Avnet / Mbed 2 deprecated Avnet_ATT_Cellular_IOT

This program connects to a few sensors via I2C and sends the data collected to a WNC Cellular Module which is located on an Avnet WNC-Shield card.

Dependencies:   FXOS8700CQ MODSERIAL mbed

/media/uploads/kevinkeryk/avnet_logo_tagline_rgb.png

Avnet Cellular IoT Instructions

  • One problematic area is setting the MY_SERVER_URL. When you copy the URL from the flow, you must make sure the MY_SERVER_URL is also set to the appropriate server. It can be either "run-east.att.io" or "run-west.att.io".

Useful Links

Adding Additional Sensors

The FLOW_DEVICE_NAME field must contain the name of the instance of the Virtual Starter Kit in FLOW you will be communicating with. Usually this is "vstarterkit001", but if you have problems communicating you can verify this is correct. Note: This device will not be created until you click the “Initialize” input on the Virtual Device tab of the Starter Kit project in FLOW. At that point, it becomes available in M2X and you can see it as the DEVICE SERIAL field under Devices as in the image below. /media/uploads/JMF/vstarterkit.png

Sensors: When executing, the FRDM-K64F board uploads sensor measurements to AT&T’s Flow environment every 5 seconds, using the Cellular shield board. You can adjust how often you want to do this by editing the SENSOR_UPDATE_INTERVAL_MS value in the header file.

Temperature and humidity: By default, the board reports readings from the HTS221 temperature and humidity sensor. These two values are sent to the HTTP IN /climate port in FLOW with field names “temp” and “humidity”. Temperature is in degrees Fahrenheit and humidity is a %. This default assignment is: iSensorsToReport = TEMP_HUMIDITY_ONLY;

Accelerometer: If you want to expand and use the onboard motion sensor, you can also send 3-axis accelerometer information from the board as “accelX”, “accelY”, and “accelZ”. This is useful if you want to know the stationary position of the board with regards to gravity, or whether it is in motion. These readings are in g’s. To send these values, change the assignment to: iSensorsToReport = TEMP_HUMIDITY_ACCELEROMETER;

PMOD Sensors: If you have a Silicon Labs sensor module that can plug into the PMOD connector on the Cellular shield, you are able to measure proximity, UV light, ambient visible and infrared light from the Si1145 sensor. This PMOD also has a temperature and humidity sensor, but in this case it is redundant. When enabled, the fields “proximity”, “light_uv”, “light_vis” and “light_ir” are also sent. To enable all these sensors, change the assignment to: iSensorsToReport = TEMP_HUMIDITY_ACCELEROMETER_PMODSENSORS;

Connecting the PMOD sensors: Because the pinouts do not align, the SiLabs PMOD sensor board cannot be plugged into the J10 PMOD receptacle on the shield directly. The following wiring instructions must be followed:

SignalJ10ShieldPMOD Color in the image below
VCCPin 6Pin 6Red
GNDPin 5Pin 5Black
SDAPin4Pin 3Green
SCLPin3Pin 2Yellow

/media/uploads/JMF/xyz.jpg

AT&T M2X and FLOW Instructions

M2X & FLOW Instructions

Link to AT&T M2X

M2X

Link to AT&T Flow

FLOW

Avnet WNC-Shield Information

Getting Started with the Avnet WNC-Shield Software

  • This project uses Revision 119 of the MBED library because of I2C implementation differences with the tip (Revision 121).
  • This project uses Revision 4 of the FXOS8700CQ library for sensors.

Easily Modifiable Parameters

Inside the mbed Avnet_ATT_Cellular_IOT project, the parameters needed to customize your board are in the config_me.h file.

  • FLOW parameters: This project assumes you are using a fork of the Starter Kit Base project, which is a reference design created using AT&T’s FLOW (https://flow.att.com) that allows the creation of online virtualization and other IoT functionality. The default parameters in the config_me.h file are done for a specific instance of this project. When you fork the original project, you get your own instance and it will have its own base address. At the bottom of the FLOW environment, when you click on the Endpoints tab, URL information that is specific to your instance is displayed. Of note is the Base URL. In the example below (as in the default mbed project), the Base URL is: https://run-west.att.io/1e464b19cdcde/774c88d68202/86694923d5bf28a/in/flow You have to take note of two parts of this address. The run-west.att.io part is the server URL, and you have to make sure the
  • MY_SERVER_URL field in config_me.h matches this. The rest of the base URL, in green above, needs to be pasted into the FLOW_BASE_URL field.

There is also a FLOW_INPUT_NAME field. This should match the name of the HTTP IN port in the FLOW project that you want to send sensor data to. The default is "/climate", as in the FLOW image below.

/media/uploads/JMF/sf.png

Where is the Binary I compiled

When the COMPILE button is pressed, it compiles your project and links it. The result is placed in the DOWNLOAD folder you use when downloading files from the Internet. It will be called AvnetATT_shape_hackathon_K64F.bin.

Additional Information on Compiling/Configuring

Comprehensive instructions can be found at: Quick Start Instructions

sensors.cpp@11:e6602513730f, 2016-07-12 (annotated)

Committer:
stefanrousseau
Date:
Tue Jul 12 03:11:05 2016 +0000
Revision:
11:e6602513730f
Parent:
4:f83bedd9cab4
Child:
55:3abf9e3f42e6
Fixed I2C issues.  ; a) Removed stop between HTS221 address and read; b) The latest MBED uses the slave address differently from the legacy.  Stick with the old for now and fixed the HTS221 address to BF instead of 5F.; c) Made I2C definitions externs.

