Team Fox
Updated EPS code with flowchart v2.3 (CDMS and HW faults)
Dependencies: FreescaleIAP mbed-rtos mbed
Fork of
QM_BAE_review_1_EPS_faults
by 
Mohamed Azad
BCN.cpp
- Committer:
- azaddevarm
- Date:
- 2016-06-23
- Revision:
- 17:bb0d64656ba1
- Parent:
- 14:a9588f443f1a
File content as of revision 17:bb0d64656ba1:
#include "BCN.h"
#include <stdio.h>
#include "pin_config.h"
//Check the pin names
//Takes max 4.3 sec in void FCTN_BCN_TX_MAIN() (temp.calc. + long_beacon + short_beacon)
Serial pc_bcn(USBTX, USBRX); //tx,rx
SPI spi(PIN16, PIN17, PIN15); // mosi, miso, sclk
DigitalOut cs(PIN6); //slave select or chip select
Timer t_i;
Timeout rf_sl_timeout;
Ticker loop;
//GLOBAL VARIABLES
uint8_t BCN_INIT_STATUS = 0;
uint8_t BCN_TX_MAIN_STATUS = 0;
uint8_t BCN_TX_STATUS = 0;
uint8_t BCN_TX_EN = 1; //hardcoding for now //check where is this variable toggled??
uint8_t BCN_FEN = 0; //hardcoding for now //write this value to flash
uint8_t BCN_STANDBY = 0; //hardcoding for now //check where is this variable toggled??
uint8_t BCN_TS_BUFFER = 0; // For Temperature
void FCTN_BCN_INIT()
{
pc_bcn.printf("FCTN_BCN_INIT\n");
BCN_INIT_STATUS = 1;
if(BCN_FEN == 0)
rf_sl_timeout.attach(&FCTN_BCN_FEN, 30);
Init_BEACON_HW();
BCN_INIT_STATUS = 0;
}
void FCTN_BCN_FEN()
{
pc_bcn.printf("FCTN_FEN\n");
BCN_FEN = 1;//write this value to flash
}
void FCTN_BCN_TX_MAIN()
{
pc_bcn.printf("FCTN_BCN_TX_MAIN\n");
t_i.start();
int begin = t_i.read_us();
BCN_TX_MAIN_STATUS = 1;
if(BCN_FEN == 1)
{
if(BCN_TX_EN == 1)
{
//Measure and store BCN temperature in BCN_TS_BUFFER
BCN_TS_BUFFER = check_Temperature();
pc_bcn.printf("\n\ntemperature = %d\n\n",BCN_TS_BUFFER);
//Get BCN_HK data from BCN HW(SPI) //Store BCN_HK data in BCN_HK_BUFFER
if(BCN_STANDBY == 1 )
{
Set_BCN_TX_STATUS(BCN_TX_STANDBY);
BCN_TX_MAIN_STATUS = 0;
// break;
}
else
{
//transmit short beacon and long beacon
//SHORT_BCN_TX();
LONG_BCN_TX();
if(Check_ACK_RECEIVED() == 1)
{
Set_BCN_TX_STATUS(BCN_TX_SUCCESS);
BCN_TX_MAIN_STATUS = 0;
}
else
{
Set_BCN_TX_STATUS(BCN_TX_FAILURE);
BCN_TX_MAIN_STATUS = 0;
}
}
}
else
{
Set_BCN_TX_STATUS(BCN_TX_DISABLED);
BCN_TX_MAIN_STATUS = 0;
}
}
else
{
Set_BCN_TX_STATUS(BCN_RF_SILENCE); //Window of RF Silence: None of the Txs should be on.
