MAT2500 12S [jantzen] homework and daily class log

Your homework will appear here each day as it is assigned, with occasional links to some MAPLE worksheets when helpful to illustrate some points where technology can be useful. [There are 56 class days in the semester, numbered consecutively below and  labeled by the (first initial of the) day of the week.] Usually it will be summarized on the white board in class, but if not, it is your responsibility to check it here. You are responsible for any hyperlinked material here as well as requesting any handouts or returned tests or quizzes from classes you missed. Homework is understood to be done by the  next class meeting (unless that class is a test).


Textbook technology: Red numbered homework problems have hints on the textbook [7e Early Transcendentals] website TEC site, which also has tutorials and on-line quizzes and web extras. You just need to do a short Java software install on your laptop first to use it.

1. T (January 17, 2011): GETTING STARTED STUFF. By Friday, January 20, e-mail me [robert.jantzen@villanova.edu] from your OFFICIAL Villanova e-mail account (which identifies you with your full name) with the subject heading "[mat2500]", telling about your last math courses, your comfort level with graphing calculators and computers and math itself, [for sophomores only] how much experience you have with Maple (and Mathcad if appropriate) so far, why you chose your major, etc, anything you want to let me know about yourself. Tell me what your previous math course was named (Mat1500 = Calc 1, Mat1505 = Calc 2, Mat2705 = DEwLA).
   HINT: Just reply to the welcome email I sent you before classes started.
   [In ALL email to me, include the string "mat2500" somewhere in the subject heading if you want me to read it. I filter my email.]
   
   On your laptop if you brought it:
   1) Open Internet Explorer or your favorite browser. (You can open Maple files linked to web pages automatically if Maple is installed on your computer.)
   2) Log in to MyNova on the Villanova home page in Internet Explorer (click on the upper right "login" icon and use your standard VU email username and password) and check out our class photo roster, and visit the link to my course homepage from it by clicking on my home page URL under my photo and then on our class homepage, directly (better yet, right click on the link and open it in another tab to get rid of all that MyNova crap at the top of the window!):
   [ http://www.homepage.villanova.edu/robert.jantzen/courses/mat2500/ ],
   3) Open Maple 15 Standard or Maple 14 if you already have it by clicking on this maple file link: equianglespiralshell.mw] [Duke website]
   4) bob will quickly show you the computer environment supporting our class.
   [maybe he will try to impress you with this gee whizz! Maple video; naahh...we'll leave this only to the curious among us.]
   
   During class in the first part of the semester, a signup sheet will be passed around for your signature. Make sure you sign at the end if it bypasses you. Today please correct your nickname to be used in class if not the obvious one, and include your cell phone number and 3 letter dorm abbreviation (list given on the reverse side of the paper schedule sheet you received).
   
   Afterclass:
   5) log on to My Nova, choose the Student tab, and go to BlackBoard and look at the Grade book for our course: you will find all your Quiz, Test and Maple grades here during the semester once there is something to post.
   [This is the only part of BlackBoard we will use this semester.]
   In the Student Tab, click on the double person icon to the right of our class line to get to our photo class roster [look at the photo class roster to identify your neighbors in class!]
   and click on my home page URL under my photo. Click on our class URL there. Check out the on-line links describing aspects of the course (no need yet to look at the MAPLE stuff).
   [You can drop by my office St Aug 370 (third floor, Mendel side, by side stairwell) to talk with me about the course if you wish and to see where you can find me in the future when you need to.]
   
   6) Download Maple 15 if you haven't already done so and install it on your laptop when you get a chance (it takes about 15 minutes, do the update too please, only an extra couple minutes, I will help you in my office if you wish, Mac users can install in my office). If you have any trouble, email me with an explanation of the errors.
   [You can always access and open Maple 15 Standard in citrixweb on any Windows computer anywhere through Internet Explorer but the first time you use citrix on a computer, you must download and install the client from the link on that web page, but the local copy of Maple is preferable, especially for printing purposes.]
   You are expected to be able to use Maple on your laptop when needed. We will develop the experience as we go. No problem if you never used it before.
   
   7) Read computer classroom /laptop etiquette.
   
