S16: Warriors

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Grading Criteria

  • How well is Software & Hardware Design described?
  • How well can this report be used to reproduce this project?
  • Code Quality
  • Overall Report Quality:
    • Software Block Diagrams
    • Hardware Block Diagrams
      Schematic Quality
    • Quality of technical challenges and solutions adopted.

Project Title

WiFi Based Sensor System

Abstract

The most basic aspect of an IoT system is the network of devices/objects. IoT allows objects to be sensed and controlled remotely across existing network infrastructure. This project is based on the same fundamental. SJOne board senses temperature, light intensity, and GPS (SIM800) module. WiFi capability is added to SJOne board using ESP8266 serial module. SJOne(client) transmits the sensor data over the network to the server. Raspberry Pi 3 acts as a server, receives the data from the client and stores it in mysql database. A php webpage takes the most recent entry from database and displays on the webpage along with map.

Objectives

1) Set up sensor hub:

  • Interface GPS module with SJOne
  • Write drivers to access the temperature and light intensity sensors on-board SJOne

2) Set up TCP Client:

  • Interface the WiFi module with SJOne board and implement a TCP client
  • Write device driver to transmit data from SJOne client to the server

3) Set up TCP Server:

  • Use Raspberry Pi 3 to work as a TCP server to receive data from client
  • Create a database to keep a record of previously acquired data

4) Set up Webserver:

  • Start the web server and host a webpage


Team Members & Responsibilities

Ankit Gandhi

--> Software Architecture, Rasberry Pi setup, ESP8266 firmware development

Bharat Khanna

--> Device driver development for SIM808/ESP8266 for ARM microcontroller, PCB designing

Sujeeth Emmadi

--> Software Architecture, Wiki Report, PHP webserver

Veena Manasa Kanakamalla

--> Wiki Report, Sensor interface, Hardware Support

Schedule

This section of the report provides the team schedule for the Assembly line project, indicating the milestones to be achieved during the course of the project.

SI No. Start Date End Date Task Status Actual Completion Date
1 03/21/2016 03/27/2016
  • System design and High level Block diagram
  • Parts and components identification and ordering
Completed
2 03/28/2016 04/03/2016
  • Design of Software Architecture(Flow diagram)
Completed
3 04/04/2016 04/10/2016
  • Device deiver development for I2C(Temperature Sensor) and UART(GPS) communication protocol
  • Testing of individual module
Completed
4 04/11/2016 04/17/2016
  • Device Driver development for ESP8266(Wi-Fi module) on ARM microcontroller
Completed
5 04/18/2016 04/24/2016
  • Socket programming on server(Raspberry Pi) to communicate between microcontroller and server.
Completed
6 04/25/2016 05/01/2016
  • Webserver development on Raspberry PI
Completed
7 05/02/2016 05/08/2016
  • Integration of all modules
Completed
8 05/09/2016 05/15/2016
  • Testing and debugging
Completed
8 05/16/2016 05/22/2016
  • Report writting
In Progress

Parts List & Cost

Item# Part Description Vendor Qty Cost
1 Raspberry Pi Adafruit 1 $39.95
2 ESP8266-Wifi Module Adafruit 1 $9.95
3 SIM808 GPS/GSM Module Adafruit 1 $49.95
4 Passive GPS Antenna uFL Adafruit 1 $3.95
5 USB to TTL Serial Cable Adafruit 1 $9.95

Design & Implementation

System consists of two entities. A client and a server.

System Block Diagram


Cmpe244 warriors blockdiagram.jpg

Components


SJOne Board


SJOne board


  • Built-in Temperature Sensor.
  • Software Stack for Mesh Network.
  • Built-in Light Intensity Sensor.
  • Many GPIOs with two SPI, Multiple UARTs, and I2C availability.
  • Power from USB or External Power.
  • PWM support.


The SJOne board offers whole lot of features out of which the temperature sensor, light intensity sensor and UART interfaces are utilized for the project.




The WiFi Module - ESP8266


ESP8266


The features of ESP8266 are:

  • 1 x Analog input (1.8V max)
  • 9 x GPIO (3.3V logic), which can also be used for I2C or SPI
  • 2 x UART pins
  • 2 x 3-12V power inputs, reset, enable, LDO-disable, 3.3V output


Though it has the option of working on I2C or SPI, we have used UART for integration in our project.