Who changed what in which revision?

UserRevisionLine numberNew contents of line
stefanrousseau 4:f83bedd9cab4 1 #include "mbed.h"
stefanrousseau 4:f83bedd9cab4 2 #include "sensors.h"
stefanrousseau 4:f83bedd9cab4 3
stefanrousseau 4:f83bedd9cab4 4 //I2C for pmod sensors:
stefanrousseau 4:f83bedd9cab4 5 #define Si1145_PMOD_I2C_ADDR 0xC0 //this is for 7-bit addr 0x60 for the Si7020
stefanrousseau 4:f83bedd9cab4 6 #define Si7020_PMOD_I2C_ADDR 0x80 //this is for 7-bit addr 0x4 for the Si7020
stefanrousseau 4:f83bedd9cab4 7
stefanrousseau 11:e6602513730f 8 #include "hardware.h"
stefanrousseau 11:e6602513730f 9 //I2C i2c(PTC11, PTC10); //SDA, SCL
stefanrousseau 4:f83bedd9cab4 10
stefanrousseau 4:f83bedd9cab4 11 #include "FXOS8700CQ.h"
stefanrousseau 4:f83bedd9cab4 12 // Pin names for the motion sensor FRDM-K64F board:
stefanrousseau 4:f83bedd9cab4 13 FXOS8700CQ fxos(PTE25, PTE24, FXOS8700CQ_SLAVE_ADDR1); // SDA, SCL, (addr << 1)
stefanrousseau 4:f83bedd9cab4 14 // Storage for the data from the sensor
stefanrousseau 4:f83bedd9cab4 15 SRAWDATA accel_data;
stefanrousseau 4:f83bedd9cab4 16 SRAWDATA magn_data;
stefanrousseau 4:f83bedd9cab4 17 //InterruptIn fxos_int1(PTC6); // unused, common with SW2 on FRDM-K64F
stefanrousseau 4:f83bedd9cab4 18 InterruptIn fxos_int2(PTC13); // should just be the Data-Ready interrupt
stefanrousseau 4:f83bedd9cab4 19 bool fxos_int2_triggered = false;
stefanrousseau 4:f83bedd9cab4 20 void trigger_fxos_int2(void)
stefanrousseau 4:f83bedd9cab4 21 {
stefanrousseau 4:f83bedd9cab4 22 fxos_int2_triggered = true;
stefanrousseau 4:f83bedd9cab4 23 //us_ellapsed = t.read_us();
stefanrousseau 4:f83bedd9cab4 24 }
stefanrousseau 4:f83bedd9cab4 25
stefanrousseau 4:f83bedd9cab4 26 /*------------------------------------------------------------------------------
stefanrousseau 4:f83bedd9cab4 27 * Perform I2C single read.
stefanrousseau 4:f83bedd9cab4 28 *------------------------------------------------------------------------------*/
stefanrousseau 4:f83bedd9cab4 29 unsigned char I2C_ReadSingleByte(unsigned char ucDeviceAddress)
stefanrousseau 4:f83bedd9cab4 30 {
stefanrousseau 4:f83bedd9cab4 31 char rxbuffer [1];
stefanrousseau 11:e6602513730f 32 i2c.read(ucDeviceAddress, rxbuffer, 1 );
stefanrousseau 4:f83bedd9cab4 33 return (unsigned char)rxbuffer[0];
stefanrousseau 4:f83bedd9cab4 34 } //I2C_ReadSingleByte()
stefanrousseau 4:f83bedd9cab4 35
stefanrousseau 4:f83bedd9cab4 36 /*------------------------------------------------------------------------------
stefanrousseau 4:f83bedd9cab4 37 * Perform I2C single read from address.
stefanrousseau 4:f83bedd9cab4 38 *------------------------------------------------------------------------------*/
stefanrousseau 4:f83bedd9cab4 39 unsigned char I2C_ReadSingleByteFromAddr(unsigned char ucDeviceAddress, unsigned char Addr)
stefanrousseau 4:f83bedd9cab4 40 {
stefanrousseau 4:f83bedd9cab4 41 char txbuffer [1];
stefanrousseau 4:f83bedd9cab4 42 char rxbuffer [1];
stefanrousseau 4:f83bedd9cab4 43 txbuffer[0] = (char)Addr;
stefanrousseau 11:e6602513730f 44 i2c.write(ucDeviceAddress, txbuffer, 1 );
stefanrousseau 11:e6602513730f 45 i2c.read(ucDeviceAddress, rxbuffer, 1 );
stefanrousseau 4:f83bedd9cab4 46 return (unsigned char)rxbuffer[0];
stefanrousseau 4:f83bedd9cab4 47 } //I2C_ReadSingleByteFromAddr()
stefanrousseau 4:f83bedd9cab4 48
stefanrousseau 4:f83bedd9cab4 49 /*------------------------------------------------------------------------------
stefanrousseau 4:f83bedd9cab4 50 * Perform I2C read of more than 1 byte.
stefanrousseau 4:f83bedd9cab4 51 *------------------------------------------------------------------------------*/
stefanrousseau 4:f83bedd9cab4 52 int I2C_ReadMultipleBytes(unsigned char ucDeviceAddress, char *ucData, unsigned char ucLength)
stefanrousseau 4:f83bedd9cab4 53 {
