Klika Tech / Mbed 2 deprecated Nucleo-AWS-IoT-mbed

Example of AWS IoT connection and Web Dashboard thru STM32 Nucleo evaluation board and mbed OS.

Dependencies:   X_NUCLEO_IKS01A1 mbed FP MQTTPacket DnsQuery ATParser

Introduction

The demo is aimed to STM32 Nucleo board with WiFi and sensors expansions. The board is a "thing" for the AWS IoT service. It updates IoT service shadow with sensors data every second and checks subscription messages.

Hardware Configuration

https://github.com/Klika-Tech/nucleo-aws-iot-demo/raw/master/doc/assets/device.jpg

Software Configuration

  • Import this Project to mbed online compiler
  • Find the next part of code in main.cpp file ...

WiFi network credential

#include "mbed.h"
// WiFi network credential
#define SSID   ""  // Network must be visible otherwise it can't connect
#define PASSW  ""
#error "Wifi SSID & password empty"
  • ... And set it to your Network Name and Password. Do not forget to remove "#error" pragma line.

Information

Nucleo WiFi module is not the same as your smartphone or laptope - it is based on demo board. To avoid connection problems:

  1. Place Nucleo as close to WiFi hot spot as possible. Or...
  2. Turn on mobile hot spot in your laptop as close to the device as possible.
  3. Make sure that hot spot permits 2.4 GHz band communications
  • Setup BackEnd and store certificates using this backend setup instruction
  • Find AWS_IOT_MQTT_HOST define and change it to HTTPS point mentioned in your AWS IoT thing properties named "interact" 

#define AWS_IOT_MQTT_HOST              "xxxxxxxxxx.iot.us-east-1.amazonaws.com" //Use your own host.
  • Find the certificate defines clientCRT and clientKey in main.cpp file and change it to ones provided by Amazon. 

/**********************************************************************************************
***********************************************************************************************
				Device Identity Certificates: Modify for your AWS IoT Thing
***********************************************************************************************
***********************************************************************************************/

/****************************************
(somecode)-certificate.pem.crt - Amazon signed PEM sertificate.
*****************************************/

//This Client cert is example. Use own instead.
const uint8_t clientCRT[] = "\
-----BEGIN CERTIFICATE-----\n\
MIIDBjCCAe6gAwIBAgIUVph856omeIxW3UPioq+UrX1DbwowDQYJKoZIhvcNAQEL\
BQAwTTFLMEkGA1UECwxCQW1hem9uIFdlYiBTZXJ2aWNlcyBPPUFtYXpvbi5jb20g\
SW5jLiBMPVNlYXR0bGUgU1Q9V2FzaGluZ3RvbiBDPVVTMB4XDTE3MDUyNTExNTEy\
OVoXDTQ5MTIzMTIzNTk1OVowgZUxCzAJBgNVBAYTAkJZMQ4wDAYDVQQIDAVNaW5z\
azEOMAwGA1UEBwwFTWluc2sxFzAVBgNVBAoMDktsaWthLVRlY2ggTExDMRcwFQYD\
VQQLDA5LbGlrYS1UZWNoIExMQzEMMAoGA1UEAwwDUm5EMSYwJAYJKoZIhvcNAQkB\
FhdtdmF0YWxldUBrbGlrYS10ZWNoLmNvbTBZMBMGByqGSM49AgEGCCqGSM49AwEH\
A0IABCJgOQJmoTBJVPfli9Hm/JVixaxkY5rtlgrYO3hSl633A2hg0P/ue0wXDbF3\
aQ0X57IRFE4k4FEbr3UXjT/IczKjYDBeMB8GA1UdIwQYMBaAFK3YzTUPlYB2Li75\
i/z8rEogr1d6MB0GA1UdDgQWBBT18HXBaXFJuAR/0SwegnxJ+pyJ6TAMBgNVHRMB\
Af8EAjAAMA4GA1UdDwEB/wQEAwIHgDANBgkqhkiG9w0BAQsFAAOCAQEAb0Ux1aH5\
RLxjrfGqXN6rPVqh8QQRS+AyBfzmaQN8HaPZMkX5WxXLvcn0A3uWlwQxPPkcZ4zf\
51GHtFFQWB4YZ8dx8mUQ0v/j7onHjCJgZ8iDgwOyKMGtnsDZWCakQw+a6cj+NrMZ\
tzhjwCzEEP6ePcbXwErI5OOzLuWns2L/JEr2wWNkokgRuS8ewr/SQ9OLWIWa2rFM\
ahPNTb3y/qBeWdjeJmhI+TOxdqIpsF8roWP25zwo/zkzCHCjXFBrL+0CA4MpxIl9\
x02i7aAhlJ6ys80lDxdeWeeQJXRKkGknP8mcmKn3iEqqJ5s1dQePj2b5d3ldatya\
wsxQBqqZXzIWEw==\
\n\
-----END CERTIFICATE-----\n";