SIM808 GPS Module


SIM808


SIM 808 MiniGSM + GPS, an all-in-one cellular phone module which provides location-tracking, voice, text, SMS and data facilities

  • Quad-band 850/900/1800/1900MHz
  • AT command interface with "auto baud" detection
  • 22 tracking / 66 acquisition channels
  • Sensitivity: Tracking: -165 dBm, Cold starts : -147 dBm
  • Accuracy: approx 2.5 meters




Raspberry Pi 3


Raspberry Pi


  • A 1.2GHz 64-bit quad-core ARMv8 CPU with 1 GB RAM
  • On board 802.11n Wireless LAN
  • 40 GPIO pins and many serial interfaces
  • Micro SD card slot
  • On board chip antenna for radio


The Raspberry Pi 3 is the third generation Raspberry Pi. In this project raspberry pi is used as webserver.


Hardware Interface


The hardware design includes PCB designing using cadsoft Eagle(software for PCB board designing). The circuit design of PCB includes SIM808(GSM/GPS module) and ESP826( Wi-Fi module) which can be connected with ARM cortex-M3 microcontroller and raspberry Pi. Onboard sensors of SJOne board like TEMT6000X01(light sensor) and TMP102(temperature sensor) are also used to collect data. I2C, UART and TCP/IP are the three communication protocols that are being used in the project for establishing communication of temperature/light sensor, SIM808/ESP8266 & raspberry pi with ARM microcontroller respectively.


ESP8266 interface with SJOne


The WiFi module(ESP8266) is interfaced with the SJOne board(ARM microcontroller) using UART3 bus. Pin number p4.28 and p4.29 is used as RX and TX respectively.

SIM808 GPS Module Interface with SJOne


The SIM808 module is interfaced with SJOne using UART protocol. The Transmit and Receive pins of the GPS module are connected to UART2 of SJOne. RX pin of GPS is connected to pin P2.8 of SJOne board (TX) and TX pin of GPS is connected to pin P2.9 of SJOne (RX).

Software Design & Implementation


Client


On the Client side, SJOne(ARM Cortex-M3) is interfaced with the sensors(temperature, light, latitude, longitude, time etc). It collects the data from sensors at regular interval and sends the received data to the server over WiFi.

The client software is written on FreeRTOS using C/C++, including features of real-time embedded system.which is implemented using two tasks

sensorTask

This task takes sensor readings at regular intervals (3 milliseconds) (light, temperature, time, latitude, longitude, and time) and stores in a structure
And then calls the semaphoregive API which signals the high priority WiFi task.


wifitask (High priority task than sensor task)

In the initialization it configures the ESP8266 for WiFi communication and connects to a predefined WiFi network and the server.
Then it waits for the semaphore from sensor task. Once signaled by sensor task, sends the data to the server.


sensorTask() {

readSensorData();
xSemaphoreGive();
delay();
}
wifiTask() {
readSensorData();
xSemaphoreGive();
delay();
}

Server


Raspberry pi is used as TCP and web server. TCP server listens for client connection request, once connected, the reads the data and stores it into MySQL database. Then web server reads the latest sensor values from the database and displays on the web page.

There are two units on server side

TCP server

TCP server connects to TCP client, receives the data and stores into the database.
It is written in C. It uses TCP socket to accept client requests and receive the sensor data.

Web server

Web server reads data from database and display on the web page. It is written in PHP.

Testing & Technical Challenges

  • First and very important step in any project is requirement gathering.
  • A good amount of time should be spent on Software and Hardware design. Once the on paper design is ready it makes the development phase very smooth.
  • Once the development is done testing (individual and as a whole system ) also very important.
  • Wifi client module can be tested usb to serial cable with PC. From PC terminal we can give the AT commands and check the responses. Further testing requires a TCP server, which can respond to the requests. This can be implemented using Hercules utility.
  • GPS module can also be tested in the same manner using usb to serial cable with PC. From PC terminal we can give the AT commands and check the responses.

Issues

#1 LPC17xx UART Rx FIFO

LPC17xx UART not able to receive more than 16 bytes
Resolution :
Used interupt to solve this problem.

Conclusion

The project is based on embedded platform, implementing the concepts of semaphore, Task scheduling, queues etc. Addendum to this we have also implemented features of networking like socket programming and interfacing our output with a user-friendly interface on the web page using Internet of Things. This project helped us in learning a complete embedded application from hardware design till user interface that can be used at a commercial level.

Working on this project has helped us learn many concepts:

  • Setting up TCP server-clients
  • Interfacing sensors using UART
  • Configuration of Interrupts
  • Understanding WiFi technology
  • Making use of AT commands
  • Socket Programming


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Project Source Code

References

Acknowledgement

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References Used

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