stefanrousseau 4:f83bedd9cab4 54 int status;
stefanrousseau 11:e6602513730f 55 status = i2c.read(ucDeviceAddress, ucData, ucLength);
stefanrousseau 4:f83bedd9cab4 56 return status;
stefanrousseau 4:f83bedd9cab4 57 } //I2C_ReadMultipleBytes()
stefanrousseau 4:f83bedd9cab4 58
stefanrousseau 4:f83bedd9cab4 59 /*------------------------------------------------------------------------------
stefanrousseau 4:f83bedd9cab4 60 * Perform I2C write of a single byte.
stefanrousseau 4:f83bedd9cab4 61 *------------------------------------------------------------------------------*/
stefanrousseau 4:f83bedd9cab4 62 int I2C_WriteSingleByte(unsigned char ucDeviceAddress, unsigned char Data, bool bSendStop)
stefanrousseau 4:f83bedd9cab4 63 {
stefanrousseau 4:f83bedd9cab4 64 int status;
stefanrousseau 4:f83bedd9cab4 65 char txbuffer [1];
stefanrousseau 4:f83bedd9cab4 66 txbuffer[0] = (char)Data; //data
stefanrousseau 11:e6602513730f 67 status = i2c.write(ucDeviceAddress, txbuffer, 1, !bSendStop); //true: do not send stop
stefanrousseau 4:f83bedd9cab4 68 return status;
stefanrousseau 4:f83bedd9cab4 69 } //I2C_WriteSingleByte()
stefanrousseau 4:f83bedd9cab4 70
stefanrousseau 4:f83bedd9cab4 71 /*------------------------------------------------------------------------------
stefanrousseau 4:f83bedd9cab4 72 * Perform I2C write of 1 byte to an address.
stefanrousseau 4:f83bedd9cab4 73 *------------------------------------------------------------------------------*/
stefanrousseau 4:f83bedd9cab4 74 int I2C_WriteSingleByteToAddr(unsigned char ucDeviceAddress, unsigned char Addr, unsigned char Data, bool bSendStop)
stefanrousseau 4:f83bedd9cab4 75 {
stefanrousseau 4:f83bedd9cab4 76 int status;
stefanrousseau 4:f83bedd9cab4 77 char txbuffer [2];
stefanrousseau 4:f83bedd9cab4 78 txbuffer[0] = (char)Addr; //address
stefanrousseau 4:f83bedd9cab4 79 txbuffer[1] = (char)Data; //data
stefanrousseau 11:e6602513730f 80 //status = i2c.write(ucDeviceAddress, txbuffer, 2, false); //stop at end
stefanrousseau 11:e6602513730f 81 status = i2c.write(ucDeviceAddress, txbuffer, 2, !bSendStop); //true: do not send stop
stefanrousseau 4:f83bedd9cab4 82 return status;
stefanrousseau 4:f83bedd9cab4 83 } //I2C_WriteSingleByteToAddr()
stefanrousseau 4:f83bedd9cab4 84
stefanrousseau 4:f83bedd9cab4 85 /*------------------------------------------------------------------------------
stefanrousseau 4:f83bedd9cab4 86 * Perform I2C write of more than 1 byte.
stefanrousseau 4:f83bedd9cab4 87 *------------------------------------------------------------------------------*/
stefanrousseau 4:f83bedd9cab4 88 int I2C_WriteMultipleBytes(unsigned char ucDeviceAddress, char *ucData, unsigned char ucLength, bool bSendStop)
stefanrousseau 4:f83bedd9cab4 89 {
stefanrousseau 4:f83bedd9cab4 90 int status;
stefanrousseau 11:e6602513730f 91 status = i2c.write(ucDeviceAddress, ucData, ucLength, !bSendStop); //true: do not send stop
stefanrousseau 4:f83bedd9cab4 92 return status;
stefanrousseau 4:f83bedd9cab4 93 } //I2C_WriteMultipleBytes()
stefanrousseau 4:f83bedd9cab4 94
stefanrousseau 4:f83bedd9cab4 95 bool bSi7020_present = false;
stefanrousseau 4:f83bedd9cab4 96 void Init_Si7020(void)
stefanrousseau 4:f83bedd9cab4 97 {
stefanrousseau 4:f83bedd9cab4 98 char SN_7020 [8];
stefanrousseau 4:f83bedd9cab4 99 //SN part 1:
stefanrousseau 4:f83bedd9cab4 100 I2C_WriteSingleByteToAddr(Si7020_PMOD_I2C_ADDR, 0xFA, 0x0F, false);
stefanrousseau 4:f83bedd9cab4 101 I2C_ReadMultipleBytes(Si7020_PMOD_I2C_ADDR, &SN_7020[0], 4);
stefanrousseau 4:f83bedd9cab4 102
stefanrousseau 4:f83bedd9cab4 103 //SN part 1:
stefanrousseau 4:f83bedd9cab4 104 I2C_WriteSingleByteToAddr(Si7020_PMOD_I2C_ADDR, 0xFC, 0xC9, false);
stefanrousseau 4:f83bedd9cab4 105 I2C_ReadMultipleBytes(Si7020_PMOD_I2C_ADDR, &SN_7020[4], 4);
stefanrousseau 4:f83bedd9cab4 106
