Sog Yang
BLE-WiFi with BIOSensors
Dependencies: AS7000 BNO055 NNN50_WIFI_API
DELTA NNN50 (Bluetooth LE 4.X & 802.11 b/g/n) with Bio Sensor (HRM, 9DoF motion Sensor) reference design.
Env. Setup step by step.
- Download or build a TCP Server on you host computer
- Please find out the TCP server code or install TCP server application in your host computer.
- Import this sample application and setup these information about AP & TCP Server
- *char* AP_SSID = "SOG";
- *char* AP_PWD = "1122334455667788";
- *char* TCP_SERVER_ADDRESS = "10.0.1.13";
- *int TCP_SERVER_PORT = 1030;
- Compiler your code and download to your mBed device.
- Control your mBed device
- Please use NORDSemi nRF Tool and setup and watch these information: GATT CMD: 0x00 (connect to AP, TCP Server, and create TCP socket), 0x02 disconnection TCP server, close socket, and WiFi sleep), 0xA1 (send sensor data to tcp server from out_buffer[]) and Status will be update by Bluetooth LE adv through manufacturing information
| 0x00 | 0x02 | 0xA1 |
|---|---|---|
| WiFi,AP&TCP Server connect | WiFi,AP, & TCP Server disconnect | Send sensor data to TCP Server |
main.cpp
- Committer:
- sog_yang
- Date:
- 2017-06-01
- Revision:
- 14:eacafd9e019f
- Parent:
- 13:a777cab6c218
- Child:
- 15:d22f450bb909
File content as of revision 14:eacafd9e019f:
#include "mbed.h"
#include "BNO055.h"
#include "AS7000.h"
#include "ble/BLE.h"
#include "ble/Gap.h"
#include "ble/services/BatteryService.h"
#include "DOORService.h"
#include "EthernetInterface.h"
#include "WIFIDevice.h"
#define DEBUG_LOG 0
union IP {
unsigned int ip;
struct {
unsigned char d;
unsigned char c;
unsigned char b;
unsigned char a;
} ip2;
};
char ips[20];
IP ip;
DOORService *doorServicePtr;
BNO055 imu(p0,p30);
AS7000 hrm(p0,p30);
Serial pc(USBTX, USBRX);
DigitalInOut myOutputPin(USBTX);
EthernetInterface eth;
WIFIDevice wifi;
TCPSocketConnection sock_tcp;
char* AP_SSID = "SOG";
char* AP_PWD = "1122334455667788";
char* TCP_SERVER_ADDRESS = "10.0.1.13";
int TCP_SERVER_PORT = 1030;
uint8_t initialValueForDOORCharacteristic = 0xFF;
uint8_t BLE_RX_CMD = 0xFF;
const char DEVICE_NAME[] = "FITNCTL";
uint8_t ADV_manuf[] = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
char out_buffer[45];
static EventQueue eventQueue(
/* event count */ 16 * /* event size */ 32
);
bool isConnect = false;
bool isWiFiEnable = false;
bool isCloudFiling = false;
void disconnectionCallback(const Gap::DisconnectionCallbackParams_t *params)
{
BLE::Instance().gap().startAdvertising();
}
void onDataWrittenCallback(const GattWriteCallbackParams *params) {
if ((params->handle == doorServicePtr->getValueHandle()) && (params->len == 1)) {
{
BLE_RX_CMD = *(params->data);
}
}
}
/**
* This function is called when the ble initialization process has failled
*/
void onBleInitError(BLE &ble, ble_error_t error)
{
/* Initialization error handling should go here */
}
/**
* Callback triggered when the ble initialization process has finished
*/
void bleInitComplete(BLE::InitializationCompleteCallbackContext *params)
{
BLE& ble = params->ble;
ble_error_t error = params->error;
if (error != BLE_ERROR_NONE) {
/* In case of error, forward the error handling to onBleInitError */
onBleInitError(ble, error);
return;
}
/* Ensure that it is the default instance of BLE */
if(ble.getInstanceID() != BLE::DEFAULT_INSTANCE) {
return;
}
ble.gap().onDisconnection(disconnectionCallback);
ble.gattServer().onDataWritten(onDataWrittenCallback);
/* Setup primary services */
doorServicePtr = new DOORService(ble, initialValueForDOORCharacteristic);
/* Setup advertising */
ble.gap().accumulateAdvertisingPayload(GapAdvertisingData::COMPLETE_LOCAL_NAME, (uint8_t *)DEVICE_NAME, sizeof(DEVICE_NAME));
ble.gap().accumulateAdvertisingPayload(GapAdvertisingData::MANUFACTURER_SPECIFIC_DATA, ADV_manuf, sizeof(ADV_manuf));
