Team #2: Staff Adam Wozniak Barry Gentz Brad LaCount Sean Murphy Russ Diamond BSEE

Team #2: Expertise & Experience Adam Wozniak Barry Gentz Brad LaCount Sean Murphy Russ Diamond Expertise: School Classes, Marketing/Selling Experience: Franchise Owner Expertise: RF Comm, Design, Hazmat safety Experience: USMC Expertise: School classes Experience: None Expertise: Soldering, quality control, programming Experience: Military Aviation Electronics Expertise: Testing, EMI, surface mount, six sigma Experience: JCI

Team #2: Contact Info Adam Wozniak Barry Gentz Brad LaCount Sean Murphy Russ Diamond Phone 1: 262-391-0375 Phone 2: Email: wozniaka@uwm.edu Phone 1: 414-881-9884 Phone 2: Email: gentz.barry@gmail.com Phone 1: 414-935-0421 Phone 2: Email: blacount@uwm.edu Phone 1: 414-426-7865 Phone 2: Email: spmurphy@uwm.edu Phone 1: 414-737-3018 Phone 2: 414-524-7460 Email: diamondr@uwm.edu

Team #2: Weekly Availability Worksheet Adam Wozniak Barry Gentz Brad LaCount Sean Murphy Russ Diamond Time 1: T: Before 9:30am Time 2: T:2pm-6pm Time 3: R: Before 8am Time 4: R: 2pm-7pm Time 1: TR: 8am-11am Time 2: MW: 11am-2pm Time 3: TR: 5:15-6:30pm Time 4: F: anytime Time 1: M: 9am-12pm Time 2: T: 1-4pm Time 3: R: 1-4pm Time 4: F: anytime Time 1: MW: after 3:30pm Time 2: F: after 6pm Time 3: R: 6-7pm Time 4: T: 5-6:30pm Time 1: MW: after 5pm Time 2: MW: 11am-2pm Time 3: F: after 4pm Time 4: TR: after 4pm

Team #2: Weekly Project Meeting Plan Weekly Meeting 1: 3rd Fl Comp Lab, Tuesdays before class Sean, Everybody, work on Project Weekly Meeting 2: 3rd Fl Comp Lab, Thursdays before class Sean, Everybody, work on Project Note: Meeting Owners Send Weekly Email Notices, Record Business-Issues-Actions, Keep Weekly Attendance Records

Team #2: Total Resources 500 Manhours $500 or key part availability for material and prototyping LPI-Sean LSD-Russ LPM-Adam LRM-Brad LMM-Barry

Team #2: Decision Making We will decide any decisions by majority vote

Team #2: Project 1 Project 1 is a remote control car, that can display battery life speed and direction, and can turn on the lights at the flip of a switch or if it gets dark. The benefit to the user would be a better remote control car There are similar types of products, however we are the only one that has all of these features. Our product would fall under the consumer industry Picture from http://www.rccaraction.com/

Team #2: Project 1 Basic Block Diagram CPU for Controller Battery Speed Control Light Switch RF Trans / Rec Directional Control Display CPU for Car Power Source Controller Speed and Direction Indicator Lights Motor Photodiode

Team #2: Project 2 Our second project was a multi-player game that connects through a wireless connection to a main console and it can determine when you made a selection and what selection has been made. This is a good project for us because we have good skills in hardware and programming

Team #2: Project 2 Basic Block Diagram

Team #2: Project 3 Our third project is a kinetic flashlight that doesn’t need batteries. Our features will be that it can also plug into the wall to charge it and it can be remote controlled to turn off and on. This is a good project for us because we have good skills in hardware and programming

Team #2: Project 3 Basic Block Diagram

Our Recommendation Project #1 We chose project 1, because it matched well with our skills in hardware and programming. We also thought it would be a very interesting project. This project meets our interest in communications, power supplies, digital media. This project was unanimously selected by a majority vote.

Our Recommendation The major risks with this project is that it is too complex and we will not get parts of it done in time. The other projects weren’t rejected as much as this project was chosen.

Team #2: Project 1 The remote control car has a two-way antenna that can transmit to and receive data from the car. Control of the car will come from signals from the controller. The car can turn its lights on and off manually, as well as if it gets dark enough. The car will be able to tell us the speed and direction of where it is going, and the battery remaining.