/**********************************************************************************************
***********************************************************************************************
						Private Key: Modify for your AWS IoT Thing
***********************************************************************************************
***********************************************************************************************/

/********************************************************************8****************************************
nucleo.key.pem - client key generated according to readme.
**************************************************************************************************************/

//This Client Key is example. Use own instead.
const uint8_t clientKey[] ="\
-----BEGIN EC PARAMETERS-----\n\
BggqhkjOPQMBBw==\
-----END EC PARAMETERS-----\n\
-----BEGIN EC PRIVATE KEY-----\n\
MHcCAQEEIHPRfWSC8/k/BsqDWKuP15dXsI9fGwpkTIsLZe6mIrAAoAoGCCqGSM49\
AwEHoUQDQgAEImA5AmahMElU9+WL0eb8lWLFrGRjmu2WCtg7eFKXrfcDaGDQ/+57\
TBcNsXdpDRfnshEUTiTgURuvdReNP8hzMg==\
-----END EC PRIVATE KEY-----\n";

Build and Check

  1. Plugin your board to USB of your PC. USB Disk Drive and USB COM Port should appear in your system.
  2. Open any Serial Console, connect it to your USB Serial Port and setup speed equal to 115200.
  3. Compile this Project and save .bin file to USB Disk Drive
  4. After board reset you should see next log in serial console: 

X-NUCLEO-IDW01M1 mbed Application

connecting to AP
LOG:   int main() L#361 Connected to WiFI.
LOG:   int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#186 =====================================
LOG:   int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#187 Connecting WiFi.
LOG:   int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#188 Nucleo IP ADDRESS: X.X.X.X
LOG:   int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#189 Nucleo MAC ADDRESS: 00:11:22:33:44:55
LOG:   int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#190 Server Hostname: xxxxxxxx.iot.us-east-1.amazonaws.com port: 8883
LOG:   int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#191 Client ID: Nucleo
LOG:   int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#194 =====================================
LOG:   int MQTTSocket::getNTPtime(int) L#58 Success receiving time from ntp server. Tick from 1 Jan 1970 is equal to 1505399292.
--->TCP Connected
--->MQTT Connected
--->>>MQTT subscribed to: Nucleo/test
Length - 245, Publishing {"state": {"reported": {"temperature": 23.690001, "humidity": 98.190002, "pressure": 982.869141, "accelerometer": [-0.009000, 0.030000, 0.971000], "gyroscope": [0.420000, -2.660000, 1.750000], "magnetometer": [-3.600000, -7.100000, 53.300000]}}}
Length - 245, Publishing {"state": {"reported": {"temperature": 23.660000, "humidity": 98.010002, "pressure": 982.770264, "accelerometer": [-0.009000, 0.030000, 0.971000], "gyroscope": [0.770000, -2.310000, 1.470000], "magnetometer": [-3.100000, -8.300000, 54.200000]}}}
Length - 245, Publishing {"state": {"reported": {"temperature": 23.670000, "humidity": 98.129997, "pressure": 982.724121, "accelerometer": [-0.008000, 0.029000, 0.971000], "gyroscope": [0.630000, -2.380000, 1.400000], "magnetometer": [-3.100000, -7.900000, 53.400000]}}}
Length - 245, Publishing {"state": {"reported": {"temperature": 23.690001, "humidity": 98.019997, "pressure": 982.840088, "accelerometer": [-0.009000, 0.030000, 0.972000], "gyroscope": [0.700000, -2.450000, 1.540000], "magnetometer": [-3.700000, -7.900000, 53.400000]}}}
Length - 245, Publishing {"state": {"reported": {"temperature": 23.709999, "humidity": 98.040001, "pressure": 982.828613, "accelerometer": [-0.009000, 0.030000, 0.971000], "gyroscope": [0.630000, -2.520000, 1.470000], "magnetometer": [-2.900000, -7.400000, 52.400000]}}}
Length - 245, Publishing {"state": {"reported": {"temperature": 23.719999, "humidity": 97.860001, "pressure": 982.917236, "accelerometer": [-0.026000, 0.103000, 0.891000], "gyroscope": [1.050000, -2.310000, 1.260000], "magnetometer": [-3.300000, -7.100000, 53.500000]}}}

