Difference between revisions of "2007 TE Session Outline"
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===Programming=== | ===Programming=== | ||
Date: 11/06/2007 | Date: 11/06/2007 | ||
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+ | 1. How to upload code to the RC (using both easy C and MPLab) | ||
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+ | 2. Instruction following activity | ||
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+ | 3. Flowcharting | ||
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+ | 4. State machines | ||
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+ | 5. Pseudocode | ||
===Success in FIRST / Cookout=== | ===Success in FIRST / Cookout=== |
Revision as of 09:05, 26 July 2007
This is the outline for both the 2007 basic and advanced Technology Enrichment sessions.
Contents
Basic Sessions
These sessions are geared to new students and new teams.
Introduction
Date: 09/11/2007
- Welcome to 2007 TE Sessions and to Tech
- Info about RoboJackets
- Key people and contacts during the sessions
- Info about sponsors
- Info about this year vs. last year
- Show them where to get power points and materials on our site
- On our website in TE sessions (there will be a page for materials and such)
- What is a robot
- Types
- Robots in real life
- Applications
- Commercial / Industrial
- Roomba
- Kuka
- Government / Military
- Samsungs Sentry in the DMZ
- UAV's border patrol, communication, traffic reports
- Bomb defusing
- Rescue
- Research
- DARPA
- NASA
- Telescopes
- Robotics at tech
- Borg Lab
- RIM
- GTRI
- UAV Lab
- others
- Our robots
- Candi
- 1 or 2 RoboCup
- Commercial / Industrial
- Applications
- Vex Competition
- Announcement of competition
- Building toward our in-house competition
- End of TE Session Competition
- FIRST Vex Competition
- End with our goals and aspirations
- Take questions
Intro to Mechanical Engineering
Date: 09/18/2007 1. Force Balances
a. MATERIALS NEEDED: 1. Arrow shaped force applicators 2. pop can and weights 3. spring steel strips and fixtures 4. thin aluminum strips 5. plastic strips 6. poorly built box 7. strong box 8. Working Model demos b. Basics i. Gravity (2 slides) ii. equations F=sum(ma¬¬i) 2 slides iii. examples 1. pictures of point masses 2. pictures of airplane 3. crush a pop can c. Stresses i. Bending (4 slides) 1. one point 2. multiple point ii. Material basics (2 slides) 1. steel vs. aluminum 2. plastics and other iii. Examples 1. spring steel mounted in different ways 2. aluminum fatigue 3. plastic bending d. Building a decent box i. Working Model™ demos of bad designs ii. Shear loads (3 slides) 1. square with side loads on top 2. corner loads 3. triangles help! iii. Fastening (2 slides) e. Activity i. Build a box with VEX kit material 1. focus on strength and weight ii. Box should be strong enough to put entire VEX kit on top and resist side loading
2. Rotation
a. MATERIALS NEEDED 1. Wheels 2. Shafts 3. Bearing setup 4. Bushing setup 5. Shaft collars 6. VEX demo b. Bearings vs. Bushings 1. Wheel setups (4 slides) a. Overhanging loads b. Centered loads c. Should wheels spin on shaft? d. Should shaft spin in housing? 2. Types of bearings (2 slides) a. Radial b. Thrust 3. Forces bearings can resist (2 slides) a. Speed b. Loading 4. Bushing Applications (3 slides) a. Slow moving rotations b. Radial and thrust c. Materials 5. Shaft Restraint (3 slides) a. Set screws b. Shaft Collars c. Nuts c. VEX kit examples c. Making square shafts spin in round holes (2 slides) 1. Intro to VEX parts 2. Physical examples d. Activity i. Put wheels on your box to transport a load ii. See if your box can support load while accelerating/decelerating to demonstrate dynamic loading. iii. Put wheels on sides too, to test overall robustness of design
Mechanical Power Transmission
Date: 09/25/2007
- What is power
- Physics
- Work x time = force x velocity
- Idea
- Make your motors useful
- Physics
- Mechanisms
- Gears
- How they work
- Teeth
- Pitch diameter
- How they work
- Ratio
- What it means
- How to calculate
- Teeth to teeth
- Belts
- Types
- V Belt
- Timing Belt
- How they work
- V Belt - Fits in a wheel that has groove
- Timing belt - Have notches
- Goal when using keep as much contact as possible between belt and wheel (sort of)
- How to calculate
- Diameter to diameter
- Types
- Chains and Sprockets
- How they work
- Links
- Master links
- Numbering (what it means)
- Standard sizes (lengths etc)
- Goal when using ...
