University of Florida/Egm6341/s10.Team2/HW5

Problem 1: Determination of leading coefficients of polynomials[edit | edit source]

Statement[edit | edit source]

P. 26-3

To show that the value of the constants ${\displaystyle \;c_{6}=0}$ and ${\displaystyle c_{5}={\frac {-7}{360}}}$ in the polynomials ${\displaystyle P_{4}\left(t\right)}$ and ${\displaystyle P_{5}\left(t\right)}$

Solution[edit | edit source]

From page 26-2, we know that:

${\displaystyle P_{5}\left(t\right)={\frac {-t^{5}}{120}}+{\frac {t^{3}}{36}}+C_{5}t+C_{6}}$

We select ${\displaystyle \;P_{5}\left(t\right)}$ such that it is a odd function and ${\displaystyle \;P_{5}\left(1\right)=P_{5}\left(-1\right)=P_{5}\left(0\right)=0}$

Therefore, using ${\displaystyle P_{5}\left(0\right)=0}$, we get:

${\displaystyle P_{5}\left(0\right)={\frac {-0^{5}}{120}}+{\frac {0^{3}}{36}}+C_{5}*0+C_{6}=0}$

${\displaystyle \displaystyle {\boldsymbol {\therefore }}\;C_{6}=0}$

(1)

Similarly, using ${\displaystyle \;P_{5}\left(1\right)=0}$, we get:

${\displaystyle P_{5}\left(1\right)={\frac {-1^{5}}{120}}+{\frac {1^{3}}{36}}+C_{5}*1+C_{6}={\frac {-1}{120}}+{\frac {1}{36}}+C_{5}=0}$

${\displaystyle \displaystyle {\boldsymbol {\therefore }}\;C_{5}={\frac {1}{120}}-{\frac {1}{36}}=-{\frac {7}{360}}}$

(2)

Author[edit | edit source]

Egm6341.s10.team2.lee 08:58, 24 March 2010 (UTC)

proofread --Egm6341.s10.team2.niki 14:53, 24 March 2010 (UTC)

Problem 2: Continuation of proof of trapezoidal error[edit | edit source]

Statement[edit | edit source]

P. 27-1

Continue the proof of Trapezoidal Rule Error to steps 4a and 4b and determine ${\displaystyle {\boldsymbol {P_{6}(t)}}}$ and ${\displaystyle {\boldsymbol {P_{7}(t)}}}$

Solution[edit | edit source]

From steps 3a and 3b( P.26-3) we get the expression

${\displaystyle \displaystyle {\boldsymbol {E=[P_{2}(t)g^{(1)}(t)+P_{4}(t)g^{(3)}(t)]_{-1}^{+1}-\underbrace {\int _{-1}^{+1}P_{5}(t)g^{(5)}(t)dt} _{D}}}}$

(P.26-3)

${\displaystyle \displaystyle P_{4}(t)={\frac {-t^{4}}{24}}+{\frac {t^{2}}{12}}-{\frac {7}{360}}=c_{1}({\frac {t^{4}}{4!}})+c_{3}({\frac {t^{2}}{2!}})+c_{5}}$ ${\displaystyle P_{5}(t)={\frac {-t^{5}}{120}}+{\frac {t^{3}}{36}}-{\frac {7t}{360}}=c_{1}({\frac {t^{5}}{5!}})+c_{3}({\frac {t^{3}}{3!}})+c_{5}(t)}$

(P.26-3)

Step 4a[edit | edit source]

${\displaystyle \displaystyle \int _{-1}^{+1}\underbrace {P_{5}(t)} _{v'}\underbrace {g^{(5)}(t)} _{u}dt=[g^{(5)}(t)P_{6}(t)]_{-1}^{+1}-\underbrace {\int _{-1}^{+1}[{P_{6}(t)g^{(6)}(t)}} _{E}]dt}$

where, ${\displaystyle P_{6}(t)=\int P_{5}(t)=c_{1}({\frac {t^{6}}{6!}})+c_{3}({\frac {t^{4}}{4!}})+c_{5}({\frac {t^{2}}{2!}})+c_{7}}$

          ${\displaystyle P_{6}(t)={\frac {-t^{6}}{720}}+{\frac {t^{4}}{144}}-{\frac {7t^{2}}{720}}+\alpha }$

