Download presentation
Presentation is loading. Please wait.
1
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 1 Bruce Mayer, PE Chabot College Mathematics Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege.edu Chabot Mathematics §2.2 Methods of Differentiation
2
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 2 Bruce Mayer, PE Chabot College Mathematics Review § Any QUESTIONS About §2.1 → Intro to Derivatives Any QUESTIONS About HomeWork §2.1 → HW-07 2.1
3
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 3 Bruce Mayer, PE Chabot College Mathematics §2.2 Learning Goals Use the constant multiple rule, sum rule, and power rule to find derivatives Find relative and percentage rates of change Study rectilinear motion and the motion of a projectile http://kmoddl.library. cornell.edu/resource s.php?id=1805
4
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 4 Bruce Mayer, PE Chabot College Mathematics Rule Roster Constant Rule For Any Constant c The Derivative of any Constant is ZERO Prove Using Derivative Definition For f(x) = c Example f(x) =73 By Constant Rule
5
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 5 Bruce Mayer, PE Chabot College Mathematics Rule Roster Power Rule For any constant real number, n Proof by Definition is VERY tedious, So Do a TEST Case instead Let F(x) = x 5 ; then plug into Deriv-Def –The F(x+h) & F(x) –Then: F(x+h) − F(x) 4321
6
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 6 Bruce Mayer, PE Chabot College Mathematics Rule Roster Power Rule Then the Limit for h→0 Finally for n = 5 The Power Rule WILL WORK for every other possible Test Case 0000
7
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 7 Bruce Mayer, PE Chabot College Mathematics MuPAD Code
8
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 8 Bruce Mayer, PE Chabot College Mathematics Rule Roster Constant Multiple Rule For Any Constant c, and Differentiable Function f(x) Proof: Recall from Limit Discussion the Constant Multiplier Property: Thus for the Constant Multiplier
9
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 9 Bruce Mayer, PE Chabot College Mathematics Rule Roster Sum Rule If f(x) and g(x) are Differentiable, then the Derivative of the sum of these functions: Proof: Recall from Limit Discussion the “Sum of Limits” Property
10
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 10 Bruce Mayer, PE Chabot College Mathematics Rule Roster Sum Rule Then by Deriv-Def thus
11
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 11 Bruce Mayer, PE Chabot College Mathematics Derivative Rules Summarized
12
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 12 Bruce Mayer, PE Chabot College Mathematics Derivative Rules Summarized In other words… The derivative of a constant function is zero The derivative of a constant times a function is that constant times the derivative of the function The derivative of the sum or difference of two functions is the sum or difference of the derivative of each function
13
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 13 Bruce Mayer, PE Chabot College Mathematics Derivative Rules: Quick Examples Constant Rule Power Rule Constant Multiple Rule
14
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 14 Bruce Mayer, PE Chabot College Mathematics Example Sum/Diff & Pwr Rule Find df/dx for: SOLUTION Use the Difference & Power Rules (difference rule)
15
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 15 Bruce Mayer, PE Chabot College Mathematics Example Sum/Diff & Pwr Rule Thus (constant multiple rule) (power rule)
16
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 16 Bruce Mayer, PE Chabot College Mathematics RectiLinear (StraightLine) Motion If the position of an Object moving in a Straight Line is described by the function s(t) then: The Object VELOCITY, v(t) The Object ACCELERATION, a(t)
17
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 17 Bruce Mayer, PE Chabot College Mathematics RectiLinear (StraightLine) Motion Note that: The Velocity (or Speed) of the Object is the Rate-of-Change of the Object Position The Acceleration of the Object is the Rate- of-Change of the Object Velocity To Learn MUCH MORE about Rectilinear Motion take Chabot’s PHYS4A Course (it’s very cool)
18
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 18 Bruce Mayer, PE Chabot College Mathematics RectMotion: Positive/Negative For the Position Fcn, s(t) Negative s → object is to LEFT of Zero Position Positive s → object is to RIGHT of Zero Position For the Velocity Fcn, v(t) Negative v → object is moving to the LEFT Positive v → object is moving to the RIGHT For the Acceleration Fcn, a(t) Negative a → object is SLOWING Down Positive a → object is SPEEDING Up 10-9-7-5-313579-10-8-4048-10-26-6102
19
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 19 Bruce Mayer, PE Chabot College Mathematics Example High Diver A High-Diver’s height, in meters, above the surface of a pool t seconds after jumping is given by by Math Model For this situation Determine how quickly diver is rising (or falling) after 0.2 seconds? After 1 second?