stefanrousseau 4:f83bedd9cab4 107 char Ver_7020 [2];
stefanrousseau 4:f83bedd9cab4 108 //FW version:
stefanrousseau 4:f83bedd9cab4 109 I2C_WriteSingleByteToAddr(Si7020_PMOD_I2C_ADDR, 0x84, 0xB8, false);
stefanrousseau 4:f83bedd9cab4 110 I2C_ReadMultipleBytes(Si7020_PMOD_I2C_ADDR, &Ver_7020[0], 2);
stefanrousseau 4:f83bedd9cab4 111
stefanrousseau 4:f83bedd9cab4 112 if (SN_7020[4] != 0x14)
stefanrousseau 4:f83bedd9cab4 113 {
stefanrousseau 4:f83bedd9cab4 114 bSi7020_present = false;
stefanrousseau 4:f83bedd9cab4 115 printf("Si7020 sensor not found\n");
stefanrousseau 4:f83bedd9cab4 116 }
stefanrousseau 4:f83bedd9cab4 117 else
stefanrousseau 4:f83bedd9cab4 118 {
stefanrousseau 4:f83bedd9cab4 119 bSi7020_present = true;
stefanrousseau 4:f83bedd9cab4 120 printf("Si7020 SN = 0x%02X%02X%02X%02X%02X%02X%02X%02X\n", SN_7020[0], SN_7020[1], SN_7020[2], SN_7020[3], SN_7020[4], SN_7020[5], SN_7020[6], SN_7020[7]);
stefanrousseau 4:f83bedd9cab4 121 printf("Si7020 Version# = 0x%02X\n", Ver_7020[0]);
stefanrousseau 4:f83bedd9cab4 122 } //bool bSi7020_present = true
stefanrousseau 4:f83bedd9cab4 123
stefanrousseau 4:f83bedd9cab4 124 } //Init_Si7020()
stefanrousseau 4:f83bedd9cab4 125
stefanrousseau 4:f83bedd9cab4 126 void Read_Si7020(void)
stefanrousseau 4:f83bedd9cab4 127 {
stefanrousseau 4:f83bedd9cab4 128 if (bSi7020_present)
stefanrousseau 4:f83bedd9cab4 129 {
stefanrousseau 4:f83bedd9cab4 130 char Humidity [2];
stefanrousseau 4:f83bedd9cab4 131 char Temperature [2];
stefanrousseau 4:f83bedd9cab4 132 //Command to measure humidity (temperature also gets measured):
stefanrousseau 4:f83bedd9cab4 133 I2C_WriteSingleByte(Si7020_PMOD_I2C_ADDR, 0xF5, false); //no hold, must do dummy read
stefanrousseau 4:f83bedd9cab4 134 I2C_ReadMultipleBytes(Si7020_PMOD_I2C_ADDR, &Humidity[0], 1); //dummy read, should get an nack until it is done
stefanrousseau 4:f83bedd9cab4 135 wait (0.05); //wait for measurement. Can also keep reading until no NACK is received
stefanrousseau 4:f83bedd9cab4 136 //I2C_WriteSingleByte(Si7020_PMOD_I2C_ADDR, 0xE5, false); //Hold mod, the device does a clock stretch on the read until it is done (crashes the I2C bus...
stefanrousseau 4:f83bedd9cab4 137 I2C_ReadMultipleBytes(Si7020_PMOD_I2C_ADDR, &Humidity[0], 2); //read humidity
stefanrousseau 4:f83bedd9cab4 138 //printf("Read Si7020 Humidity = 0x%02X%02X\n", Humidity[0], Humidity[1]);
stefanrousseau 4:f83bedd9cab4 139 int rh_code = (Humidity[0] << 8) + Humidity[1];
stefanrousseau 4:f83bedd9cab4 140 float fRh = (125.0*rh_code/65536.0) - 6.0; //from datasheet
stefanrousseau 4:f83bedd9cab4 141 //printf("Si7020 Humidity = %*.*f %%\n", 4, 2, fRh); //double % sign for escape //printf("%*.*f\n", myFieldWidth, myPrecision, myFloatValue);
stefanrousseau 4:f83bedd9cab4 142 sprintf(SENSOR_DATA.Humidity_Si7020, "%0.2f", fRh);
stefanrousseau 4:f83bedd9cab4 143
stefanrousseau 4:f83bedd9cab4 144 //Command to read temperature when humidity is already done:
stefanrousseau 4:f83bedd9cab4 145 I2C_WriteSingleByte(Si7020_PMOD_I2C_ADDR, 0xE0, false);
stefanrousseau 4:f83bedd9cab4 146 I2C_ReadMultipleBytes(Si7020_PMOD_I2C_ADDR, &Temperature[0], 2); //read temperature
stefanrousseau 4:f83bedd9cab4 147 //printf("Read Si7020 Temperature = 0x%02X%02X\n", Temperature[0], Temperature[1]);
stefanrousseau 4:f83bedd9cab4 148 int temp_code = (Temperature[0] << 8) + Temperature[1];
stefanrousseau 4:f83bedd9cab4 149 float fTemp = (175.72*temp_code/65536.0) - 46.85; //from datasheet in Celcius
stefanrousseau 4:f83bedd9cab4 150 //printf("Si7020 Temperature = %*.*f deg C\n", 4, 2, fTemp);
stefanrousseau 4:f83bedd9cab4 151 sprintf(SENSOR_DATA.Temperature_Si7020, "%0.2f", fTemp);
stefanrousseau 4:f83bedd9cab4 152 } //bool bSi7020_present = true
stefanrousseau 4:f83bedd9cab4 153
stefanrousseau 4:f83bedd9cab4 154 } //Read_Si7020()