ble.gap().setAdvertisingType(GapAdvertisingParams::ADV_CONNECTABLE_UNDIRECTED);
ble.gap().setAdvertisingInterval(150); /* 1000ms */
ble.gap().startAdvertising();
}
void scheduleBleEventsProcessing(BLE::OnEventsToProcessCallbackContext* context) {
BLE &ble = BLE::Instance();
eventQueue.call(Callback<void()>(&ble, &BLE::processEvents));
}
int main (void) {
myOutputPin.mode(PullUp);
pc.baud(38400);
hrm.enable();
imu.reset();
imu.setmode(OPERATION_MODE_NDOF);
BLE &ble = BLE::Instance();
ble.onEventsToProcess(scheduleBleEventsProcessing);
ble.init(bleInitComplete);
int i = 0;
int j = 0;
BLE_RX_CMD = 0xFF;
wait_ms(10);
sprintf(out_buffer,"\r\n");
while (true) {
wait_ms(2);
__disable_irq(); // Disable Interrupts
imu.get_angles(); //query the i2c device
hrm.hr_only();
__ensable_irq();// Enable Interrupts
wait_ms(8);
if (BLE_RX_CMD != 0xA1) {
if (i > 40){
pc.printf("*HR=%03d#", hrm.hrm.hreat_rate);
i=0;
} i++;
}
/* GATT Command 0xA1 Cloud Data Transfer*/
if (BLE_RX_CMD == 0xA1){
ADV_manuf[5] = 0xF1;
if (isWiFiEnable == true){
if (isConnect == true) {
if (j > 2){
pc.printf("*HR=%03d#", hrm.hrm.hreat_rate);
j = 0;
}j++;
sprintf(out_buffer,"hrm:%03d yaw:%6.2f pitch:%6.2f roll:%6.2f\n", hrm.hrm.hreat_rate, imu.euler.yaw, imu.euler.pitch, imu.euler.roll);
sock_tcp.send_all(out_buffer, sizeof(out_buffer) - 1);
sock_tcp.set_blocking(false, 200);// Timeout after 0.2s
isCloudFiling = true;
} else {
if (sock_tcp.connect(TCP_SERVER_ADDRESS, TCP_SERVER_PORT) < 0) {
isConnect = false;
BLE_RX_CMD = 0xFF;
#if DEBUG_LOG
pc.printf("Unable to connect to (%s) on port (%d)\n", ECHO_SERVER_ADDRESS, ECHO_SERVER_PORT);
#endif
ADV_manuf[4] = 0xCF;
BLE_RX_CMD = 0xFF;
} else {
isConnect = true;
ADV_manuf[4] = 0xF1;
#if DEBUG_LOG
pc.printf("Connected to Server at %s\n",ECHO_SERVER_ADDRESS);
#endif
}
}
}
}
/* GATT Command 0x02 WiFI & Cloud Connection Close*/
if (BLE_RX_CMD == 0x02){
BLE_RX_CMD = 0xFF;
ADV_manuf[5] = 0xF2;
if ( isConnect == true ) {
sock_tcp.close();
isConnect = false;
}
if ( isWiFiEnable == true ) {
eth.disconnect();
wifi.sleep();
isWiFiEnable = false;
}
while(true) {
if (wifi.is_AP_connected()==0) break; //make sure wifi disconnect
}
if (isConnect == true) isConnect = false;
isConnect = false;
isWiFiEnable = false;
isCloudFiling = false;
ADV_manuf[0] = 0x00;
ADV_manuf[1] = 0x00;
ADV_manuf[2] = 0x00;
ADV_manuf[3] = 0x00;
ADV_manuf[4] = 0x00;
sprintf(out_buffer,"\n");
}
/* GATT Command 0x0 init WiFI & Cloud Connection*/
if (BLE_RX_CMD == 0x00){
if(isCloudFiling == false) {
BLE_RX_CMD = 0xFF;
ADV_manuf[5] = 0xF0;
if (isWiFiEnable == false) {
eth.init();
wifi.setNetwork(M2M_WIFI_SEC_WPA_PSK, AP_SSID, AP_PWD);
eth.connect();
while(true) {
if (wifi.is_AP_connected()==1) break;
}
sock_tcp.set_blocking(false, 1200);// Timeout after 1.2s
#if DEBUG_LOG
pc.printf("Connect Success! \n");
pc.printf("MAC: %s\n", eth.getMACAddress());
pc.printf("IP: %s\n", eth.getIPAddress());
pc.printf("Gateway: %s\n", eth.getGateway());
pc.printf("NetworkMask: %s\n", eth.getNetworkMask());
#endif
snprintf(ips, sizeof(ips), "%s",eth.getIPAddress());
unsigned short a, b, c, d;
sscanf(ips, "%hu.%hu.%hu.%hu", &a, &b, &c, &d);
sprintf(ips, "%x.%x.%x.%x", a, b, c, d);
ADV_manuf[0] = a;
ADV_manuf[1] = b;
ADV_manuf[2] = c;
ADV_manuf[3] = d;
isWiFiEnable = true;
}
if (isConnect == false) {
if (isWiFiEnable == true) {
if (sock_tcp.connect(TCP_SERVER_ADDRESS, TCP_SERVER_PORT) < 0) {
#if DEBUG_LOG
pc.printf("Unable to connect to (%s) on port (%d)\n", ECHO_SERVER_ADDRESS, ECHO_SERVER_PORT);
#endif
sock_tcp.close();
ADV_manuf[4] = 0xCF;
} else {
isConnect = true;
isCloudFiling = false;
ADV_manuf[4] = 0xF1;
#if DEBUG_LOG
pc.printf("Connected to Server at %s\n",ECHO_SERVER_ADDRESS);
#endif
}
}
}
}
}
BLE::Instance(BLE::DEFAULT_INSTANCE).gap().updateAdvertisingPayload(GapAdvertisingData::MANUFACTURER_SPECIFIC_DATA, ADV_manuf, sizeof(ADV_manuf));
ble.waitForEvent();
}
}