Step 4b[edit | edit source]

${\displaystyle \displaystyle \int _{-1}^{+1}[{\underbrace {P_{6}(t)} _{v'}\underbrace {g^{(6)}(t)} _{u}}]dt=E=[g^{(6)}(t)P_{7}(t)]_{-1}^{+1}-\int _{-1}^{+1}P_{7}(t)g^{(7)}(t)dt}$

where, ${\displaystyle P_{7}(t)=\int P_{6}(t)==c_{1}({\frac {t^{7}}{7!}})+c_{3}({\frac {t^{5}}{5!}})+c_{5}({\frac {t^{3}}{3!}})+c_{7}(t)+c_{8}}$

          ${\displaystyle P_{7}(t)={\frac {-t^{7}}{5040}}+{\frac {t^{5}}{720}}-{\frac {7t^{3}}{2160}}+\alpha t+\beta }$

Selecting ${\displaystyle \displaystyle {P_{7}(t)}}$ such that

${\displaystyle \displaystyle {P_{7}(+1)=P_{7}(-1)=P_{7}(0)=0}}$ ,we get

${\displaystyle \displaystyle {P_{7}(t=0)=0\Rightarrow \beta =c_{8}=0}}$

${\displaystyle P(-1)=0=-{\frac {(-1)^{7}}{7!}}+{\frac {1}{6}}({\frac {(-1)^{5}}{5!}})-{\frac {7}{360}}({\frac {(-1)^{3}}{3!}})-\alpha \Rightarrow \alpha =c_{7}={\frac {31}{15120}}}$

Summary[edit | edit source]

${\displaystyle \displaystyle P_{6}(t)={\frac {-t^{6}}{720}}+{\frac {t^{4}}{144}}-{\frac {7t^{2}}{720}}+{\frac {31}{15120}}}$ ${\displaystyle P_{7}(t)=\int P_{6}(t)={\frac {-t^{7}}{5040}}+{\frac {t^{5}}{720}}-{\frac {7t^{3}}{2160}}+{\frac {31}{15120}}t}$

Author[edit | edit source]

--Egm6341.s10.team2.niki 22:04, 23 March 2010 (UTC)

--Proofread by Egm6341.s10.team2.lee 10:14, 26 March 2010 (UTC)

Problem 3: Expression of ${\displaystyle \;t_{k}}$ as function of ${\displaystyle \;x}$[edit | edit source]

Statement[edit | edit source]

find ${\displaystyle \;t_{k}(x)}$ on P. 27-1

Solution[edit | edit source]

From Page 27-1, we know:

${\displaystyle x\left(t_{k}\right)={\frac {1}{2}}\left(x_{k}+x_{k+1}\right)+t_{k}{\frac {h}{2}}}$

Now rearranging the terms on both sides to write ${\displaystyle \;t_{k}}$ in terms of ${\displaystyle \;x}$, we get:

${\displaystyle t_{k}\left(x\right)={\frac {2x-\left(x_{k}+x_{k+1}\right)}{h}}}$ ${\displaystyle \;\;}$ where the size of the interval, ${\displaystyle \;h=x_{k+1}-x_{k}}$

It can also be easily verified by substituting ${\displaystyle \;x=x_{k}}$ which yields ${\displaystyle t_{k}\left(x=x_{k}\right)={\frac {x_{k}-x_{k+1}}{x_{k+1}-x_{k}}}=-1}$

Also when ${\displaystyle \;x=x_{k+1}}$ yields ${\displaystyle t_{k}\left(x=x_{k+1}\right)={\frac {x_{k+1}-x_{k}}{x_{k+1}-x_{k}}}=1}$

Author[edit | edit source]

Srikanth Madala (SM)

Problem 4: Evaluation of ${\displaystyle d_{1},d_{2}\;and\;d_{3}}$ which can be used to calculate the coefficients of the even power euler-maclaurin error series for trapezoidal rule[edit | edit source]

Statement[edit | edit source]

P. 27-2

Find the values of ${\displaystyle d_{1}={\bar {d_{2}}},d_{2}={\bar {d_{4}}}}$ and ${\displaystyle d_{3}={\bar {d_{6}}}}$