stefanrousseau 4:f83bedd9cab4 155
stefanrousseau 4:f83bedd9cab4 156 /*------------------------------------------------------------------------------
stefanrousseau 4:f83bedd9cab4 157 * The following are aliases so that the Si1145 coding examples can be used as-is.
stefanrousseau 4:f83bedd9cab4 158 *------------------------------------------------------------------------------*/
stefanrousseau 4:f83bedd9cab4 159 unsigned char ReadFrom_Si1145_Register(unsigned char reg) //returns byte from I2C Register 'reg'
stefanrousseau 4:f83bedd9cab4 160 {
stefanrousseau 4:f83bedd9cab4 161 unsigned char result = I2C_ReadSingleByteFromAddr(Si1145_PMOD_I2C_ADDR, reg);
stefanrousseau 4:f83bedd9cab4 162 return (result);
stefanrousseau 4:f83bedd9cab4 163 } //ReadFrom_Si1145_Register()
stefanrousseau 4:f83bedd9cab4 164
stefanrousseau 4:f83bedd9cab4 165 void WriteTo_Si1145_Register(unsigned char reg, unsigned char value) //writes 'value' into I2C Register reg'
stefanrousseau 4:f83bedd9cab4 166 {
stefanrousseau 4:f83bedd9cab4 167 I2C_WriteSingleByteToAddr(Si1145_PMOD_I2C_ADDR, reg, value, true);
stefanrousseau 4:f83bedd9cab4 168 } //WriteTo_Si1145_Register()
stefanrousseau 4:f83bedd9cab4 169
stefanrousseau 4:f83bedd9cab4 170 #define REG_PARAM_WR 0x17
stefanrousseau 4:f83bedd9cab4 171 #define REG_PARAM_RD 0x2E
stefanrousseau 4:f83bedd9cab4 172 #define REG_COMMAND 0x18
stefanrousseau 4:f83bedd9cab4 173 #define REG_RESPONSE 0x20
stefanrousseau 4:f83bedd9cab4 174 #define REG_HW_KEY 0x07
stefanrousseau 4:f83bedd9cab4 175 #define HW_KEY_VAL0 0x17
stefanrousseau 4:f83bedd9cab4 176 #define REG_MEAS_RATE_LSB 0x08
stefanrousseau 4:f83bedd9cab4 177 #define REG_MEAS_RATE_MSB 0x09
stefanrousseau 4:f83bedd9cab4 178 #define REG_PS_LED21 0x0F
stefanrousseau 4:f83bedd9cab4 179 #define REG_PS_LED3 0x10
stefanrousseau 4:f83bedd9cab4 180 #define MAX_LED_CURRENT 0xF
stefanrousseau 4:f83bedd9cab4 181 #define PARAM_CH_LIST 0x01
stefanrousseau 4:f83bedd9cab4 182 #define REG_ALS_VIS_DATA0 0x22
stefanrousseau 4:f83bedd9cab4 183 #define REG_ALS_VIS_DATA1 0x23
stefanrousseau 4:f83bedd9cab4 184 #define REG_ALS_IR_DATA0 0x24
stefanrousseau 4:f83bedd9cab4 185 #define REG_ALS_IR_DATA1 0x25
stefanrousseau 4:f83bedd9cab4 186 #define REG_PS1_DATA0 0x26
stefanrousseau 4:f83bedd9cab4 187 #define REG_PS1_DATA1 0x27
stefanrousseau 4:f83bedd9cab4 188 #define REG_PS2_DATA0 0x28
stefanrousseau 4:f83bedd9cab4 189 #define REG_PS2_DATA1 0x29
stefanrousseau 4:f83bedd9cab4 190 #define REG_PS3_DATA0 0x2A
stefanrousseau 4:f83bedd9cab4 191 #define REG_PS3_DATA1 0x2B
stefanrousseau 4:f83bedd9cab4 192 #define REG_UVINDEX0 0x2C
stefanrousseau 4:f83bedd9cab4 193 #define REG_UVINDEX1 0x2D
stefanrousseau 4:f83bedd9cab4 194 int Si1145_ParamSet(unsigned char address, unsigned char value) //writes 'value' into Parameter 'address'
stefanrousseau 4:f83bedd9cab4 195 {
stefanrousseau 4:f83bedd9cab4 196 char txbuffer [3];
stefanrousseau 4:f83bedd9cab4 197 txbuffer[0] = (char)REG_PARAM_WR; //destination
stefanrousseau 4:f83bedd9cab4 198 txbuffer[1] = (char)value;
stefanrousseau 4:f83bedd9cab4 199 txbuffer[2] = (char)(0xA0 + (address & 0x1F));
stefanrousseau 4:f83bedd9cab4 200 int retval;
stefanrousseau 4:f83bedd9cab4 201 //if((retval = _waitUntilSleep(si114x_handle))!=0) return retval;
stefanrousseau 4:f83bedd9cab4 202 retval = I2C_WriteMultipleBytes(Si1145_PMOD_I2C_ADDR, &txbuffer[0], 3, true);
stefanrousseau 4:f83bedd9cab4 203 if(retval!=0) return retval;
stefanrousseau 4:f83bedd9cab4 204 while(1)
stefanrousseau 4:f83bedd9cab4 205 {
stefanrousseau 4:f83bedd9cab4 206 retval=ReadFrom_Si1145_Register(REG_PARAM_RD);
stefanrousseau 4:f83bedd9cab4 207 if (retval==value) break;
stefanrousseau 4:f83bedd9cab4 208 }
stefanrousseau 4:f83bedd9cab4 209 return (0);
stefanrousseau 4:f83bedd9cab4 210 } //Si1145_ParamSet()
