Marshal Stout Michael Brooks Nathan Wilson ENGR 329 Team Green February 11, 2009.

Slides:

Advertisements

Similar presentations

Objective - To graph linear equations using the slope and y-intercept.

Advertisements

Slope intercept form of an equation

1 Long Run Cost Here we study the long run.. 2 Long Run Costs Remember the long run is when all inputs are variable. I think it is useful to think of.

Linear Functions and Modeling

Green Team Dustin Fraley DeAndre Strong Stephanie Wilson September 14, 2005 UTC ENGR 329 Speed System.

Voltage Control System: Proportional Integral (PI) Controllers Team Purple: John Pangle Jessica Raymond Justin Whitt ENGR 329 November 30, 2005.

-Pressure System- Root Locus Cory Richardson Dennis To Jamison Linden 6/14/2015, UTC, ENGR-329.

Flow Rate Control System “Step Response Modeling” February 15, 2006 U.T.C. Engineering 329.

Flow Control System Steady State Operation & Step Response February 1 st, 2006 U.T.C. ENGR 329.

Level Team Team Members Note by Dr. Henry: List your team members’ names on this slide.

LEVEL-1 Frequency Response –Experiments –Modeling Jim Henry.

Pressure System Amanda Newman Andy Patel Bryan Cuervo September 28 th 2005 ENGR. 329 UTC Engineering.

Team Green Speed Control - Steady State Performance and Step Response John Barker John Beverly Keith Skiles ENGR 329 UTC 2/1/06.

Red Team Amanda Newman Ankit Patel Bryan Cuervo UTC ENGR 329 Sept. 14, 2005.

Red Team -Pressure- Steady State Operating And Step Response Dennis To Cory Richardson Jamison Linden 6/26/2015, UTC, ENGR-329.

-Pressure System- Frequency Response Cory Richardson Dennis To Jamison Linden 6/27/2015, UTC, ENGR-329.

Pressure Control System: Root Locus Plotting Team Green: X Y Z.

Flow Rate Control System “Frequency Response” By: Taylor Murphy March 1, 2006 U.T.C. Engineering 329.

Team Green John Barker John Beverly Keith Skiles UTC ENGR Steady State and Step Response Performance Speed Control System.

Root Locus Plotting Red Squad Flow System Ben Gordon, Ben Klingler, Dianah Dugan October 31, 2007 University of Tennessee Chattanooga ENGR 329.

Green Team Speed System Proportional Only Controller Design and Experimental Dustin Fraley DeAndre Strong Stephanie Wilson.

B Note from Dr. Henry These slides are suggested to be ADDED to your previous presentation that included system description, diagrams, SSOC, operating.

Flow Rate Control System Proportional Only Controller April 2, 2006 U.T.C. Engineering 329.

~adapted from Walch Education CONSTRUCTING FUNCTIONS FROM GRAPHS AND TABLES.

Yellow Team Spray-Booth Pressure Station Steady, Step Behavior and Step Modeling Jamie West Jay Baker Joel Wood 10/10/11 UTC ENGR 3280L.

Graph the linear function What is the domain and the range of f?

February 22, 2012 What does the slope of a Position vs. Time graph tell us? What does the slope of a Velocity vs. Time graph tell us?

Experimental determination of motor model parameters ETEC6419.

Choose a category. You will be given the answer. You must give the correct question. Click to begin. UNIT 3.

1 Dr. Jerrell T. Stracener EMIS 7370 STAT 5340 Probability and Statistics for Scientists and Engineers Department of Engineering Management, Information.

Functions. Warm Up Solve each equation. 1.2x – 6 = x = X + 29 = x – 5 – 4x = 17 x = 14 x = - 7 x = -15 x = 11.

Lesson 3.2 Topic/ Objective: Comparing linear and nonlinear functions. EQ: How can you tell if a function is linear or not? Linear Functions vs. Nonlinear.

EXAMPLE 1 Find a positive slope Let (x 1, y 1 ) = (–4, 2) = (x 2, y 2 ) = (2, 6). m = y 2 – y 1 x 2 – x 1 6 – 2 2 – (–4) = = = Simplify. Substitute.

2.1.1 Calling Plans day 3 Unit 2: Linear Relationships SWBAT: Compare calling plans by using graphs, tables, and equations.

4.6 Model Direct Variation

GraphsTablesEquationsVocabularyFunctions.

ADD To get next term Have a common difference Arithmetic Sequences Geometric Sequences MULTIPLY to get next term Have a common ratio.

Parent Graphs Family of Graphs. Linear Equations Type your description here.

Writing Rules for Linear Functions. We compared slopes across three different representations – graphs, tables, and in equations. Functions are similar,

Grade 7 Chapter 4 Functions and Linear Equations.

Graphs of a falling object And you. Objective 1: Graph a position –vs- time graph for an object falling from a tall building for 10 seconds Calculate.

Given Slope & y-Intercept

y – y1 = m (x – x1) Point-Slope Form

Input/Output tables.

Objective – To use tables to represent functions.

Graphing Systems of Inequalities.

Linear vs. Nonlinear Functions!

Linear Functions SOL 8.14, SOL 8.16, SOL 8.17.

Chapter 7 Functions and Graphs.

Linear Model Application

Basic Design of PID Controller

Writing Equations in Point-Slope Form

Using the Slope Formula

SYSTEMS OF LINEAR INEQUALITIES

PARENT GRAPH FOR LINEAR EQUATIONS

SLOPE = = = The SLOPE of a line is There are four types of slopes

Left-Handed Locomotive

Jamie West Jay Baker Joel Wood 11/2/11 UTC ENGR 3280L

x-Value = The horizontal value in an ordered pair or input Function = A relation that assigns exactly one value in the range to each.

Write the equation for the following slope and y-intercept:

First-Order System Chapter 5

Jamie West Jay Baker Joel Wood 10/10/11 UTC ENGR 3280L

Y x Linear vs. Non-linear.

Objective- To use an equation to graph the

7.3 Linear Equations and Their Graphs

Point-Slope Form & Graphing

Objective- To graph a relationship in a table.

Students will be able to graph equations of lines.

1: Slope from Equations Y = 8x – 4 B) y = 6 – 7x

Equations & Graphing Algebra 1, Unit 3, Lesson 5.

Presentation transcript:

Marshal Stout Michael Brooks Nathan Wilson ENGR 329 Team Green February 11, 2009

Outline System Background –Description, SSOC, Step Response FOPDT Modeling Experimental vs. Model Results Conclusions

System Background

Steady State Region Steady State Input M(s) Output C(s)

The SSOC

First Order Step Response MJB 01/25

First Order Transfer Function Gain, K Dead Time, t 0 Time Constant,

Experimental Fit Results Table Experimental Fit Results taugaindead Question: Dr. Henry should I include uncertainty here or just let them be shown as they are in the bar graphs?

FOPDT Model Equation Will include the Model parameters for this graph similar to table in previous slide

Input Model Output: Purple Curve Experiment Output: Red Curve Step Up 33% to 66% Input FOPDT Model MJB 02/04 Will Probably OMIT this slide and use the next one

FOPDT Model Model and Experimental Input Overlap Model and Experimental Output Overlap Step Down 66% to 33% Input MJB 02/04

Gain Experimental vs. Model MJB 02/08

Dead Time Experimental vs. Model MJB 02/08

Time Constant Experimental vs. Model MJB 02/08

Conclusions Linear SSOC – Slope represents Gain Reliable Operating Range (0-100) % Small Uncertainties FOPDT Parameters: Model vs. Experimental Similar Similar Uncertainty, relatively small Model shows FOPDT parameter are constant