   8) Homework Problems: 12.1: 1, 2, 3, 5 (short list so you can check out our class website and read about the course rules, advice, bob FAQ, etc, respond with your email; freshmen who do not yet have the book: handouts/stewart6e_12-1.pdf). It is important that you read the section in the book from which homework problems have been selected before attempting them. Here is an example of a PDF problem solution: Stewart 12.1.42 [Okay, I cheated and looked at the solution manual to see how to get started. Then I made a nice Maple worksheet of the problem, just to have an example of a Maple worksheet to show you. Don't worry, we will take it slow with Maple.]
   It is important that you read the section in the book from which homework problems have been selected before attempting them.
   
   9) Fill out the paper schedule form bob handed out in class. [see handouts];  use the 3 letter dorm abbreviations to return in class the next class day. Block out your time slots, identify by name of course like MAT2500.
    
2. W: handout on diff/int/algebra;
   return your schedule forms at the beginning of class;
   check phone number, dorm info on daily signup sheet;
   check out the textbook website homework hints (Calculus, Early Trancendentals) and extras;
   12.1:  11, 13, 15, 19a [hint: show the distance from P₁ to M is the same as from P₂ to M and equal to half the total distance; this is the hard way with points and not vectors],
   21a, 23, 33, 37;
   12.2: 1, 2, 3, 5, 7, 9, 13, 15, 19, 21, 25.  
    
3. F:  handout on course rules, syllabus;
   12.2: vector diagram problems [numbers for example 7];
   34 (draw a picture, express the components of each vector, add them exactly (symbolically), evaluate to decimal numbers, think significant digits),
   37 (tension result given in units of force; vertical component balances downward gravitational force F = mg, g = 9.8 N/kg, where m = 0.8kg) [pdf,.mw],
   45.
   
   WEEK 2[-1]:
4. M: Review ends, now we start new material: vector geometry beginning with the dot product;
   12.3: [example 3];
   1, 3, 5, 9, 11, 15, 21 (it is enough practice to find just one angle), 23, 33;
   optional fun problems if you like math: 55 (geometry [pdf,.mw]), 57 (chemical geometry [.mw]).
    
5. T: handout on resolving a vector [using Maple (for dot and cross products and projection)];
   12.3: 39, 45, 46 [ans: b_perp = orth_a b = <1.18,-0.29>], 49.
    
6. W: cross product; 
   12.4: [crossprodetails.pdf];
   1, 5, 8, 11, 15 (move u right so initial points coincide), 16,
   19, 21, 27 (find 2 edge vectors from a mutual corner first, use 3 vectors and cross product),
   31 (Maple example: trianglearea.mw),
   33, 35, 37 (zero triple scalar product => zero volume => coplanar),
   39 (first redo diagram with same initial points for F and r).
   
   > <2,1,1> · (<1,-1,2> × <0,-2,3>)  
   [boldface "times" sign and boldface centered "dot" from Common Symbols palette]
   > <2,1,1> · <2,1,1>     then take sqrt (Expressions palette) to get length [example worksheet: babyvectorops.mw]
    
7. F: Quiz 1 on 12.2 
   [look at quiz archive to get an idea what I expect, given any two vectors in the plane, one can project one along and perpendicular to the other];
   we can even make an animation of this with a little extra care:
   handouts/triangleprojectionvideo.gif [.mw];
   detour: parametrized curves:
   [textbook example curves: s10-1.mw (wow!)][parametrized curve tutorial];
   open these worksheets and execute them by hitting the !!! icon on the toolbar (then read them!);
   it is not very useful to try to draw parametrized curves based on what the graphs of x and y look like: technology is meant for visualizing math!;
   10.1: 1, 9, 13, 17 [hyperbolic functions, Stewart 7e section 3.11: cosh² x- sinh² x = 1, recognition is enough],
   19, 21, 28 [eqns; it does not hurt to use technology if you cannot guess them all];
   33, 37.
   
   > plot([cos(t), sin(t)], t =0..2)           square bracket after last function, plots functions versus t on same axis
   > plot([cos(t), sin(t), t =0..2])           square bracket after parameter range, plots parametrized curve in plane
   or
   > cos(t), sin(t)   right click on output, choose Plots, PlotBuilder, 2d parametrized curve.
   