stefanrousseau 4:f83bedd9cab4 211
stefanrousseau 4:f83bedd9cab4 212 void PsAlsForce(void) //equivalent to WriteTo_Si1145_Register(REG_COMMAND,0x07). This forces PS and ALS measurements
stefanrousseau 4:f83bedd9cab4 213 {
stefanrousseau 4:f83bedd9cab4 214 WriteTo_Si1145_Register(REG_COMMAND,0x07);
stefanrousseau 4:f83bedd9cab4 215 } //PsAlsForce()
stefanrousseau 4:f83bedd9cab4 216
stefanrousseau 4:f83bedd9cab4 217 bool bSi1145_present = false;
stefanrousseau 4:f83bedd9cab4 218 void Init_Si1145(void)
stefanrousseau 4:f83bedd9cab4 219 {
stefanrousseau 4:f83bedd9cab4 220 unsigned char readbyte;
stefanrousseau 4:f83bedd9cab4 221 //Read Si1145 part ID:
stefanrousseau 4:f83bedd9cab4 222 readbyte = ReadFrom_Si1145_Register(0x00);
stefanrousseau 4:f83bedd9cab4 223 if (readbyte != 0x45)
stefanrousseau 4:f83bedd9cab4 224 {
stefanrousseau 4:f83bedd9cab4 225 bSi1145_present = false;
stefanrousseau 4:f83bedd9cab4 226 printf("Si1145 sensor not found\n");
stefanrousseau 4:f83bedd9cab4 227 }
stefanrousseau 4:f83bedd9cab4 228 else
stefanrousseau 4:f83bedd9cab4 229 {
stefanrousseau 4:f83bedd9cab4 230 bSi1145_present = true;
stefanrousseau 4:f83bedd9cab4 231 printf("Si1145 Part ID : 0x%02X\n", readbyte);
stefanrousseau 4:f83bedd9cab4 232 //Initialize Si1145 by writing to HW_KEY (I2C Register 0x07 = 0x17)
stefanrousseau 4:f83bedd9cab4 233 WriteTo_Si1145_Register(REG_HW_KEY, HW_KEY_VAL0);
stefanrousseau 4:f83bedd9cab4 234
stefanrousseau 4:f83bedd9cab4 235 // Initialize LED Current
stefanrousseau 4:f83bedd9cab4 236 // I2C Register 0x0F = 0xFF
stefanrousseau 4:f83bedd9cab4 237 // I2C Register 0x10 = 0x0F
stefanrousseau 4:f83bedd9cab4 238 WriteTo_Si1145_Register(REG_PS_LED21,(MAX_LED_CURRENT<<4) + MAX_LED_CURRENT);
stefanrousseau 4:f83bedd9cab4 239 WriteTo_Si1145_Register(REG_PS_LED3, MAX_LED_CURRENT);
stefanrousseau 4:f83bedd9cab4 240
stefanrousseau 4:f83bedd9cab4 241 // Parameter 0x01 = 0x37
stefanrousseau 4:f83bedd9cab4 242 //Si1145_ParamSet(PARAM_CH_LIST, ALS_IR_TASK + ALS_VIS_TASK + PS1_TASK + PS2_TASK + PS3_TASK);
stefanrousseau 4:f83bedd9cab4 243 //Si1145_ParamSet(0x01, 0x37); //CHLIST is address 0x01 in the parameter RAM. It defines which sensors are enabled (here, some)
stefanrousseau 4:f83bedd9cab4 244 Si1145_ParamSet(0x01, 0x7F); //CHLIST is address 0x01 in the parameter RAM. It defines which sensors are enabled (here, all but UV. One can only use AUX or UV but here we use AUX because UV does not work...)
stefanrousseau 4:f83bedd9cab4 245 // I2C Register 0x18 = 0x0x07 //This is PSALS_FORCE to the Command register => Force a single PS (proximity sensor) and ALS (ambient light sensor) reading - The factory code has this as 0x05 which only does PS...
stefanrousseau 4:f83bedd9cab4 246 PsAlsForce(); // can also be written as WriteTo_Si1145_Register(REG_COMMAND,0x07);
stefanrousseau 4:f83bedd9cab4 247 WriteTo_Si1145_Register(REG_COMMAND, 0x0F);//command to put it into auto mode
stefanrousseau 4:f83bedd9cab4 248 //Set MES_RATE to 0x1000. I.e. the device will automatically wake up every 16 * 256* 31.25 us = 0.128 seconds to measure
stefanrousseau 4:f83bedd9cab4 249 WriteTo_Si1145_Register(REG_MEAS_RATE_LSB, 0x00);
stefanrousseau 4:f83bedd9cab4 250 WriteTo_Si1145_Register(REG_MEAS_RATE_MSB, 0x10);
stefanrousseau 4:f83bedd9cab4 251 } //bSi1145_present = true
stefanrousseau 4:f83bedd9cab4 252 } //Init_Si1145()
stefanrousseau 4:f83bedd9cab4 253
stefanrousseau 4:f83bedd9cab4 254 void Read_Si1145(void)
stefanrousseau 4:f83bedd9cab4 255 {
stefanrousseau 4:f83bedd9cab4 256 if (bSi1145_present)
stefanrousseau 4:f83bedd9cab4 257 {
stefanrousseau 4:f83bedd9cab4 258 // Once the measurements are completed, here is how to reconstruct them
stefanrousseau 4:f83bedd9cab4 259 // Note very carefully that 16-bit registers are in the 'Little Endian' byte order