- Big v. Small
- Big
- Stronger
- Less efficient
- Small
- Weaker
- More efficient
- Big
- How to calculate
- Diameter to diameter
- How they work
- Pulleys
- How they work
- Special
- Rack and Pinion
- How they work
- Worm Gears
- How they work
- Rack and Pinion
- Gears
- Advantages and Disadvantages of each
- Gears
- Weight
- You will be reducing them
- Location
- Motor is close to output
- Easier to work with
- Don't have to tension
- Weight
- Belts
- Tensioning
- Location
- Motor can be much farther away from output
- Weight
- Don't need to remove mass
- Skipping
- Chains
- Tensioning
- Location
- Motor can be much farther away from output
- Slack
- Less efficient than gears
- Weight
- Don’t need to remove mass
- Special
- Rack and Pinion
- Linear motion
- Worm Gears
- High torque
- Cant back drive (in theory but teeth can break...)
- High torque
- Rack and Pinion
- Gears
- Demos
- Gears
- C4's Gearbox and Lego Demo
- Belts
- C4’s Panning Turret (ghetto)
- Chains
- C4's drive module
- Pulleys
- ?
- Special
- Rack and Pinion
- Lego
- Worm
- Lego
- Rack and Pinion
- Gears
- Activities
- Build a gear box with a ratio of X (lego)
- Allow groups to come up and see C4’s various aspects.
- ??
- What to expect
- A combination of these on your bot (not just one)
- Be prepared to chop of some weight
Drive Types
Date: 10/02/2007
- Methods of motion
- Tank
- Swerve / Ackerman
- Swerve / Crab
- Omni
- Mecanum
- Advantages and Disadvantages of each
- Tank
- Advantages
- mechanically simple
- saves space
- zero turning radius
- high traction
- Disadvantages
- more turning effort/traction tradeoff
- single axis of motion
- Advantages
- Swerve / Ackerman
- Advantages
- mechanically simple
- low turning effort
- high traction
- Disadvantages
- large turning radius
- difficult to power all wheels
- Advantages
- Swerve / Crab
- Advantages
- Multi-axis motion
- zero turning radius
- high traction
- low turning effort
- Disadvantages
- complex control
- mechanically complex
- Advantages
- Omni drive
- Advantages
- mechanically simple
- zero turning radius
- multi-axis motion
- Disadvantages
- low traction
- complex controls
- expensive parts
- Advantages
- Mecanum
- Advantages
- mechanically simple (uses tank setup)
- zero turning radius
- multi-axis motion
- higher traction than omni drive
- Disadvantages
- complex controls
- expensive parts
- Advantages
- Tank
- Demos (during presentation)
- RC Cars
- Robocup bases / video
- Mecanum forklift video
- Activities
- Drive demo vehicles through maze (time trials)
Manipulation
Date: 10/09/2007
- Arms
- Types
- single bar
- parallel bar
- telescoping
- Reach
- single joint range of motion (angular and linear)
- workspace (several joints)
- Stability
- Center of gravity
- static balance
- dynamic balance
- Types
- Conveyors
- Belts / rollers
- single / double belt systems
- enclosed conveyor system
- Belts / rollers
- Demos
- Hand crank powered conveyors
- Unpowered linkages and joints
- Activities
Manufacturing and Safety
Date: 10/16/2007
- Design Tools
- Brainstorming
- Strategy
- Idea cloud
- Function tree
- Organizes possible robot functions during competition
- Robot designs
- Morphological chart
- Strategy
- Evaluation
- Objective weighting based on strategy
- Evaluation table
- considers importance of robot characteristics based on selected strategy
- Machinability (6 slides)
- Design parts that can be made
- Design parts to fit available materials
- Show design of one part
- Show manufacturable design of same part
- Drafting (5 slides)
- Importance of drawing accurately and well
- Drafting basics (dimensions and linetypes)
- CAD, why its good
- Proper dimensioning
- Demo of poorly drafted part
- Weight (3 slides)
- Weight removal
- Material selection
- Shape and weight considerations
- Building Successful Machines
- Technical Drawing
- Last step before fabrication
- Can use anything from simensioned sketchees to 3D models