   WEEK 3[-1]:
8. M: handout on lines and planes [.mw];
   never use the symmetric equations of a line: they are useless for all practical purposes!;
   12.5: 1 (draw a quick sketch to understand each statement),
   3, 5, 7 (parametric only),
   13, 16 [ans: a) x = 2+ t, y = 4 - t, z = 6 + 3 t ; b) (0,6,0), (6,0,18)],
   17,
   19;  23, 25, 31, 41, 45, 51, 55.
    
9. T: on-line handout on geometry of lines and planes (distances between);
   in these problems do not just plug into a formula: this is practice in vector projection geometry, we really don't care about the distance!:
   12.5: 57, 69 (find point on plane, project their difference vector along the normal),
   71 , 73 (find pt on each plane, project their difference vector along the normal);
   76, 78 (find pt on each line (set parameters to zero!), project the 2 point difference vector along the normal to the parallel planes that contain them; ans: D = 2).
    
10. W: Maple assignments start: note asterisks;
    13.1: 1, 3, 5, 7, 11, 13, 21-26 (do quickly, note technology is not necessary here to distinguish the different formulas: .mw, .pdf),
    25, 37* [refer back to similar problem 27: note that  z² = (x²+y²)! plot the spacecurve and the surface together as in the template, adjust the ranges for the surface so it is just contains the curve and it not a lot bigger],
    41 [eliminate z first by setting: z² (for cone) = z² (for plane) and solve for y in terms of x, and then express z in terms of  x and finally let x be t],
    12.5.57*: using the answer in the back of the book and this template, plot the two planes and the line of intersection and confirm that visually it looks right. Adjust your plot to be pleasing,  i.e., so the line segment is roughly a bit bigger than the intersecting planes (choosing the range of values for t).
    
    EVERYONE is requested to stop by my office for a 5 minute visit before our first test in week 5, but especially anyone who is having difficulty.
     
11. F: Quiz 2;
    let's try to find one or two partners for Maple assignments from either section 01/04 (paper roster handout);
    13.2: 1[pdf], 2, 5, 7 [recall: exp(2t) = (exp(t))²], 9, 13, 15, 19, 21, 31,  29a (by hand),
    29b* [graph your results using this template; make a comment about how it looks]. 
    
    > with(Student[VectorCalculus]):               or Menu: Tools, Load Package, Student Vector Calculus
    > <1,2,-3> × <1,1,1>
                     5 e_x - 4 e_y - e_z              
     [this is just new notation for the unit vectors i, j, k;  > BasisFormat(false): returns to column notation]
    > F := t → <t, t² , t³> : F(t)
    > F '(t)
    >  ∫  F(t) dt
    > with(plots):
    > spacecurve(F (t), t=0..1, axes=boxed)
    and recall for 2D plots:
    
    > plot([cos(t), sin(t)], t =0..2)           square bracket after last function, plots functions versus t on same axis
    > plot([cos(t), sin(t), t =0..2])           square bracket after parameter range, plots parametrized curve in plane
    
    EVERYONE is requested to stop by my office for a 5 minute visit before our first test in week 5, but especially anyone who is having difficulty. Tuesday will be test day.
    Blackboard grades for quiz 1 are posted. Check that they agree with your paper grade.
    
    WEEK 4[-1]:
12. M: 13.2: 22, 33 [angle between tangent vectors],
    37 [use technology to do the integrals, then repeat using u-substitution on each simple integral and compare results],
    43, 51, 55 [use combined cross product differentiation rules 4,5 from this section:
      (a · (b x c)) ' = a' · (b x c))  + a · (b' x c))  + a · (b x c')) ].
     
13. T:  13.3: 3 [note the input of the sqrt in the integrand is a perfect square in this problem];
    7 (or 9) [use numerical integration either with your graphing calculator or if you use Maple, right-click on output of integral, choose "Approximate"; oops! what a mess!];
    11 [hint: to parametrize the curve, first express y and then z in terms of x, then let x = t; another perfect square],
    13, 17, 25,
    27 [do not use formula 11: instead use the parametrized curve form r = <t,t⁴,0> of the curve y = x⁴];
    [on-line reminder of  dot and cross products and  length, area, volume]
     
14. W: handouts on geometry of spacecurves (page 1 for 13.3) and space curve curvature and acceleration (pages 2-4 for 13.4, print together)
    13.3: 47 [perfect square!], 49;
    > with(Student[VectorCalculus]):
       SpaceCurveTutor(<t,t²,0>,t=-1..1)      from the Tools Menu, Tutors, Vector Calculus, Space Curves [choose animate osculating circles]
    parabola osculating circle zoom.
     