stefanrousseau 4:f83bedd9cab4 260 // It may be more efficient to perform block I2C Reads, but this example shows
stefanrousseau 4:f83bedd9cab4 261 // individual reads of registers
stefanrousseau 4:f83bedd9cab4 262
stefanrousseau 4:f83bedd9cab4 263 int PS1 = ReadFrom_Si1145_Register(REG_PS1_DATA0) + 256 * ReadFrom_Si1145_Register(REG_PS1_DATA1);
stefanrousseau 4:f83bedd9cab4 264 int PS2 = ReadFrom_Si1145_Register(REG_PS2_DATA0) + 256 * ReadFrom_Si1145_Register(REG_PS2_DATA1);
stefanrousseau 4:f83bedd9cab4 265 int PS3 = ReadFrom_Si1145_Register(REG_PS3_DATA0) + 256 * ReadFrom_Si1145_Register(REG_PS3_DATA1);
stefanrousseau 4:f83bedd9cab4 266 //printf("PS1_Data = %d\n", PS1);
stefanrousseau 4:f83bedd9cab4 267 //printf("PS2_Data = %d\n", PS2);
stefanrousseau 4:f83bedd9cab4 268 //printf("PS3_Data = %d\n", PS3);
stefanrousseau 4:f83bedd9cab4 269 //OBJECT PRESENT?
stefanrousseau 4:f83bedd9cab4 270 if(PS1 < 22000){
stefanrousseau 4:f83bedd9cab4 271 //printf("Object Far\n");
stefanrousseau 4:f83bedd9cab4 272 sprintf(SENSOR_DATA.Proximity, "Object Far");
stefanrousseau 4:f83bedd9cab4 273 }
stefanrousseau 4:f83bedd9cab4 274 else if(PS1 < 24000)
stefanrousseau 4:f83bedd9cab4 275 {
stefanrousseau 4:f83bedd9cab4 276 //printf("Object in Vicinity\n");
stefanrousseau 4:f83bedd9cab4 277 sprintf(SENSOR_DATA.Proximity, "Object in Vicinity");
stefanrousseau 4:f83bedd9cab4 278 }
stefanrousseau 4:f83bedd9cab4 279 else if (PS1 < 30000)
stefanrousseau 4:f83bedd9cab4 280 {
stefanrousseau 4:f83bedd9cab4 281 //printf("Object Near\n");
stefanrousseau 4:f83bedd9cab4 282 sprintf(SENSOR_DATA.Proximity, "Object Near");
stefanrousseau 4:f83bedd9cab4 283 }
stefanrousseau 4:f83bedd9cab4 284 else
stefanrousseau 4:f83bedd9cab4 285 {
stefanrousseau 4:f83bedd9cab4 286 //printf("Object Very Near\n");
stefanrousseau 4:f83bedd9cab4 287 sprintf(SENSOR_DATA.Proximity, "Object Very Near");
stefanrousseau 4:f83bedd9cab4 288 }
stefanrousseau 4:f83bedd9cab4 289
stefanrousseau 4:f83bedd9cab4 290 //Force ALS read:
stefanrousseau 4:f83bedd9cab4 291 //WriteTo_Si1145_Register(REG_COMMAND, 0x06);
stefanrousseau 4:f83bedd9cab4 292 //wait (0.1);
stefanrousseau 4:f83bedd9cab4 293 int ALS_VIS = ReadFrom_Si1145_Register(REG_ALS_VIS_DATA0) + 256 * ReadFrom_Si1145_Register(REG_ALS_VIS_DATA1);
stefanrousseau 4:f83bedd9cab4 294 int ALS_IR = ReadFrom_Si1145_Register(REG_ALS_IR_DATA0) + 256 * ReadFrom_Si1145_Register(REG_ALS_IR_DATA1);
stefanrousseau 4:f83bedd9cab4 295 int UV_INDEX = ReadFrom_Si1145_Register(REG_UVINDEX0) + 256 * ReadFrom_Si1145_Register(REG_UVINDEX1);
stefanrousseau 4:f83bedd9cab4 296 //printf("ALS_VIS_Data = %d\n", ALS_VIS);
stefanrousseau 4:f83bedd9cab4 297 //printf("ALS_IR_Data = %d\n", ALS_IR);
stefanrousseau 4:f83bedd9cab4 298 //printf("UV_INDEX_Data = %d\n", UV_INDEX);
stefanrousseau 4:f83bedd9cab4 299
stefanrousseau 4:f83bedd9cab4 300 //printf("Ambient Light Visible Sensor = %d\n", ALS_VIS);
stefanrousseau 4:f83bedd9cab4 301 sprintf(SENSOR_DATA.AmbientLightVis, "%d", ALS_VIS);
stefanrousseau 4:f83bedd9cab4 302 //printf("Ambient Light Infrared Sensor = %d\n", ALS_IR);
stefanrousseau 4:f83bedd9cab4 303 sprintf(SENSOR_DATA.AmbientLightIr, "%d", ALS_IR);
stefanrousseau 4:f83bedd9cab4 304 //float fUV_value = (UV_INDEX -50.0)/10000.0;
stefanrousseau 4:f83bedd9cab4 305 float fUV_value = (UV_INDEX)/100.0; //this is the aux reading
stefanrousseau 4:f83bedd9cab4 306 //printf("UV_Data = %0.2f\n", fUV_value);
stefanrousseau 4:f83bedd9cab4 307 sprintf(SENSOR_DATA.UVindex, "%0.2f", fUV_value);
stefanrousseau 4:f83bedd9cab4 308 } //bSi1145_present = true
stefanrousseau 4:f83bedd9cab4 309 } //Read_Si1145()
stefanrousseau 4:f83bedd9cab4 310
stefanrousseau 4:f83bedd9cab4 311 //********************************************************************************************************************************************
