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Effective Presentations. Chad A. B. Wilson, Ph.D. Director of Technical Communications Across the Curriculum February 9, 2010. Acoustic Locator. Facilitators: Dr. Trombetta & Dr. Jackson. Team 1: Anh Pham Eric Flores Cheng Du Daniel Febus. September 25,2009.
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Effective Presentations Chad A. B. Wilson, Ph.D. Director of Technical Communications Across the Curriculum February 9, 2010
Acoustic Locator Facilitators: Dr. Trombetta & Dr. Jackson Team 1: Anh Pham Eric Flores Cheng Du Daniel Febus September 25,2009
Direct-Driven Wind Turbine Team 5 Oral Presentation (Student D 09/25/09) Team Members: Truong, David, Quy Ngo, Cristobal Pena, Raghuvar Seth
BLU-LEDPROGRESS REPORT Team 3: Hao Le Andrew Hammen Jianfeng He September 25, 2009
We will learn three things today: How to determine the parts of a presentation How to design presentation slides How to deliver PowerPoint presentations
Time Engineers Spend Communicating source: Survey of 300+ Cornell engr grads, 1950-1992 Other Work Writing 56% 28% Oral Pres 16% source: instruct1.cit.cornell.edu/courses/aep264/LectureOneFeb02.ppt
Presentations in engineering Disadvantages of presentations • One chance to say something correctly • One chance to catch the material • Deal with time constraints • Communicate tomultiple audiences Advantages of presentations • Can make the presentation come alive • Can revise the presentation on the spot • Can use films, slides, and color From Michael Alley’s The Craft of Scientific Writing
The components of a presentation are based on the same principles as the components of written texts • Purpose What is the purpose of a progress report? • Audience Who is the audience for your progress report? • Time You want to consider your
How much time do you have? Never go over time.
The guideline for creating an effective presentation: Tell ‘em what you’re going to tell ‘em, Tell ‘em, Tell ‘em what you told ‘em.
Always tell your audience where your presentation is going. Mapping
Introduction • Determining the parts of the presentation • Designing slides • Delivering the presentation
Introduction • Determining the parts of the presentation • Designing slides • Delivering the presentation
Three things to consider when creating a presentation The components of a presentation Slide design, including balancing the oral and written components of a presentation Presentation delivery
Three things to consider when creating a presentation The parts The slides The delivery
Introduction • Military Applications • Applications for health/medicine • Computer Stuff
Three kinds of applications • Military Applications • Applications for health/medicine • Computer Stuff
Overview of today’s presentation • Military Applications • Applications for health/medicine • Computer Stuff
Overview of today’s presentation • Military Applications • Medical Applications • Computer Applications
Three applications of nanotechnology • Military • Medical • Computer
Three applications of nanotechnology • Military • Medical • Computer
Three applications of nano-technology • Military • Medical • Computer
Three applications of nano-technology Military Medical Computer
Three applications of nano-technology Military Medical Computer
Three applications of nano-technology Military Medical Computer
Three applications of nano-technology Military Medical Computer
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Overview • Project Description/Scope • Technical Aspects • Current Stages • Milestones • Project Schedule • Project Budget
Contents • Introduction • Milestones • Progress Description • Engineering Constraints • Scheduling • Budget • Conclusions
Background & Goal • Technical detail of project: Analog circuit and MCU • Progress of our project • Milestones we are working on & expected accomplished date. • Goal: Construct device that locates direction & distance of sound source from device.
OverView • Purpose : To produce a small wind turbine direct driven power train. • Milestones Accomplished and in Progress • Goals: • 1.Generate power to supply effectively for a Load(Grid) • 2. To Effectively use kinetic energy to charge a 12 volt battery • Engineering Constraints • Schedule & Budget
Overview Cheng Du’s Picture
Incorporate knowledge of the • nature of speech sounds in • measurement of the features. • Utilize rudimentary models of • human perception. • Measure features 100 times per sec. • Use a 25 msec window forfrequency domain analysis. • Include absolute energy and 12 spectral measurements. • Time derivatives to model spectral change. Acoustic Modeling Feature Extraction Fourier Transform Input Speech Cepstral Analysis Perceptual Weighting Time Derivative Time Derivative Delta Energy + Delta Cepstrum Delta-Delta Energy + Delta-Delta Cepstrum Energy + Mel-Spaced Cepstrum From Michael Alley’s website at www.writing.eng.vt.edu
Microwave Power Transmission Horn Antenna Magnetron Simulated Solar Panels KEY DC : μWave : LED Display Rectenna Array
Bluetooth Module Bluetooth BLU-LED Microcontroller Unit University of Houston System Design Team 3 LEDs University of Houston System Design Team 3 Motor
ECE 4436 Robot Requirements Design Deliverable Flash LED’s Measure distance Detect line Assembling parts Record audio Play sound Display message on LCD Electronic Design Grip & carry objects Programming
Milestones • M1: Robot moves and turns • M2: Robot follows a black line • M3: Robot displays distance to the wall on LCD • M4: Robot records and plays sound • M5: Complete robot with printed PCBs, a subroutine library, and a sample set of lab exercises
Progress Description • M1: Robot moves and turns • Order parts • Assemble gearbox, motors, and chassis • Hardware design • Design and implement Motor Driver module • Regulate voltage to 3V from a 6V battery pack • Integrate wireless transceiver • Integrate MCU module (NanoCore12DXC32S) • Software design • Control motors using Pulse Width Modulation (PWM) • Test and debug
Motor Driver Module Figure 1: Diagram of Motor Driver Module
Prototyping Board Figure 2: Prototyping board with MCU and Motor Driver modules integrated
Mechanical Structure Figure 3: Robot chassis, gearbox, motors, and ball caster
PMDF permanent metal deck forms Created by Dr. Todd Helwig, Civil Engineering
Scheduling Gantt chart created by Jonathan Arias Figure 4: Gantt chart
Scheduling [1]