20
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 20 Bruce Mayer, PE Chabot College Mathematics Example High Diver SOLUTION Assuming that the Diver Falls Straight Down, this is then a Rect-Mtn Problem In other Words this a Free-Fall Problem Use all of the Derivative rules Discussed previously to Calculate the derivative of the height function
21
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 21 Bruce Mayer, PE Chabot College Mathematics Example High Diver Using Derivative Rules Thus
22
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 22 Bruce Mayer, PE Chabot College Mathematics Example High Diver Use the Derivative fcn for v(t) to find v(0.2s) & v(1s) The POSITIVE velocity indicates that the diver jumps UP at the Dive Start The NEGATIVE velocity indicates that the diver is now FALLING toward the Water
23
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 23 Bruce Mayer, PE Chabot College Mathematics Relative & %-age Rate of Change The Relative Rate of Change of a Quantity Q(z) with Respect to z: The Percentage RoC is simply the Relative Rate of Change Converted to the PerCent Form Recall that 100% of SomeThing is 1 of SomeThing
24
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 24 Bruce Mayer, PE Chabot College Mathematics Relative RoC, a.k.a. Sensitivity Another Name for the Relative Rate of Change is “Sensitivity” Sensitivity is a metric that measures how much a dependent Quantity changes with some change in an InDependent Quantity relative to the BaseLine-Value of the dependent Quantity
25
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 25 Bruce Mayer, PE Chabot College Mathematics MultiVariable Sensitivty Analysis B. Mayer, C. C. Collins, M. Walton, “Transient Analysis of Carrier Gas Saturation in Liquid Source Vapor Generators”, Journal of Vacuum Science Technolgy A, vol. 19, no.1, pp. 329-344, Jan/Feb 2001
26
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 26 Bruce Mayer, PE Chabot College Mathematics Sensitivity: Additional Reading For More Info on Sensitivity see B. Mayer, “Small Signal Analysis of Source Vapor Control Requirements for APCVD”, IEEE Transactions on Semiconductor Manufacturing, vol. 9, no. 3, pp. 344-365, 1996 M. Refai, G. Aral, V. Kudriavtsev, B. Mayer, “Thermal Modeling for APCVD Furnace Calibration Using MATRIXx“, Electrochemical Soc. Proc., vol. 97-9, pp. 308-316, 1997
27
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 27 Bruce Mayer, PE Chabot College Mathematics Example Rice Sensitivity The demand for rice in the USA in 2009 approximately followed the function Where –p ≡ Rice Price in $/Ton –D ≡ Rice Demand in MegaTons Use this Function to find the percentage rate of change in demand for rice in the United States at a price of 500 dollars per ton
28
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 28 Bruce Mayer, PE Chabot College Mathematics Example Rice Sensitivity SOLUTION By %-RoC Definition Calculate RoC at p = 500 Using Derivative Rules
29
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 29 Bruce Mayer, PE Chabot College Mathematics Example Rice Sensitivity Finally evaluate the percentage rate of change in the expression at p=500: In other words, at a price of 500 dollars per ton demand DROPS by 0.1% per unit increase (+$1/ton) in price.
30
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 30 Bruce Mayer, PE Chabot College Mathematics WhiteBoard Work Problems From §2.2 P60 → Rapid Transit P68 → Physical Chemistry
31
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 31 Bruce Mayer, PE Chabot College Mathematics All Done for Today Power Rule Proof A LOT of Missing Steps…
32
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 32 Bruce Mayer, PE Chabot College Mathematics Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege.edu Chabot Mathematics Appendix –
33
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 33 Bruce Mayer, PE Chabot College Mathematics
34
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 34 Bruce Mayer, PE Chabot College Mathematics
35
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 35 Bruce Mayer, PE Chabot College Mathematics
36
BMayer@ChabotCollege.edu MTH15_Lec-07_sec_2-2_Differeniatation-Methods_.pptx 36 Bruce Mayer, PE Chabot College Mathematics
Similar presentations