stefanrousseau 4:f83bedd9cab4 312 //* Read the FXOS8700CQ - 6-axis combo Sensor Accelerometer and Magnetometer
stefanrousseau 4:f83bedd9cab4 313 //********************************************************************************************************************************************
stefanrousseau 11:e6602513730f 314 bool bMotionSensor_present = false;
stefanrousseau 4:f83bedd9cab4 315 void init_motion_sensor()
stefanrousseau 4:f83bedd9cab4 316 {
stefanrousseau 11:e6602513730f 317 int iWhoAmI = fxos.get_whoami();
stefanrousseau 11:e6602513730f 318
stefanrousseau 11:e6602513730f 319 printf("FXOS8700CQ WhoAmI = %X\r\n", iWhoAmI);
stefanrousseau 4:f83bedd9cab4 320 // Iterrupt for active-low interrupt line from FXOS
stefanrousseau 4:f83bedd9cab4 321 // Configured with only one interrupt on INT2 signaling Data-Ready
stefanrousseau 4:f83bedd9cab4 322 //fxos_int2.fall(&trigger_fxos_int2);
stefanrousseau 11:e6602513730f 323 if (iWhoAmI != 0xC7)
stefanrousseau 11:e6602513730f 324 {
stefanrousseau 11:e6602513730f 325 bMotionSensor_present = false;
stefanrousseau 11:e6602513730f 326 printf("FXOS8700CQ motion sensor not found\n");
stefanrousseau 11:e6602513730f 327 }
stefanrousseau 11:e6602513730f 328 else
stefanrousseau 11:e6602513730f 329 {
stefanrousseau 11:e6602513730f 330 bMotionSensor_present = true;
stefanrousseau 11:e6602513730f 331 fxos.enable();
stefanrousseau 11:e6602513730f 332 }
stefanrousseau 4:f83bedd9cab4 333 } //init_motion_sensor
stefanrousseau 4:f83bedd9cab4 334
stefanrousseau 11:e6602513730f 335 void read_motion_sensor()
stefanrousseau 11:e6602513730f 336 {
stefanrousseau 11:e6602513730f 337 if (bMotionSensor_present)
stefanrousseau 11:e6602513730f 338 {
stefanrousseau 11:e6602513730f 339 fxos.get_data(&accel_data, &magn_data);
stefanrousseau 11:e6602513730f 340 //printf("Roll=%5d, Pitch=%5d, Yaw=%5d;\r\n", magn_data.x, magn_data.y, magn_data.z);
stefanrousseau 11:e6602513730f 341 sprintf(SENSOR_DATA.MagnetometerX, "%5d", magn_data.x);
stefanrousseau 11:e6602513730f 342 sprintf(SENSOR_DATA.MagnetometerY, "%5d", magn_data.y);
stefanrousseau 11:e6602513730f 343 sprintf(SENSOR_DATA.MagnetometerZ, "%5d", magn_data.z);
stefanrousseau 11:e6602513730f 344
stefanrousseau 11:e6602513730f 345 //Try to normalize (/2048) the values so they will match the eCompass output:
stefanrousseau 11:e6602513730f 346 float fAccelScaled_x, fAccelScaled_y, fAccelScaled_z;
stefanrousseau 11:e6602513730f 347 fAccelScaled_x = (accel_data.x/2048.0);
stefanrousseau 11:e6602513730f 348 fAccelScaled_y = (accel_data.y/2048.0);
stefanrousseau 11:e6602513730f 349 fAccelScaled_z = (accel_data.z/2048.0);
stefanrousseau 11:e6602513730f 350 //printf("Acc: X=%2.3f Y=%2.3f Z=%2.3f;\r\n", fAccelScaled_x, fAccelScaled_y, fAccelScaled_z);
stefanrousseau 11:e6602513730f 351 sprintf(SENSOR_DATA.AccelX, "%2.3f", fAccelScaled_x);
stefanrousseau 11:e6602513730f 352 sprintf(SENSOR_DATA.AccelY, "%2.3f", fAccelScaled_y);
stefanrousseau 11:e6602513730f 353 sprintf(SENSOR_DATA.AccelZ, "%2.3f", fAccelScaled_z);
stefanrousseau 11:e6602513730f 354 } //bMotionSensor_present
stefanrousseau 11:e6602513730f 355 } //read_motion_sensor
stefanrousseau 11:e6602513730f 356
stefanrousseau 4:f83bedd9cab4 357 void sensors_init(void)
stefanrousseau 4:f83bedd9cab4 358 {
stefanrousseau 4:f83bedd9cab4 359 Init_Si7020();
stefanrousseau 4:f83bedd9cab4 360 Init_Si1145();
stefanrousseau 4:f83bedd9cab4 361 init_motion_sensor();
stefanrousseau 4:f83bedd9cab4 362 } //sensors_init
stefanrousseau 4:f83bedd9cab4 363
stefanrousseau 4:f83bedd9cab4 364 void read_sensors(void)
stefanrousseau 4:f83bedd9cab4 365 {
stefanrousseau 4:f83bedd9cab4 366 Read_Si7020();
stefanrousseau 4:f83bedd9cab4 367 Read_Si1145();
stefanrousseau 4:f83bedd9cab4 368 read_motion_sensor();
stefanrousseau 4:f83bedd9cab4 369 } //read_sensors