BCN_TX_MAIN_STATUS = 0;
}
t_i.stop();
int end = t_i.read_us();
pc_bcn.printf("The time required for FCTN_BCN_TX_MAIN is %d useconds\r\n", end-begin);
}
void Set_BCN_TX_STATUS(uint8_t STATUS)
{
BCN_TX_STATUS = STATUS;
}
uint8_t check_Temperature()
{
uint8_t temperature;
writereg(RF22_REG_0F_ADC_CONFIGURATION,0x00);
writereg(RF22_REG_12_Temperature_Sensor_Calibration,0x20);
writereg(RF22_REG_0F_ADC_CONFIGURATION,0x80);
wait(0.1);
temperature = readreg(RF22_REG_11_ADC_Value);
temperature = (float)temperature*0.5 - 64;
return temperature;
}
void SHORT_BCN_TX()
{
writereg(RF22_REG_6E_TX_DATA_RATE,0x01);
writereg(RF22_REG_6F_TX_DATA_RATE,0x50);//160bps
writereg(RF22_REG_3E_PACKET_LENGTH,SHORT_TX_DATA); //short packet length
wait(0.02);
uint32_t timeout_count = 10e5;
//extract values from short_beacon[]
struct Short_beacon
{
uint8_t Voltage[1];
uint8_t AngularSpeed[2];
uint8_t SubsystemStatus[1];
uint8_t Temp[3];
uint8_t ErrorFlag[1];
}Shortbeacon = { {0x88}, {0x99, 0xAA} , {0xAA},{0xAA,0xDD,0xEE}, {0x00} };
//filling hk data
//uint8_t short_beacon[] = { 0xAB, 0x8A, 0xE2, 0xBB, 0xB8, 0xA2, 0x8E,Shortbeacon.Voltage[0],Shortbeacon.AngularSpeed[0], Shortbeacon.AngularSpeed[1],Shortbeacon.SubsystemStatus[0],Shortbeacon.Temp[0],Shortbeacon.Temp[1],Shortbeacon.Temp[2],Shortbeacon.ErrorFlag[0]};
uint8_t short_beacon[] = { 0x11, 0x22, 0x33, 0x44, 0x55, 0x66, 0x77,Shortbeacon.Voltage[0],Shortbeacon.AngularSpeed[0], Shortbeacon.AngularSpeed[1],Shortbeacon.SubsystemStatus[0],Shortbeacon.Temp[0],Shortbeacon.Temp[1],Shortbeacon.Temp[2],Shortbeacon.ErrorFlag[0]};
clearTxBuf();
//writing data first time
int byte = 0;
cs = 0;
spi.write(0xFF);
for (int byte_counter = 0; byte_counter <15 ; byte_counter++)
{
for(int j = 3; j >= 0 ; j--)
{
if((short_beacon[byte_counter] & (uint8_t) pow(2.0,(j*2+1)))!= pow(2.0,(j*2+1)))
{
byte=0x00;
}
else
{
byte=0xF0;
}
if((short_beacon[byte_counter] & (uint8_t) pow(2.0,j*2))!= pow(2.0,j*2))
{
byte=byte | 0x00;
}
else
{
byte=byte | 0x0F;
}
spi.write(byte);
}
}
cs = 1;
//Set to Tx mode
writereg(RF22_REG_07_OPERATING_MODE1,0x08);//*
wait(0.1);
//Check for fifoThresh
while(timeout_count--)if((readreg(RF22_REG_03_INTERRUPT_STATUS1) & 0x20) == 0x20)break;
timeout_count=10e5;
//Check for packet_sent
while(timeout_count--)if((readreg(RF22_REG_03_INTERRUPT_STATUS1) & 0x04) == 0x04)break;
//pc_bcn.printf("Short packet sent\r\n");
writereg(RF22_REG_07_OPERATING_MODE1,0x00); //standby mode
}
void LONG_BCN_TX()
{
writereg(RF22_REG_6E_TX_DATA_RATE,0x08);
writereg(RF22_REG_6F_TX_DATA_RATE,0x31);//1000 bps
writereg(RF22_REG_3E_PACKET_LENGTH,LONG_TX_DATA); //long packet length
wait(0.02);
uint32_t timeout_count=10e5;
//get long_beacon array
uint8_t Long_beacon[125];
for(int i = 0;i<125;)
{
Long_beacon[i++] = 0xAA;
}
//setModeIdle();
clearTxBuf();
//writing data first time
cs = 0;
spi.write(0xFF);
for(int i=0; i<60;i++)
{
spi.write(Long_beacon[i]);
}
cs = 1;
//Set to Tx mode
writereg(RF22_REG_07_OPERATING_MODE1,0x08);//*
wait(0.1);
//Check for fifoThresh
while(timeout_count--)if((readreg(RF22_REG_03_INTERRUPT_STATUS1) & 0x20) == 0x20)break;
timeout_count=10e5;
cs = 0;
spi.write(0xFF);
for(int i=60; i<125;i++)
{
spi.write(Long_beacon[i]);
}
cs = 1;
wait(0.1);
//Check for fifoThresh
while(timeout_count--)if((readreg(RF22_REG_03_INTERRUPT_STATUS1) & 0x20) == 0x20)break;
timeout_count=10e5;
//Check for packetsent interrupt
while(timeout_count--)if((readreg(RF22_REG_03_INTERRUPT_STATUS1) & 0x04) == 0x04)break;
//pc_bcn.printf("Long packet sent\r\n");
writereg(RF22_REG_07_OPERATING_MODE1,0x00); //standby mode
}
void reset_rfm()