- Important to shot not only individual part dimensions but also how it fits into the overall design
- Brainstorming
Safety and Fabrication
- MATERIALS NEEDED:
- Old pair of safety glasses
- Ear protection
- Gloves
- Machined parts that demonstrate topics
- Safety
- Glasses (4 slides)
- Reasons to wear
- Times to wear
- Glasses vs. face shields
- Welding
- Demo (Pair of damaged glasses)
- Clothing and hair (3 slides)
- Shoes and shirts
- Pull hair back
- Gloves and types
- Ear protection (2 slides)
- Types
- Hazards
- Pass around different types
- Chemicals (3 slides)
- Paint and solvents
- Dust masks
- Gloves and skin protection
- Machinery dangers (4 slides)
- Don’t touch drill bits and moving parts
- Pinch points
- Parts may be hot
- Fixturing parts properly
- First Aid (3 slides)
- When to call for help & first aid kits
- Bleeding & Shock
- Broken bones & Falls
- Glasses (4 slides)
- Fabrication
- Drilling (6 slides) +video
- Use lubricants
- Proper speed for material
- Battery drills vs drill press
- Drill holes oversized for bolts
- Material thickness and chip removal
- Safety
- Cutting (7 slides) +videos
- Powered vs. manual
- Workpiece Material
- Bandsaws
- Rotary saws
- Hacksaws
- Milling
- Safety
- Grinding (7 slides) +video
- Reasons to grind
- Grinders
- Material removal is slow
- Heat buildup
- Grinding disc types
- Aluminum and steel
- Safety
- Milling and Turning (7 slides) + video
- Reasons to use mill or lathe
- CNC machining
- Precision
- Bits
- Show different bits and the cuts they produce
- Show lathed parts
- Safety
- Tapping (5 slides) + video
- Reasons to tap
- Tap sizes
- Material
- Tapping procedures
- Safety
- Drilling (6 slides) +video
- Activity
- Thoroughly design a complex device for manufacture.
- Draw pieces out by hand
- Describe fabrication processes involved
Pneumatic / Fluid Power
Date: 10/23/2007 Mechanical Energy Storage
- Materials Needed
- Springs
- Steel balls
- Plastic balls
- Flywheel setup
- Pneumatic demos
- Materials Needed
- Energy
- Definitions (4 slides)
- Energy direction
- Kinetic E=1/2mv2 E=1/2Iw2
- Potential E=mgh = 1/2kx2 =pdV
- Dissipative E=something about friction heat
- Blow up and deflate a balloon
- Kinetic (3 slides)
- Mass vs. speed
- Spinning
- Falling
- Demos
- Potential (3 slides)
- Springs
- Height and gravity
- Falling
- Demos
- Dissipative (3 slides)
- Friction is everywhere
- Reduce or rely on it
- Demos
- Bring all 3 energy types together (1 slide)
- Example of ball rolling up and down
- Demo
- Definitions (4 slides)
- Activity
- Use Vex kit to fling something
- Do one with just potential and one with kinetic
- Hand out some springs
- Fluid Power
- Dr. Book and Dr. Paredis lecture
- Activity
- Use Vex kit and pneumatics to fling something
- Hand out cylinder and storage tank and sol. valve
Electrical Power
Date: 10/30/2007
Programming
Date: 11/06/2007
1. How to upload code to the RC (using both easy C and MPLab)
2. Instruction following activity
3. Flowcharting
4. State machines
5. Pseudocode
Success in FIRST / Cookout
Date: 11/10/2007
- Project Management
- Raising Interest
- Raising Funds
- corporate sponsorship
- generic HS fundraisers
- Team organization
- Teachers
- Parents
- Mentors
- Students
- Building a robot
- preseason development
- students
- ideas
- prototypes
- Build season schedule
- Generic layout (kickoff to ship)
- Team specific considerations
- Cash flow
- what money do you have when
- Suppliers and purchase procedures
- lead time for purchases due to school procedures
- outsourced machining time
- Student responsibilities
- overlapping responsibilities
- Cash flow
- preseason development
- About kickoff (reminders and Q/A if possible)
- About scrimmage (reminders and Q/A if possible)
- About Peachtree (reminders and Q/A if possible)
Advanced Sessions
Technical Design
Date:
- CAD vs. Solid modeler
- Autodesk AutoCAD
- Eagle CAD
- Autodesk Inventor
- UGS Solid Edge
- Dassult Systems CATIA
