A Project Team Members: Shamlan Albahar Rifaah Alkhamis Doug Bloomquist Chris Deboer What? • Widlife monitoring system – Use wireless sensor network to gather data about wildlife behavior and.
Download ReportTranscript A Project Team Members: Shamlan Albahar Rifaah Alkhamis Doug Bloomquist Chris Deboer What? • Widlife monitoring system – Use wireless sensor network to gather data about wildlife behavior and.
A Project Team Members: Shamlan Albahar Rifaah Alkhamis Doug Bloomquist Chris Deboer What? • Widlife monitoring system – Use wireless sensor network to gather data about wildlife behavior and patterns Why? • Wild life research Reduces cost Better results Less risky • Environmental Impact studies Development projects Construction How? • Movement/Motion • Take photographs • Temperature • Humidity • Light • Geological shocks, GPS, Wind • Perform simple data manipulation and interpretation. Temp = 700F Humidity = 26% Light level = 87% Movement = TRUE Photo Photo Courtesy of Google Maps Key considerations • Size and Cost High number of sensors • Durability Exposed to elements 24 hours a day • Power consumption: Replacement of batteries not viable Battery life >6 months Block Diagram for Wild Thingz Sensors Microcontroller Microcontroller = 1. Required Functionality 1. Collect and package data from camera and sensors 2. Change behavior of sensor based on input from motherboard or environmental conditions 3. Manage power of entire board 2. Constraints 1. Cost 2. Size 3. Speed/Power Block Diagram for Wild Thingz Sensors Radio Microcontroller 1100 1110 0011 1010 Radio 1. Required Functionality 1. Allows a sensor to send its data and to receive instructions from the motherboard 2. Constraints 1. Speed 2. Transmission distance 3. Power consumption Block Diagram for Wild Thingz Sensors Radio Microcontroller Control Control 1. Required Functionality 1. Allow behavior of sensors to be changed 1. Data collection rate, sleep time, transmission power, etc… 2. How will sensors be programmed and initialized? 3. Communication protocol 2. Constraints 1. How interface with sensors for programming? 2. How do sensors receive data and modify their behavior? Block Diagram for Wild Thingz Sensors Radio Microcontroller Control Interface Interface 1. Required Functionality 1. Allows data collected by sensors to be viewed and used 2. Large amount of data should be efficiently processed and displayed 2. Constraints 1. Large amount of data Block Diagram for Wild Thingz Sensors Radio Microcontroller Control Interface Sensors Sensors 1. Required Functionality 1. Images, motion, humidity, temperature, light, shocks, wind, GPS 2. Constraints 1. 2. 3. 4. Size Power Interface with processor (DIO pins) Start up time, turn off time Block Diagram for Wild Thingz Sensors Radio Power Microcontroller Control Interface Sensors Power 1. Required Functionality 1. Batteries 2. Power all components on board 2. Constraints 1. Size, voltage, capacity 2. Temperature 2.45GHz Radio Link JN5139 Module +3.3V Serial + DIO Pins Camera +3.3V Motion +3.3V Light +3.3V Temp +3.3V Humidity +3.3V JN5139 Microcontroller • Operates at low power – CPU processing current consumption at 3.5[mA] 11.55 [mW] – deep sleep current 1.3 [uA] 4.29 [uW]) • Built in radio – Comes with an external antenna, 4km range, and an on board antenna, 1km range • Temperature Operating Range -20° C to 70° C LinkSprite Jpeg Camera • 1.3 Mega Pixel • Power Consumption – Normal Mode Current 100[mA] 0.330 [W] – Runs of 3.3V or 5V • Speed – Baud rate range 9600 to 115200 • RS232 connection to MCU • Output JPEG format • Size of board – 3.2 [cm] by 2.2 [cm] TAOS TSL2550 • Light sensor – Converts light intensity to a digital signal with a two wire Serial Interface • Power Consumption – Active Power 1[mW] – Power Down Mode • Temperature Range – 80 ° C to -40 ° C Sensirion SHT11 • Precise Temperature and Humidity Sensor – Temperature Accuracy +/- 0.5° C @ 25 ° C – Temperature Range -40 ° C to 123.8 ° C – Humidity Accuracy +/- 3.5% RH – Humidity Range 0 to 100% RH • Power Consumption – 30 [uW] PaPIRs (EKMA) • Passive Infrared Motion Sensor with a Polyethylene lens • Electrical Current Consumption – Sleep mode 1[uA] – Standby mode 1.9 [uA] • Detection Range – Max 5m – Horizontal 94° (+/- 47 °) – Vertical 82 ° (+/- 41 °) Power • Li-ion batteries – Prototype will run off of a rechargeable Li-ion 3.0 [V] battery • AAA batteries – Final product will run off of 2 AAA GANTT Chart Milestone 1 Milestone 2 Milestones First Milestone • Initial prototype – – – – Motherboard Sensor unit Initial human interface Wireless communication Second Milestone • Final network – Testing and debugging – Fully functional sensor units and motherboard Mid Range Goals • Three sensor boards, one mother board – Fully functional wireless communication • Ability to send images, sensor data, and receive instructions from mother board • Human Interface – Data processing and display with MatLab – Ability for user to modify behavior of sensor network High Range Goals • Sensors packaged in fully functional, weather proof unit. • Have data gathered by network uploaded onto website • Integration of additional sensors – GPS, wind, geological shocks • Environment model built in lab for demo day Risks and contingency plan • Testing expensive components • Unfamiliar Technology : Programming the camera • • • • Schedule uncertainty Ability to transmit data Unclear photos at night Testing in lab and real life Division of Labor and responsibility Task Programming: -Hardware (Microcontroller, camera,…) - Human Interface Hardware Development: -Selection of components -Circuit board layout Data Processing: -Data algorithms - Classification Testing, Debugging and Documentation for project Primary Secondary Cost Estimation Item Quantity Cost estimate PCBs 3 $ 105 JN5139 Module 3 $ 84.66 LinkSprite Camera 3 $ 150.00 Temp & humid sensor 2 $ 71.98 Light sensor 2 $ 6.98 Motion sensor 2 $ 53.32 Packaging 2 $ 40 Miscellaneous parts - $150 Presentation expenses - $ 100 Total estimated cost $ 761 Questions?