Difference between revisions of "S14: Android based home monitoring system"

Revision as of 21:14, 22 May 2014

Grading Criteria

Android based home monitoring system

Abstract

The home monitoring system is designed to monitor light and temperature of different rooms. The monitoring system will monitor light and temperature of different rooms and report the status to the user via an android application.

Features

1. Light and temperature monitoring of multiple rooms
2. Android application to view status of sensors

Team Members

1. Om Narasimhan
   • Software design and Android App development
2. Aysha Malik
   • Hardware interface design and integration
3. Sri Latha Ayyannagari
   • FreeRTOS driver design and development

Schedule

Parts List & Cost

Design & Implementation

The project was completed in a number of steps

1. Device driver development

2. Android Application development

Hardware Design

Fig 1. Bluetooth module

Basic Bluetooth module (JY-MCU HC-06) was purchased from ebay for $8 including shipping. This particular series (HC-06) has four pins RX, TX, VCC and GND and can only work in slave mode. The module specification mentions that the module can be reprogrammed, but the KEY and STATE pins are not available in this series (HC-06).

Note: Although VCC pin indicates that the module works with 3.6-6V, connecting it to the LPC1758 3.3V output worked fine.

Hardware Interface

This project uses UART2 for communication.The default setting for UART is: Baud Rate - 9600, no parity, one start bit and one stop bit.

Software Design

Fig 3. Android application flowchart

Parameters are monitored by devices placed in each room. The monitoring device communicates to android application using Bluetooth. The application records incoming data from different devices and continuously analyses it. Interpretation of the data can either be done in real time or at fixed intervals and logical decisions are taken (e.g, no motion sensor update for X minutes, so switch off lights, or based on the historical data, switch on lights at a particular time ..etc)

In this project software design has two components: device driver and android application.

Figures (Fig 3 and Fig 4 )give an overview of the individual components.

Fig 4. Device driver flowchart

• Android application is implemented in three parts:

1. Start Screen

• Enable Bluetooth
• Upon selection of Room connect to the corresponding device

2. Communication Screen

• Once connection is established, status is shown as connected or a message “connection failed”
• Send characters for information request and display incoming data

Current Temperature

Temperature History

Current Lumosity

Lumosity History

3. Graphing Screen

• Plot the requested weather data.

• Free RTOS application is implemented in two parts

1. Data Structure

• Every board gathers temperature and Luminosity samples at fixed intervals. The interval is configurable and was set at 5sec

2. Data gathering and transfer Protocol

Android application development

Fig 5. Android SDK manager

First thing to do before application development is to install the tools needed. We downloaded the Android SDK and followed the instructions for tool setup in this tutorial. (https://developer.android.com/sdk/index.html) Second thing to get started on android development is to understand the android development environment we used this tutorial (https://developer.android.com/training/index.html) for building and run the first application.

It is very hard for anyone without the knowledge of Java and Xml to write an application from scratch. For this reason we used the Bluetooth Chat sample code provided in the Android SDK package as a starting point for this project.

Application GUI

Start app development by changing the main.xml file to add buttons as seen in the layout in figure(10) , add the corresponding stings in the string.xml file. This project uses the buttons to send a particular character when clicked. To do this change the BluetoothChat.java file as follows by adding the following lines of code in the setupChat() function.

● The first screen for application is for home station selection

Fig 7. Select parameter

As you can see in the screen shot, there are three buttons to select among three home stations. Upon selecting a weather station (denoted by “roomX”, X => 1, 2, and 3), the application establishes a connection to the Bluetooth agent in the weather station. Once connection is established, the status is shown to the user as “connection established” or “connection failed”

Fig 6. First Screen

● There are 4 different buttons viz,

Temperature Now (Read the current temperature) History (Historical temperature data and graphs)

Light Now (Read the current luminosity) History (Historical luminosity data and graphs)

● Graphing method

Fig 12. XYplotcode

Our graphics are primarily based on the library “androidplot” downloadable from (www.androidplot.com)

AndroidPlot is a very powerful package to plot graphs. The input for graphing method are two arrays of type Number. To plot an XY graph, these numbers are converted to XY-Series data type and use a LineandPointFormatter class. Once X-axis plane is fully plotted, another series will be used to plot Y- axis plane.

Application configuration

In main, we have instantiated two variables (one for Temperature and another for Luminosity) of type data_buffer with a buffer size 100 entries. We setup a thread to read the sensors at periodic intervals and fill into the corresponding buffers. By virtue of our data structure, maximum space allocated for readings are bound at the init time.

Data Analysis

The gather_tmplight() thread wakes up at intervals and fills in the data into the buffer. The Android app can query any device either for a. Last wrote data, or b. Complete history (upto 100 entries).

Data structures

Fig 10. Data structures

Every board gathers temperature and Luminosity samples at fixed intervals. The interval is configurable and default is set at 5sec. Initially, our first choice was to use a FIFO for storing these readings. But then, it became very difficult to discard older entries. Although we planned to have a timeout mechanism associated with every entry, later we figured out that a FIFO implementation based on a circular buffer would be easier to implement and maintain.

Fig 11. Circular buffer

Here is a graphical representation of our FIFO based on a circular buffer.

Communication protocol

The transaction is carried out using the following protocol:

Implementation

The sample code is downloaded using the Android SDK Manager. From the navigation menu of the IDE go to Windows -> Android SDK Manager. All the installed and available SDK packages are listed; attention should be paid to the version of SDK platform. It should be the same as the Android version of your device. This project is developed using Android 4.2.2.(kitkat), API level 19. After this sample code can be found in the folder sdk->samples->android-19->legacy on the host machine. Import the Bluetooth Chat sample in to the project workspace.

Fig 8. BluetoothChatService

Next step is to establish communication with the LPC1758 using Bluetooth Chat sample application. Bluetooth sample is not a functioning application; this tutorial (http://www.instructables.com/id/Android-talks-to-Arduino/?ALLSTEPS) provided the solution to the problem. It said to change the UUID in BluetoothChatService.java file to “00001101-0000-1000-8000-00805F9B34FB”

Fig 9. Setupuart

Once the change is made this application is able to communicate with LPC1758. In this project android application is composed of three activities: BluetoothChat.java, Avtivity_main.java and SampleXYPlotActivity.java.

Testing & Technical Challenges

Testing

Install the app BlueTerm on your android device. This app is a terminal emulator, and uses RFCOMM/SPP protocol for serial communication over Bluetooth. It is used to establish connection between LPC1758 and android device. The JY-MCU Bluetooth module appears as linvor in the available device list. Once the connection is established send a character from LPC1758 using Hercules, you should now be able to see the character appear on the terminal. Now send a character from the android device and it should appear on the Hercules terminal. This verifies the communication between LPC1258 and android device.

Challenges

Data structures implementation: Initially we toyed with the idea of every reading will be stored with a timeout value. But soon it became apparent that it is not a scalable solution. So, we searched for an alternative and finally came up with a Circular Buffer based FIFO. Initially we tried storing both temperature and luminosity in the same data structure. But later it became so cumbersome that we decided to simplify code using two separate instances of the same data structure. Graph plotting was considered difficult till we came across Androidplot libraries.

Difficulty with testing: The state machine designed was to wait till a suitable input. In order to simplify testing, we implemented a command (to be input from the prompt) using a terminal task. Thus, by connecting uart2 to uart3 we could independently verify the functionality of the device – by reading the temperature value and history as well as Luminosity value and history.

Conclusion

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References

Acknowledgement

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References Used

Appendix

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