Clue: Use the formula: ${\displaystyle d_{i}={\bar {d_{2i}}}={\frac {P_{2i}\left(1\right)}{2^{2i}}}}$

Solution[edit | edit source]

We know from the formula:

${\displaystyle d_{i}={\bar {d_{2i}}}={\frac {P_{2i}\left(1\right)}{2^{2i}}}}$

From Mtg 26,slide 26-1, we know the formula:

${\displaystyle P_{2}\left(t\right)={\frac {-t^{2}}{2!}}+{\frac {1}{6}}}$

${\displaystyle P_{2}\left(1\right)={\frac {-1^{2}}{2!}}+{\frac {1}{6}}}$

${\displaystyle d_{1}={\bar {d_{2}}}={\frac {P_{2}\left(1\right)}{2^{2}}}={\frac {\frac {-1}{3}}{4}}={\frac {-1}{12}}}$

(1)

From Mtg 26,slide 26-3, we know the formula:

${\displaystyle P_{4}\left(t\right)={\frac {-t^{4}}{24}}+{\frac {t^{2}}{12}}-{\frac {7}{360}}}$

${\displaystyle P_{4}\left(1\right)={\frac {-1^{4}}{24}}+{\frac {1^{2}}{12}}-{\frac {7}{360}}={\frac {1}{45}}}$

${\displaystyle d_{2}={\bar {d_{4}}}={\frac {P_{4}\left(1\right)}{2^{4}}}={\frac {\frac {1}{45}}{16}}={\frac {1}{720}}}$

(2)

From problem 2 on this HW , where we deduced that:

${\displaystyle P_{6}(t)={\frac {-t^{6}}{720}}+{\frac {t^{4}}{144}}-{\frac {7t^{2}}{720}}+{\frac {31}{15120}}}$

${\displaystyle P_{6}(1)={\frac {-1^{6}}{720}}+{\frac {1^{4}}{144}}-{\frac {7*1^{2}}{720}}+{\frac {31}{15120}}={\frac {-2}{945}}}$

${\displaystyle d_{3}={\bar {d_{6}}}={\frac {P_{6}\left(1\right)}{2^{6}}}={\frac {\frac {-2}{945}}{64}}={\frac {-1}{30240}}}$

(3)

Author[edit | edit source]

--Srikanth Madala 01:44, 24 March 2010 (UTC) Srikanth Madala (SM)

Problem 5: Derivation of the Error of the Trapezoidal Rule[edit | edit source]

Statement[edit | edit source]

P. 28-2 derive

Derive the Following Equation for the error of the trapezoidal rule:

${\displaystyle E_{n}^{1}=I-T_{0}(n)=\sum _{r=1}^{l}h^{2r}{\tilde {d}}_{2r}\left[f^{2r-1}(b)-f^{2r-1}(a)\right]-{\frac {h^{2l}}{2^{2l}}}\sum _{k=0}^{n-1}\int _{x_{k}}^{x_{k+1}}P_{2}l(t_{k}(x))f^{2l}(x)dx}$

Solution[edit | edit source]

The Following Equation is to be derived:

${\displaystyle E_{n}^{1}=I-T_{0}(n)=\sum _{r=1}^{l}h^{2r}{\tilde {d}}_{2r}\left[f^{2r-1}(b)-f^{2r-1}(a)\right]-{\frac {h^{2l}}{2^{2l}}}\sum _{k=0}^{n-1}\int _{x_{k}}^{x_{k+1}}P_{2}l(t_{k}(x))f^{2l}(x)dx}$

${\displaystyle E=\int _{-1}^{+1}P_{1}(t)g^{1}(t)dt=\underbrace {{\frac {h}{2}}\left[P_{2}g^{1}+P_{4}g^{3}+...+P_{2l}g^{2l-1}\right]_{-1}^{+1}} _{A}-\underbrace {\int _{-1}^{+1}P_{2l}(t)g^{2l}(t)dt} _{B}}$

Since ${\displaystyle P_{2}}$ is an even function then:

${\displaystyle \left[P_{2}(t)g^{1}(t)\right]_{-1}^{+1}=P_{2}(+1)\left[g^{1}(+1)-g^{1}(-1)\right]}$

With this property then A can be rewritten as follows:

${\displaystyle \sum _{i}^{l}P_{2r}(+1)\left[g^{2r-1}(+1)-g^{2r-1}(-1)\right]}$

A transformation of variable is needed from 't' to 'x' and is as follows:

${\displaystyle g_{k}^{i}(t)=({\frac {h}{2}})^{i}f^{i}(x(t))\quad \quad x\epsilon [x_{k},x_{k+1}]}$

With this transformation A can be rewritten as follows:

${\displaystyle {\frac {h}{2}}\sum _{i=1}^{l}P_{2r}(+1)({\frac {h}{2}})^{2r-1}\left[f^{2r-1}(b)-f^{2r-1}(a)\right]}$

The Following is then defined:

${\displaystyle {\tilde {d}}_{2r}={\frac {P_{2r}(+1)}{2^{2r}}}}$ as discussed in [28-2] of the lectures.

A is then rewritten as follows:

${\displaystyle {\frac {h}{2}}\sum _{i=1}^{l}{\tilde {d}}_{2r}2^{2r}\left({\frac {h}{2}}\right)^{2r-1}\left[f^{2r-1}(b)-f^{2r-1}(a)\right]}$

${\displaystyle {\frac {h}{2}}\sum _{i=1}^{l}{\tilde {d}}_{2r}2h^{2r-1}\left[f^{2r-1}(b)-f^{2r-1}(a)\right]}$

${\displaystyle \sum _{i=1}^{l}{\tilde {d}}_{2r}h^{2r}\left[f^{2r-1}(b)-f^{2r-1}(a)\right]}$

The Next Step is to simplify the term 'B'

${\displaystyle B=\int {-1}^{+1}P_{2l}(t)g^{2l}(t)dt}$

Using the previously mentioned transformation of variable the following can be stated:

${\displaystyle \int _{-1}^{+1}P_{2l}(t)\left({\frac {h}{2}}\right)^{2l}f^{2l}(x(t))dt}$

With the previously performed simplifications the following is written:

${\displaystyle E_{n}^{1}=A-B=\sum _{i=1}^{l}{\tilde {d}}_{2r}h^{2r}\left[f^{2r-1}(b)-f^{2r-1}(a)\right]-{\frac {h^{2l}}{2^{2l}}}\int _{-1}^{+1}P_{2l}(t)\left({\frac {h}{2}}\right)^{2l}f^{2l}(x(t))dt}$

This is recognized as the Error for the trapezoidal rule.

Author[edit | edit source]

--Egm6341.s10.Team2.GV 22:09, 25 March 2010 (UTC)

--Proofread by Egm6341.s10.team2.lee 10:13, 26 March 2010 (UTC)

Problem 6: Derivation of ${\displaystyle {\bar {d}}}$ terms using Taylor expansion of the hyperbolic function[edit | edit source]

Statement[edit | edit source]

P. 28-2 bernoulli nos

Solution[edit | edit source]

Author[edit | edit source]

Egm6341.s10.team2.lee 10:12, 26 March 2010 (UTC)

Problem 7: Understanding the derivation of the proof of Trapezoidal Error[edit | edit source]

Statement[edit | edit source]

P. 28-2

Redo steps in the proof of the Trapezoidal Rule error by trying to cancel terms with odd order derivatives of "g"

Solution[edit | edit source]

We begin with equation (5) on P. 21-1 which is the result of transformation of variables on equation (1) P. 21-1

(Prob 4 HW4) (P. 21-1)

${\displaystyle \displaystyle E_{n}^{1}={\frac {h}{2}}\sum _{k=0}^{n-1}[\int _{-1}^{1}g_{k}(t)dt-[g_{k}(-1)+g_{k}({+1})]]}$

(5) on P.21-1

From Prob 5 HW4, we can express the above equation as:

${\displaystyle \displaystyle E_{n}^{1}={\frac {h}{2}}\sum _{k=0}^{n-1}[\int _{-1}^{+1}(-t)g^{(1)}(t)dt]}$

(1)

Integrating the term withing the square brackets by "Integration by parts" Prob 7 HW4 we can rewrite (1) as follows

${\displaystyle \displaystyle E_{n}^{1}={\frac {h}{2}}\sum _{k=0}^{n-1}[[P_{2}(t)g^{(1)}(t)]_{-1}^{+1}-\int _{-1}^{+1}P_{2}(t)g^{(2)}(t)dt]}$

(2)

In order to eliminate terms with even powers of ${\displaystyle \displaystyle {h}}$ we need to remove terms with odd derivatives of ${\displaystyle \displaystyle {g(t)}}$.Therefore, the boundary term in eqn (2) above must be set to zero by selection of ${\displaystyle \displaystyle {P_{2}(t)}}$.