15. F: Quiz 3; 13.4 (no Kepler's laws): 1, 2 [avg velocity = vector displacement / time interval],
    5, 11  [recall v = exp(t) + exp(-t) since v² is a perfect square],
    17a, 17b*[graph your spacecurve using the template; pick the time interval t = -n π..n π, where n is a small integer, and by trial and error, reproduce the figure in the back of the book with 6 peaks, rotating the curve around and comparing with the back of the book sketch (note the horizontal axis tickmarks); if you wish, then animate the curve with the template provided],
    37 [note that v² = 3²(1 + t²)² is a perfect square],
    41 [also perfect square, see 11] .
    
    WEEK 5[-1]: Maple 13 is due any time from this Wednesday after the test to Tuesday next week; did you do your 5 minute office visit?
16. M: projections revisited just for those who like vector geometry;
    13.4: 19 (minimize a function when its derivative is zero (critical point)! confirm minimum by plotting function);
    13.R. (p.874-875):
    14a [use parametrized curve r = [t, t⁴ - t²,0], evaluate T '(0) before simplifying derivative (i.e., set t = 0 before simplifying the expressions after differentiating) to find N(0) easily, find osc circle: x² + (y+1/2)² = 1/4],
    14b*: edit the template with your hand results including comments and also do the zoom plot to see the close match of the circle to the curve];
    This is the most interesting HW problem: 24. [Note b) has answer 52 ft/sec = 36 mph]  [solution].
    HW  (for Wednesday); voluntary  problem session for Test 1 at the new MLRC (Falvey, Floor 2, right side).
     
17. T: Test 1; Valentine's Day:   but
    
    Calc 3 Part 2 begins [maple13.mw due between now and next Tuesday]
     
18. W: 14.1: 1, 3, 11, 13, 15, 21, 27, 31, 33, 39, 47;
    |maple14.mw problems begin:
    55*, using this template just do a single appropriate plot3d and contourplot after loading plots and defining the maple function f (x,y)],
    79a (read only b,c; if you are interested to see how the data is fit see example 3);
    after finishing the preceding, for fun look at 59-64 and try to first match contour plots with the 3d plots (not all are so easy!) and then think about which formulas might go with which pairs [see plots].
     
19. F: no quiz;
     14.2:  1, 2, 5, 13, 15,
    23* [toolbar plot option: contour, or "style=patchcontour" or  right-click style "surface with contour", explain in comment],
    25, 31, 37* [does a 3d plot of the expression support your conclusion? that is, your conclusion drawn before looking at the back of the book obviously, plot and explain].
    Look at 14.1: 59-62 (maple plots reveal relationships, try to see correlations between formulas and plots).
    
    WEEK 6[-1]: maple13.mw due soon;
20. M: Quiz 3, Test 1 back: come discuss test in office if grade less than 80; everyone look at answer key to learn a bit of organization (always factor out common factors, simplify!);
    check quiz, test grades on Blackboard for accuracy;
     14.3: 1, 3, 5, 11, 15, 17, 21, 31, 33, 41, 51 [in class if time: 22, 24, 28].
     
21. T: 14.3: (higher derivatives, implicit differentiation!) 47, 49; 53, 55, 59, 63, 67;
    73 [just average the adjacent secant line slopes on either side of the point where the partial derivative is to be evaluated, as in the opening example: pdf, this is not a testing problem! tedious],
    83, 84.
     
22. W: 14.4: (linear approximation and tangent planes: differentiability illustrated): 1, 3, 7, 11, 15, 19>17, 21, 23.
    7*[calculate by hand, then do two plots: first > plot3d( [f(x,y),L(x,y)],x = a..b, y = c..d); choose appropriate ranges centered about the point of tangency to show a good part of the surface behavior together with the tangent plane, then zoom in by choosing a smaller window about the point of tangency as instructed by the textbook, check that they agree, make a comment that it looks right confirming differentiability].
     