Information

Device connection state might be checked by Green Led on the board. Green light means that device is connected and transferring data to cloud.

  1. Configure and start your dashboard using instruction and corresponding sources from github
  2. Use Blue button to set up markers to charts.
  3. Use AWS IoT console MQTT Client to test device subscription to "Nucleo/test". Just publish any message to this topic and serial port output.
  4. PROFIT!

MQTT/MQTTSocket.h

Committer:
PavelSavyhin
Date:
2017-10-19
Revision:
1:042ca9148926
Parent:
0:4cdaf9b1e7d0

File content as of revision 1:042ca9148926:

#if !defined(MQTTSOCKET_H)
#define MQTTSOCKET_H

#include "MQTTmbed.h"
#include "TCPSocket.h"

class MQTTSocket
{
public:

	MQTTSocket(): mysock(true)
	{

	}

    int open(NetworkStack *ipstack)
    {
    	_time_last_ticks = 0;
    	timesock.open(ipstack);
    	return mysock.open(ipstack);
    }

    int getNTPtime(int timeout=1000)
    {
    	int err;
    	int attempts = 0;

    	uint8_t timedata[4];

		timesock.set_timeout(timeout*3);
		do
		{
			err= timesock.connect("time-d.nist.gov", 37);

			if (err != 0)
			{
				LOG("ERROR resolving ntp server IP and connecting to it! \r\n");
				attempts++;
				if (attempts == 3)
					return err;
			}
		} while (err != 0);

		while (err != 4)
		{
			err = timesock.recv((char*)timedata, 4);

			if (err != 4)
			{
				LOG("ERROR receiving time from ntp server! \r\n");
				//return -1;
			}
			else
			{
				///
				/// Time Protocol provides the time as a binary number of seconds since 1900,
				///
				/// 2,208,988,800 corresponds to 00:00  1 Jan 1970 GMT from 12:00:01 am on 1 January 1900 GMT
				///
				_time_last_ticks = ((timedata[0]<<24 )|(timedata[1]<<16)|(timedata[2]<<8)| timedata[3]) - 2208988800ul;

				LOG("Success receiving time from ntp server. Tick from 1 Jan 1970 is equal to %d. \r\n", _time_last_ticks);

			}
		}

		err = timesock.close();

		return err;
    }

    int connect(char* hostname, int port, int timeout=1000)
    {
        int err;

        mysock.set_timeout(timeout);
        err = mysock.connect(hostname, port);  
//    t.start();             
        return err; 
    }

    int read(unsigned char* buffer, int len, int timeout)
    {
        mysock.set_timeout(timeout);        
//t.reset();
// int start = t.read_ms();
        int rc = mysock.recv((char*)buffer, len);
// int stop = t.read_ms();       
//        if (rc>0) printf ("recv File: %s, Line: %d Read nB: %d rc: %d timeout: %d elaps: %d\n\r",__FILE__,__LINE__, len, rc, timeout, stop-start);        
        return rc;
    }
    
    int write(unsigned char* buffer, int len, int timeout)
    {
        mysock.set_timeout(timeout);                
//        mysock.set_blocking(false, timeout);  
//        mysock.set_blocking(false);  
        int rc = mysock.send((char*)buffer, len);
//         printf ("send File: %s, Line: %d Write nB: %d rc: %d\n\r",__FILE__,__LINE__, len, rc);
        return rc;
    }
    
    int disconnect()
    {
//        t.stop();
        return mysock.close();
    }

    inline int getTime()
    {
    	return _time_last_ticks;
    }
     
private:
    TCPSocket mysock; 
    TCPSocket timesock;

    uint32_t _time_last_ticks;
 //   Timer t;
    
};
#endif