{
FCTN_BCN_INIT();
}
void writereg(uint8_t reg,uint8_t val)
{
uint8_t count = 0;
for(;;count++)
{
int read_val =0; cs = 0;spi.write(reg | 0x80);spi.write(val);cs = 1;
if(reg != 0x7 && reg != 0x58 && reg != 0xF)
{
read_val = readreg(reg);
if (read_val == val)
{
break;
}
else if(count == 5)
{
reset_rfm(), printf("reg = 0x%X\n",reg);break;
}
}
else
break;
}
}
uint8_t readreg(uint8_t reg)
{
uint8_t val;cs = 0;spi.write(reg & ~0x80);val = spi.write(0);cs = 1;return val;
}
void clearTxBuf()
{
writereg(RF22_REG_08_OPERATING_MODE2,0x01);
writereg(RF22_REG_08_OPERATING_MODE2,0x00);
}
uint8_t setFrequency(double centre)
{
uint8_t fbsel = 0x40;
if (centre >= 480.0) {
centre /= 2;
fbsel |= 0x20;
}
centre /= 10.0;
double integerPart = floor(centre);
double fractionalPart = centre - integerPart;
uint8_t fb = (uint8_t)integerPart - 24; // Range 0 to 23
fbsel |= fb;
uint16_t fc = fractionalPart * 64000;
writereg(RF22_REG_73_FREQUENCY_OFFSET1, 0); // REVISIT
writereg(RF22_REG_74_FREQUENCY_OFFSET2, 0);
writereg(RF22_REG_75_FREQUENCY_BAND_SELECT, fbsel);
writereg(RF22_REG_76_NOMINAL_CARRIER_FREQUENCY1, fc >> 8);
writereg(RF22_REG_77_NOMINAL_CARRIER_FREQUENCY0, fc & 0xff);
return 0;
}
void Init_BEACON_HW()
{
wait(0.1);
cs=1; // chip must be deselected
wait(0.1);
spi.format(8,0);
spi.frequency(10000000); //10MHz SCLK
//should either have a flag for invalid SPI or discard this for actual case or add reset
if (readreg(RF22_REG_00_DEVICE_TYPE) == 0x08)
pc_bcn.printf("spi connection valid\r\n");
else
{pc_bcn.printf("error in spi connection\r\n");
reset_rfm();
}
writereg(RF22_REG_07_OPERATING_MODE1,0x80); //sw_reset
wait(0.1); //takes time to reset
clearTxBuf();
writereg(RF22_REG_07_OPERATING_MODE1,0x00); //standby mode
//txfifoalmostempty
writereg(RF22_REG_7D_TX_FIFO_CONTROL2,30);
//Packet-engine registers
writereg(RF22_REG_30_DATA_ACCESS_CONTROL,0x00);
writereg(RF22_REG_33_HEADER_CONTROL2,0x08);
writereg(RF22_REG_34_PREAMBLE_LENGTH,0x00);
writereg(RF22_REG_0B_GPIO_CONFIGURATION0,0x15); // TX state
writereg(RF22_REG_0C_GPIO_CONFIGURATION1,0x12); // RX state
setFrequency(435.0);
if((readreg(RF22_REG_02_DEVICE_STATUS)& 0x08)!= 0x00)
{
pc_bcn.printf("frequency not set properly\r\n");
reset_rfm();
}
//set Modem Configuration
//writereg(RF22_REG_1C_IF_FILTER_BANDWIDTH,0xdf);
//writereg(RF22_REG_1F_CLOCK_RECOVERY_GEARSHIFT_OVERRIDE,0x03);
//writereg(RF22_REG_20_CLOCK_RECOVERY_OVERSAMPLING_RATE,0x39);
//writereg(RF22_REG_21_CLOCK_RECOVERY_OFFSET2,0x20);
//writereg(RF22_REG_22_CLOCK_RECOVERY_OFFSET1,0x68); //updated 20 to 25 reg values from excel sheet for 1.2 Khz freq. deviation,fsk
//writereg(RF22_REG_23_CLOCK_RECOVERY_OFFSET0,0xdc);
//writereg(RF22_REG_24_CLOCK_RECOVERY_TIMING_LOOP_GAIN1,0x00);
//writereg(RF22_REG_25_CLOCK_RECOVERY_TIMING_LOOP_GAIN0,0x6B);
//writereg(RF22_REG_2C_OOK_COUNTER_VALUE_1,0x2C);
//writereg(RF22_REG_2D_OOK_COUNTER_VALUE_2,0x11); //not required for fsk (OOK counter value)
//writereg(RF22_REG_2E_SLICER_PEAK_HOLD,0x2A); //??
writereg(RF22_REG_58,0x80);
//writereg(RF22_REG_69_AGC_OVERRIDE1,0x60);
//Data rate set later
writereg(RF22_REG_70_MODULATION_CONTROL1,0x20);
writereg(RF22_REG_71_MODULATION_CONTROL2,0x21);//ook = 0x21
//set tx power
writereg(RF22_REG_6D_TX_POWER,0x07); //20dbm
//TX_packet_length written later
}
bool Check_ACK_RECEIVED()
{
if((readreg(RF22_REG_03_INTERRUPT_STATUS1) & 0x04) == 0x04)
{
printf("Packet sent: ACK received\r\n");
return 1;
}
else
{
pc_bcn.printf("Packet not sent\r\n");
return 0;
}
}
/*int main()
{
FCTN_BCN_INIT();
loop.attach(&FCTN_BCN_TX_MAIN, 10.0);//in actual case its 30.0
while(1);
}*/