23. F: Quiz 4; online handout on linear approximation and  differentials with HW problem at end (write it out to hand in Monday):
    In the USA (inch units), the 4x6 photo prints have dimensions 4 in by 6 in. In Europe (cm units) the 10x15 prints have dimensions 10cm by 15 cm. Unit conversion: 1 inch = 2.54 cm. Use the differential approximation to estimate the absolute change and percentage change in the (computed) area of the USA format compared to the European format: A = x y . Then compare your linear estimates for both to the corresponding exact changes. Make your response self-contained. [HINT: apply the differential approximation using the x and y values of the European format, with the differentials dx and dy given by the differences USA format dimensions minus the European dimensions. Solution .mw]
    14.4: (differentials): 25, 27, 29, 33, 35, 39 [remember partials of this function from 14.3.83].
    
    WEEK 7[-1]:
24. M: HW catchup; get started on Maple14.mw;
    order of partial derivatives does not matter if they are all continuous! 14.3: 97 (note: continuity of the first partial derivatives of a function imply the function itself is continuous);
    ideal gas law derivatives: 14.3.88.
     
25. T: 14.5 (chain rule): 1, 11, 13, 15, 17 (I never use tree diagrams), 21, 35, 39a.
     
26. W: 14.5:  14.5: 31 (no need to remember these equations, just implicit differentiate and solve in practice), 41 [units?], 43 [in degrees per second?], 45 [pdf], 49.
    optional: 53 [use answer only to check work after an honest try: maple, pdf; note this "coordinate transformation" of this second order derivative expression is extremely important for gravitational, electromagnetic, quantum mechanical and heat transfer problems, among many others].
    Quiz 5: tangent planes, linear approx, differentials, implicit diff?
     
27. F: Bring laptops to work on maple14.mw so far.
    
    Spring Break. enjoy and be safe.
    
    WEEK 8[-1]: Maple upgrades must be received by Tuesday for midterm grades!
28. M: 14.6 (stop at tangent planes): 1, 3, 5, 7, 9, 11, 15,
    19 [first find a unit vector in the given direction! sketch the two points],
    23[just split the gradient into its length and unit vector direction information], 29.
     
29. T: handout on derivatives of 2d and 2d functions;
    14.6: 27b, 31, 36, 38, 41, 47 (derive equations of plane and line by hand), 49, 55, this one is fun: 61;
    47* [plot your results in an appropriate window (using the 1-1 toggle or the option "scaling=constrained" to see the right angle correctly), i.e., adjust windows of function, plane, line to be compatible, after doing problem by hand];
    head start in class with any partner?  f(x,y,z) = x y + y z + z x = 3 at (1,1,1) -> tan plane, normal line.
     
30. W: Midterm grades are posted in Blackboard, make sure they agree with your paper data, you can use my spreadsheet to check your grade with your grade inputs;
    handout on  2D 2nd derivative test;
     14.7: 1, 3, 5, 7, 13, 23 (do by hand, including second derivative test and evaluation of f at critical points); 23* [template shows how to narrow down your search to find extrema by trial and error, record your tweaked image or images confirming your hand results, include commentary, see additional comments on Maple HW page summary (inconclusive saddle point?)];
    optional: if you are interested in the more realistic case of example 4 where numerical root finding is required, read this worksheet.
    
    Today is Pi Day:  π!  [and Einstein's birthday]
     
31. F: Quiz 6;
    on-line handout on multivariable derivative and differential notation;
    14.7: 19 (a warning that extrema are not always isolated points);
    boundaries: 31;
    word problems: 39 [minimize square of distance],
    47 (similar to 43 only with different coefficients in the constraint equation),
    51, 54 [use constraint to eliminate r, maximize resulting function of 2 variables on triangular region, consider triangular boundary];
    read 55 [this explains least squares fitting of lines to data, and perhaps the most important application of this technique to practical problems].
    
    WEEK 9[-1]: Test 2 thru 14.7 Tuesday Week 10.
32. M: hoops&yoyo Hate to say it, it's.......Monday :0( No wonder we started feeling icky.
    14.R (review problems; note some of the highest numbered problems refer to 14.8, which we did not do): 
    some in class if time: 1, 7, 15, 18, 21, 25, 29, 31, 33, 34a, 39, 53,
    14.7: 50 [ans: the height is 2.5 times the square base; obviously cost of materials is not the design factor for normal aquariums, no?].
     