- Reading technical drawings
- Multi views
- Isometrics
- Properly dimensioned vs. bad
- Basics of Autodesk Inventor
- How to make a part
- Constraining sketches
- Extrusions / Cuts
- Holes
- Importance of placing holes for bolts
- Assembly
- Mating / Constraining
- Projecting geometry
- Output a drawing
- 3 view
- Placing dimensions
- What a machine shop might want from you
- How to make a part
Motor Control
Date:
- Selecting Motors
- Motor Specifications
- A Little Math
- Some of the terminology and why its important
- Sinusoidal Functions and the Complex Domain
- A little trig and why its important
- Sin, Cos, and polar coordinates frame and their relations
- Describing Sinusoidal Signals as phasors
- Systems of Equations
- Representing Equations as matrices
- Using rank to determine if a system is solvable
- Methods for solving systems of equations
- Gaussian Elimination
- Row Echelon
- Brute Force
- Matlab
- Calculus
- Derivatives
- Graphical interpretation
- The easy approximation (Change in one variable over change in another)
- The actual way (That equations)
- That Equation
- Power Rule
- Substitution
- The way your computer does it
- Derivatives
- Integrals
- Geometric Interpretation
- Rieman Sums Approximation
- The way your computer does it
- Signals And Systems
- Frequency Response and the Frequency Domain
- Analyzing Systems
- Time Domain (differential equations)
- Frequency Domain (algrebra)
- Taking a function to the Frequency Domain
- Laplace Transform (Continuous) Z-Transform (Discrete)
- Simpler ways to do transforms (Tables)
- Frequency Response
- Gain and Phase plots
- Analyzing Systems
- Filters
- Types Low-Pass High-Pass Band-Pass All-Pass No-Pass Notch
- RC Filters
- Active Filters
- Amplification and Attenuation
- Op-Amps
- Other Signal Operations
- Mixing Addition and Subtraction of sinusoids
- Signals and Systems in Discrete Time
- A/D Conversion
- Aliasing
- Factors Affecting Sample Rate
- Frequency Response and the Frequency Domain
- Linear Control
- What to we mean by Control?
- Open Loop vs Closed Loop
- Stability
- Achieving Stability I
- Achieving Stability II (Solutions in State Space)
- Switched Systems (Achieving Stability for Systems that Switch Control Schemes)
- What to we mean by Control?
- Realizing Control Systems
- How Do We Control Real Motors?
- Sensing
- Implementing a closed-loop PID control
- Demo and Assignment
- Demo using Processing
- Simulink Demonstration
- WiFi signal tracker in one dimension
Adv. Mechanical Power Transmission
Date:
Topics in Autonomous Control
Date:
Machine Vision
Date:
Manipulation
Date: and (2 weeks)
Week 1:
Dr. Lipkin’s slides
- 1. Intro to manipulators
- a. Serial
- b. Parallel
- c. Grippers
- d. Wheeled
- 2. Serial Analysis
- a. RRR Manipulator
- i. Workspace
- ii. Angles
- iii. Singularities
- iv. Demo unpowered RRR linkages
- b. RPR Manipulators
- i. Workspace
- ii. Angles
- iii. Singularities
- iv. Demo unpowered RRP, RPR, PRR linkages
- a. RRR Manipulator
- 3. Activity
- a. Design a manipulator to reach something and so something with it
Week 2:
Manipulator fabrication
- 1. RPR Manipulator
- a. Last year’s FIRST robot
- b. Actuation types
- i. Electric Motors
- ii. Pneumatics
- iii. Hydraulics
- iv. Advantages and Disadvantages
- v. Demos
- c. Design
- i. Base Rotation
- 1. Chain drive
- a. Benefits
- b. Problems
- 2. Motor Selection
- 3. Position control
- 1. Chain drive
- ii. First link elevation
- 1. Cable drive
- a. Benefits
- b. Problems
- 2. Material
- 3. Position control
- 1. Cable drive
- iii. Extension
- 1. Belt drive
- a. Benefits
- b. Problems
- 2. Motor Selection
- 3. Position control
- 4. Material
- 1. Belt drive
- iv. Wrist
- 1. Gear drive
- a. Benefits
- b. Problems
- 2. Position control
- 3. Design
- 1. Gear drive
- v. Gripper
- 1. Pneumatic
- a. Benefits
- b. Problems
- 2. Position control
- 3. Design
- 1. Pneumatic
- d. Demos
- e. Activities
- i. Base Rotation