Features
• 3mm x 5mm x 1.0mm LGA-14 Package
• Low Current Consumption: 400 μA
• Sleep Mode: 3 μA
• Low Voltage Operation: 2.2 V – 3.6 V
• High Sensitivity (800 mV/g @ 1.5g)
• Selectable Sensitivity (±1.5g, ±6g)
• Fast Turn On Time (0.5 ms Enable Response Time)
• Self Test for Freefall Detect Diagnosis
• 0g-Detect for Freefall Protection
• Signal Conditioning with Low Pass Filter
• Robust Design, High Shocks Survivability
• RoHS Compliant
• Environmentally Preferred Product
• Low Cost
Typical Applications
• 3D Gaming: Tilt and Motion Sensing, Event Recorder
• HDD MP3 Player: Freefall Detection
• Laptop PC: Freefall Detection, Anti-Theft
• Cell Phone: Image Stability, Text Scroll, Motion Dialing, E-Compass
• Pedometer: Motion Sensing
• PDA: Text Scroll
• Navigation and Dead Reckoning: E-Compass Tilt Compensation
• Robotics: Motion Sensing
Schematic and connection
Code
int x;
int y;
int z;
void setup()
{
Serial.begin(9600);
}
void loop()
{
x = analogRead(5); // read A5 input pin
y = analogRead(4); // read A4 input pin
z = analogRead(3); // read A3 input pin
Serial.print("X = "); // print x value
Serial.println(x);
Serial.print("Y = "); // print y value
Serial.println(y);
Serial.print("Z = "); // print z value
Serial.println(z);
delay(1000);
}
Output
Open the serial monitor and move the sensor around, you should see soemthing like this
X = 445
Y = 86
Z = 451
X = 444
Y = 88
Z = 447
X = 345
Y = 65
Z = 62
X = 343
Y = 64
Z = 67
X = 341
Y = 66
Z = 71
X = 55
Y = 0
Z = 0
X = 57
Y = 0
Z = 0
Links
http://www.nxp.com/files/sensors/doc/data_sheet/MMA7361L.pdf
MMA7361 Angle Sensor Inclination Accelerometer Acceleration Module For Arduino
The ADXL335 is a small, thin, low power, complete 3-axis accelerometer with signal conditioned voltage outputs. The product measures acceleration with a minimum full-scale range of ±3 g. It can measure the static acceleration of gravity in tiltsensing applications, as well as dynamic acceleration resulting from motion, shock, or vibration.
The user selects the bandwidth of the accelerometer using the CX, CY, and CZ capacitors at the XOUT, YOUT, and ZOUT pins. Bandwidths can be selected to suit the application, with a range of 0.5 Hz to 1600 Hz for X and Y axes, and a range of 0.5 Hz to 550 Hz for the Z axis.
Here is a typical module that makes it easy to work with the ADXL335
Features:
Name: ADXL335 module (triaxial accelerometer analog output)
Model: GY-61
Power supply :3-5v
Analog X, Y, Z three-axis output
Schematic
The following layout shows how to wire the ADXL335 module up to an Arduino UNO
Code
const int xpin = A0; // x-axis of the accelerometer
const int ypin = A1; // y-axis
const int zpin = A2; // z-axis
void setup()
{
Serial.begin(9600);
}
void loop()
{
int x = analogRead(xpin); //read from xpin
delay(1); //
int y = analogRead(ypin); //read from ypin
delay(1);
int z = analogRead(zpin); //read from zpin
float zero_G = 512.0; //ADC is 0~1023 the zero g output equal to Vs/2
float scale = 102.3; //ADXL335330 Sensitivity is 330mv/g
//330 * 1024/3.3/1000
Serial.print(((float)x - 331.5)/65*9.8); //print x value on serial monitor
Serial.print("\t");
Serial.print(((float)y - 329.5)/68.5*9.8); //print y value on serial monitor
Serial.print("\t");
Serial.print(((float)z - 340)/68*9.8); //print z value on serial monitor
Serial.print("\n");
delay(1000); //wait for 1 second
}Open the serial monitor and you should see something like this
-3.54 3.51 9.22
-3.39 -5.79 3.31
-4.75 -9.08 6.77
25.40 29.83 -3.31
-1.43 6.22 8.21
-1.58 5.79 8.50
-1.73 5.79 8.50
-1.73 5.65 8.65
Links
http://www.analog.com/media/en/technical-documentation/data-sheets/ADXL335.pdf
The sensor costs under $2
GY-61 ADXL335 Module Triaxial Acceleration Gravity Angle Sensor
The MAX44009 ambient light sensor features an I²C digital output that is ideal for a number of portable applications such as smartphones, notebooks, and industrial sensors. At less than 1µA operating current, it is the lowest power ambient light sensor in the industry and features an ultra-wide 22-bit dynamic range from 0.045 lux to 188,000 lux.
Low-light operation allows easy operation in dark-glass applications.
The on-chip photodiode’s spectral response is optimized to mimic the human eye’s perception of ambient light and incorporates IR and UV blocking capability. The adaptive gain block automatically selects the correct lux range to optimize the counts/lux.
Here is a low cost module available that makes the sensor easier to work with
Features
Wide 0.045 Lux to 188,000 Lux Range
VCC = 1.7V to 3.6V
ICC = 0.65µA Operating Current
-40°C to +85°C Temperature Range
Device Address Options – 1001 010x and 1001 011x
Connection
| Module Pin |
Arduino Pin |
| Vin |
5v |
| Gnd |
Gnd |
| SCL |
|
| SDA |
|
Code
#include<Wire.h>
#define Addr 0x4A
void setup()
{
Wire.begin();
// Initialise serial communication
Serial.begin(9600);
Wire.beginTransmission(Addr);
Wire.write(0x02);
Wire.write(0x40);
Wire.endTransmission();
delay(300);
}
void loop()
{
unsigned int data[2];
Wire.beginTransmission(Addr);
Wire.write(0x03);
Wire.endTransmission();
// Request 2 bytes of data
Wire.requestFrom(Addr, 2);
// Read 2 bytes of data luminance msb, luminance lsb
if (Wire.available() == 2)
{
data[0] = Wire.read();
data[1] = Wire.read();
}
// Convert the data to lux
int exponent = (data[0] & 0xF0) >> 4;
int mantissa = ((data[0] & 0x0F) << 4) | (data[1] & 0x0F);
float luminance = pow(2, exponent) * mantissa * 0.045;
Serial.print("Ambient Light luminance :");
Serial.print(luminance);
Serial.println(" lux");
delay(500);
}
Output
Open the serial monitor and change the light intensity on the sensor, here is an example
Ambient Light luminance :4.59 lux
Ambient Light luminance :6.12 lux
Ambient Light luminance :6.12 lux
Ambient Light luminance :36.72 lux
Ambient Light luminance :36.72 lux
Ambient Light luminance :36.72 lux
Ambient Light luminance :73.44 lux
Ambient Light luminance :73.44 lux
Ambient Light luminance :73.44 lux
Ambient Light luminance :9.95 lux
Ambient Light luminance :9.95 lux
Ambient Light luminance :12.24 lux
Link
https://datasheets.maximintegrated.com/en/ds/MAX44009.pdf
MAX44009 Ambient Light Sensor Module with 4P Pin Header
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