33. T:  Catch up on Maple14 HW due anytime in next week approximately, fix Maple13 if not 2/2.
    (inconclusive saddle point?); discussion of nested integrals, first fundamental theorem of calculus.
     
34. W: Maple Tools Menu, Select Calculus Multi-Variable, Approximate Integration Tutor (midpoint evaluation usually best)
    15.1: 1, 3 [do by hand first], 3 [after doing this by hand, before next class: repeat this problem using the Maple Approximate Integration Tutor (with midpoint evaluation for (m,n) = (2,2), then (20,20), then (200,200), comparing it with the exact value given by the Tutor],
    5, 6 [midpoint sampling: (m,n)=(2,3), x along 20 ft side, y along 30 ft side: answer = 3600], 7, 9;
    15* [note: (m,n) = (1,1), (2,2), (4,4), (8,8), (16,16), (32,32) = (2^p,2^p) for p = 0..5 is what the problem is asking for (see 3 line Maple template); what can you conclude about the probable approximate value of  the exact integral to 4 decimal places?] .
    
     [happy persian new year, vernal equinox]
     
35. F: Quiz 7 on max-min problems;
     15.2: 1, 3, 7, 11, 21 [which order avoids integration by parts?], 23, 31, 33* (used boxed axes!);
    [iterated integrals in Maple (how to enter)]
    
    step by step checking of multiple integration (worksheet):
    > x + y
    > ∫ % dx
    > eval(%,x=b) - eval(%,x=a)
    >  ∫ % dy
    > eval(%,y=d) - eval(%,y=c)
    > etc... if triple integral (and simplify may help along the way)
    
    WEEK 10[-1]: Maple14.mw due this week
36. M:  5:30 MLRC (Falvey Library 2nd Floor) voluntary problem session,remember summary of 2d/3d derivatives;
    15.3: handout on double integrals; HW for after the test:
    5, 15, 17, 25, 27; 39* [just use Maple to evaluate the integral once you set it up],
    47, 49, 57, optional: 1, 9, 53.
     
37. T: Test 2.
     
38. W: jump to 15.7: 1, 3, 5, 13 [optional visualization],
    15 [make a diagram, do x or y integration first, note that the tilted plane faces are described by the equations of lines in the xz or yz planes],
    21, 27;
    handout: example of iterating triple integral 6 different ways;
    handout: exercise in setting up triple integrals in Cartesian coordinates.
     
39. F:  no quiz; maple14 is due, get it done soon;
    now first do the handout exercise: exercise in setting up triple integrals in Cartesian coordinates (please take this seriously, hand in monday stapled to your work with name); then try unaided the book problems:
    15.7: 29, 31 [see 3d Maple plot: two projections of the solid onto coordinate planes are actually faces of the solid, the third face has a border obtained by eliminating y from the two equations given in the figure to describe the condition on x and z for that edge curve];
    if you cannot get both 29 and 31, try 33 where the diagram is made for you.
    31* use the standard maple expression palette icon for the definite triple integral of the constant function 1 to check the agreement of two different iterations with two different variables for the innermost integration step.
    
    CONTEXT: While a few of you may learn how to illustrate triple integrals (my hope), I will only test all of you on being able to iterate triple integrals given the 3d figure already drawn for you as in problems 33, 34, and the handout problem once you have the 3d figure given to you.
    
    WEEK 11[-1]:
40. M: turn in triple integral worksheet (postponed till next class, read email);
    handout: review polar coordinate trig;
    handout on polar coordinates and polar coordinate integration (the integration is next time);
    10.3 pp.654-659 (stop midpage: tangents in polar coords unnecessary for us), pp.661-662 (read graphing in polar coords);
    10.3: 1, 3, 5, 7, 9, 11, 15, 17, 21, 25, 29, 31, 33, 37 (all short review problems);
    part of Maple15.mw:
    67* [Nephroid of Freeth: starting at θ = 0 how far does theta have to go for the sine to undergo one full cycle? i.e., θ/2 = 2 π ; this is the plotting interval];
    keep in mind that our most important curves for later use are circles centered at the origin or passing through the origin with a center on one of the coordinate axes, and vertical and horizontal lines, and lines passing through the origin, as in the handout examples.
     