Team #2: Project 1 Block Assignment PCB 1, power supply will be connected to each block User Input [1] Battery signal Digital CPU for Controller Brad [2] Display signal Signals Digital RF1 signal Digital Power Supply [3] Signal Input Barry [4] RF Trans / Rec Sean [5] Display [6] RF2 signal Digital Power supply signal Direction Indicator Digital CPU for Car Russ [7] Light signal Digital Speed and direction Digital Digital Power Source [8] Motor Control[9] Speed Indicator [10] Lights Adam [11] Direction Indicator [12] Direction Control [13] PCB 2, power supply will be connected to all blocks

System - Std Reqs: Market & Business Case Requirement Units to Specify Competitors Market Size Average List Price Market Geography Market Demography Intended Application Material Cost Manufacturing Cost Annual Volume Traxxus, Tra5510 $600 million, website $200 World-Wide 6 yr. old to adult, boys Home, toy $80 / unit $20 / unit 6 million / yr

System - Std Reqs: Env & Safety Requirement Units to Specify Min Oper Temp Range Min Oper Humidity Range Min Oper Alt or Press Range Min Storage Temp Range Min Storage Humidity Range Min Storage Alt or Press Range Max Storage Duration Primary EMC Standards Primary Safety Standards 10-60 Co 0-100% non-condensing 0-3000 Meters 0-100Co 0-100% non-condensing 1 year IEC60601-1-2, EN55011, etc IEC 950, UL2601, etc

System - Std Reqs: Power Interfaces Requirement Units to Specify Energy Source List Source Connection List Min Oper Voltage Range Max Power Consumption Max Energy Consumption Battery (Nimh or Li Ion) Temporary 0-9.0 V and 0-12.0 V 18.0 Watts Total 4600 mAH Total

System - Std Reqs: Mechanical Requirement Units to Specify Max Volume Shipping Container Size Max Mass Elec I/F Connector(s) Max # of PC Bds Max PCB Circuit Area Max Shock 12,000 cm3 18,000 cm3 2 Kilograms Tyco (e.g. IEC320, Nema, etc) 5 100 cm2 Total 50 G force

System - Std Reqs: Mfg & Life Cycle Requirement Units to Specify Max Parts Count Max Unique Parts Count Parts/Mat $ Allocation Asm/Test $ Allocation Product Life, Reliability Full Warranty Period Product Disposition Service Strategy 200 Total Parts 100 Unique Parts $80 (Parts+Mfg=Product Cost) $20 (Parts+Mfg=Product Cost) 3 yrs 6 months Dispose Dispose or Repair

System – Perf Reqs: Power Input(s) Requirement Definition Battery Chemistry Battery Capacity Nicd 4000 mA-Hrs

Requirement Definition System – Perf Reqs: Electrical Functions Requirement Definition Black and White Display 20cm x 10cm 1 meter Lighted LED Display Display size Max. Display Distance Viewing Enviroment

Electrical Signal Req Definition System – Perf Reqs: Electrical Interfaces Electrical Signal Req Definition Analog Signals Digital Signals Signal Direction Speed, Lights, Direction, Controller Lights, Direction, Battery Power Bidirectional

System – Perf Reqs: Operator I/F Outputs Requirement Definition Optical Indicators, Lights Display Type Display Char Matrix Display Size Display Illumination LED, Black and White 7 segment LED 7 Total Char/Row, 2 Total Rows 20cm x 10cm LED

System – Perf Reqs: Operator I/F Inputs Requirement Definition Switch Type Min SNR Max THD Min Power Gain Max Error Voltage Max Delay Min EM Transmission Distance Rotary, push-button, potentiometer 60 dB 1% 80 .25V .005s 300m

Requirement Definition System – Perf Reqs: Mech Interfaces / Safety Requirement Definition Connectors Signal 1 Max Current Limit Signal 1 Max Trip Time Signal 2 Max Current Limit Signal 2 Max Trip Time Max Potential Male pin, female socket .5 Amps .01 s 5 Amps 9 V

Requirement Definition System – Perf Reqs: Modes of Operation Requirement Definition Power Modes Power Saving Modes ON/OFF None