41. T: Test 2 back [read answer key];
    15.4: (areas but no lengths): use 1, 4, 5, 7, 21,
    23 [twice the volume under the hemisphere z = sqrt(a² - x² - y²) above the circle x² + y²  ≤ a²],
    25 [integrand is difference of z values from cone (below) to sphere (above) expressed as graphs of functions in polar coordinates];
    now look at polar coordinate integration examples handout;
     
42. W: in class: recall 15.7.ex3 and re-express the outer double integral, inner limits of integration and integrand in polar coordinates in the x-z plane (pretend z is y, or simply interchange them since they are dummy variables of integration):
     ∫ ∫ _r<=2  [∫_{y= x^{^2}+z^{^2..4}}  (x²+z²)^1/2 dy] dA = ∫ ∫ _r<=2  [∫_{z= x^{^2}+y^{^2..4}}  (x²+y²)^1/2 dz] dA (see book discussion on page 1020);
    15.4: 15 [at what acute angular negative or positive values of theta does cos(3θ) =0? these are the starting and stopping values of θ for one loop],
    29, 31, 35 [what is the average depth? (integral of depth divided by area of region)],
    36 [ans: a): 2π(1-(1+R) e^-R)],
    39 (make a diagram, assembling the 3 integration regions into one simple region, then it is easy!);
    Optional: Read 40 [this enables one to sum the probability under a normal curve in statistics, grade curving, it's important!]
    Mandatory: read solution to triple integral worksheet exercise [.mw each integral with integrand 1 should give volume 8/15]
    
    Easter Break. 
    
    WEEK 11[+1]:
43. T: Read 15.5 carefully; catch up on old homework;
    15.5 (center of mass, "centroids" when constant density; skip moment of inertia): 5, 7, 11 [see example 3], [integrals, visualize etc: .mw],
     
44. W: 15.5: (probability): 
    27, 29, 30a [P(x<=1000,y<=1000) = .3996], 30b [P(x+y<=1000) = .2642]. [Maple is the right tool for evaluating probability integrals!],
    31* [on-line handout only: distributions of stuff] <<<<< NEW! [solution to 31]
     
45. F: Quiz 8; handout on cylindrical  and spherical coordinates and using them to describe regions of space and bounding surfaces;
    15.8 (cylindrical): 1, 3, 5, 7, 9, 13, 15, 17, 21, 29.
    Paraskevidekatriaphobia??
    
    Final exam on paper course syllabus handout was wrong (editing glitch): see below.
    
    WEEK 12[+1]:
46.  M: handout on cylindrical and spherical regions of space and their bounding surfaces: examples;
    handout on cylindrical and spherical triple integral: examples;
    15.9 (spherical): 1, 3, 5, 7, 9, 11, 13 , 15, 17, 21, 25, 39.
     
47. T: handout on radial integration diagrams for simple circles and lines (cylinders, spheres, planes);
    in class review problems, homework:
    15.8: 27;
    15.9: 23, 29, 35;
    15.R (p.1050): 19, 20, 27, 37a, 41, 47;
    review online: integration over 2d and 3d regions;
     
48. W: F: 16.1: 1, 5, 9; 21, 25;
    comparison shopping:
    11-14: < x,-y>, <y, x - y>,  <y, y + 2>, <cos(x+y), x> ;
    15-18, <1, 2, 3>, <1, 2, z>, <x, y, 3>, <x, y, z> ;
    29-32: x²+y², x(x+y), (x+y)²,  sin(x²+y²)^1/2;
    19*; just try the template, no need to submit [check here for result, with bonus problem 25 done as well].
    look over archived Test 3.
    
    Th: dr bob gets his 15 minutes of fame: 1pm Falvey Library talk.
     
49. F: Quiz 9 pretend; hand in Monday;
    16.2 (f ds scalar line integrals: pp.1063-1068 midpage, for Thursday): 1, 3, 9, 11 [write vector eq of line, t = 0..1];
    33, 36 [ans: <4.60,0.14,-0.44>, worksheet compares with centroid: obvious midpoint, also bonus: 33 solution].
    
    WEEK 13[+1]:
50. M: Turn in Quiz 9;
    Test 3 problem session 5:30 MLRC;
    Test 3 online after, paper copy in class next day, due Monday one week;
    handout on line integrals;
    16.2 (F • dr = F • (dr/dt) dt  = F • T ds  vector line integrals):
    7 [ ∫_C <x+2y, x²> • <dx, dy>], 17, 19, 21, 27, 29a;
     45, 51 (notice projection along line constant on each line segment, so can multiply it by the length, add two separate results);
    optional: 42 [ans: K(1/2-1/sqrt(30)],  48.
     
51. T: In class work on Test 3;
    Armenian Genocide Day.
     
52. W: 16.3: 1, 3, 5, 11 (b: find potential function and take difference, or do straight line segment line integral), 15 (potential function); 25, 35.
    short class because of conflict:

    Cosmology/Astrophysics Symposium: Today

    Please join us in the Connelly Center Cinema for an Cosmology/Astrophysics symposium being held in honor of Rashid Sunyaev, Director of the Max Planck Institute fur Astrophysik, Garching and the Russian Academy of Sciences, Moscow. He is the 2012 recipient of the Franklin Institute's Benjamin Franklin Medal in Physics. The symposium, entitled "From the Origin of the Universe to Accretion by Black Holes: A Symposium in Honor of Rashid Sunyaev", will take place in the Connelly Center Cinema at 1:30 p.m -3:30 p.m. Wednesday, April 25. There will be three speakers: Prof. Mark Birkinshaw (University of Bristol, UK), Dr. Mario Livio (Space Telescope Science Institute), and Prof. Rashid Sunyaev (New Science Results from Orbiting X-ray Observatories). The symposium is free and open to the public. We hope that you will be able to attend this exciting afternoon. Refreshments will be served.
    
    If you need to see me, 3:35:-4pm in my office today.
    
    Optional note: the final section of 16.3 on conservation of energy is really important for physical applications. Enough said.
    
    Maple15.mw is cancelled to lighten your end of semester load.
     

53. F: 16.4: 1, 3, 17,
    18 [convert double integral to polar coordinates; ans: 12 π];
    [optional: the line integral technique for integrating areas of regions of the plane is cute but we just don't have time for it so you can ignore it.]
    
    WEEK 14:
54. M: Monday. Test 3 due;
    handout on divergence and curl, Gauss and Stokes versions of Green's Theorem.
    Final section 16.5: 1, 5, 9, 11,
    12 [easier to interpret vectorially if convert to "del, del dot, del cross" form],
    13, 15, 31 [but read 37, 38 and look at identities 23-29].
     
55. T=F: optional handout on interpretation of circulation and flux densities for curl and div [visualize];
    Optional 16.6-7: surface integrals for fun [hemisphere example];
    Optional 16.8-9: read lightly Stokes Theorem, Gauss's law if you are interested, when you have time;
    [example1: centroid of hemisphere, Gauss law example, wedge of cylinder 16.7.example3;
     example2: parabola of revolution (Stewart16.7.23 expanded into Gauss/Stokes examples)].
     
56. W=M: last day of class May 2. In class exercise:
    a) Surface integral of <0,0,1> over parabola of revolution z = 4 - x² - y² >  0 of Stewart 16.7.23;
    b) Surface area same surface;
    CATS Teaching evaluations.
    
    
    MLRC Problem session: W May 9: 5:00pm Office hours: 2:30-4:50pm.
    Email me for other times.
    
    Final exams Th/F May 10/11 in Mendel G92/JB202B.

MAPLE HW files:
maple13.mw due:  Week 6
maple14.mw due:  Week 10
maple15.mw due: Week 13?

*MAPLE homework log and instructions [asterisk "*" marked homework problems]

Test 1:  Week 5: ; MLRC 5:30 problem session .
Test 2:  Week 10: ;  MLRC 5:30 problem session  .
Test 3: WEEK 13: Take home out ; in  ; MLRC problem session 

FINAL EXAM: you can switch section exam times with permission

Graphing Calculator / Maple Checking ALLOWED FOR ALL QUIZZES/EXAMS