We have ${\displaystyle \displaystyle {P_{2}(t)}}$ from eqns (1 and 2)P. 21-3

${\displaystyle \displaystyle P_{2}(t)=c_{1}({\frac {t^{2}}{2!}})+c_{3}}$

(1)p21-3

${\displaystyle \displaystyle c_{2}=0}$

(2)p21-3

Setting ${\displaystyle \displaystyle {P_{2}(-1)=0}}$ gives ${\displaystyle \displaystyle {c_{3}=1/2}}$ and hence we get

${\displaystyle \displaystyle P_{2}(t)=c_{1}({\frac {t^{2}}{2!}})+c_{3}}$

(3)

So following this method, the next term to be eliminated will have P4(t)

${\displaystyle \displaystyle P_{4}(t)=c_{1}({\frac {t^{4}}{4!}})+c_{3}({\frac {t^{2}}{2!}})+c_{4}(t)+c_{5}}$

(4)

Setting ${\displaystyle \displaystyle {P_{4}(-1)=0andP_{4}(1)=0}}$ and solving we get ${\displaystyle \displaystyle {c_{4}=0andc_{4}=-5/24}}$.Continuing on these lines we get the eqn (2) in the form

${\displaystyle \displaystyle E_{n}^{1}={\frac {h}{2}}\sum _{k=0}^{n-1}{[P_{2}g^{(1)}]_{-1}^{+1}-[P_{3}g^{(2)}]_{-1}^{+1}}+[P_{4}g^{(3)}]_{-1}^{+1}-[P_{5}g^{(4)}]_{-1}^{+1}+[P_{6}g^{(5)}]_{-1}^{+1}-[P_{7}g^{(6)}]_{-1}^{+1}-\int _{-1}^{+1}P_{7}g^{(7)}dt}$

(5)

Dropping all the terms with odd order derivatives of ${\displaystyle g(t)}$ we get

${\displaystyle \displaystyle E_{n}^{1}={\frac {h}{2}}\sum _{k=0}^{n-1}{-[P_{3}g^{(2)}]_{-1}^{+1}}+-[P_{5}g^{(4)}]_{-1}^{+1}+-[P_{7}g^{(6)}]_{-1}^{+1}-\int _{-1}^{+1}P_{7}g^{(7)}dt}$

(6)

In general on integrating "m" times we get:

${\displaystyle \displaystyle E_{n}^{1}={\frac {h}{2}}\sum _{k=0}^{n-1}(\sum _{i=1}^{m}-[P_{(2i+1)}g^{(2i)}]_{-1}^{+1})-\int _{-1}^{+1}P_{(2m+1)}g^{(2m+1)}dt}$

(7)

manipulating the terms yields,

${\displaystyle \displaystyle E_{n}^{1}={\frac {h}{2}}\sum _{k=0}^{n-1}[\sum _{i=1}^{m}-[(P_{(2i+1)}(+1)g^{(2i)}(+1))-(P_{(2i+1)}(-1)g^{(2i)}(-1))]-\int _{-1}^{+1}P_{(2m+1)}g^{(2m+1)}dt}$

(8)

Transforming g(t) back to f(x) we get [see [prob 6 HW4]

${\displaystyle \displaystyle E_{n}^{1}=\sum _{i=1}^{m}({\frac {h}{2}})^{2i+1}\sum _{k=0}^{n-1}[(P_{(2i+1)}(-1)(f^{(2i)}(x_{k}))-(P_{(2i+1)}(+1)f^{(2i)}(x_{k+1}))]-({\frac {h}{2}})^{2m+1}\sum _{k=0}^{n-1}(\int _{x_{k}}^{x_{k+1}}P_{(2m+1)}(x)f^{(2m+1)}(x))dx)}$

(9)

Since the polynomial is odd, it can be extracted out to give the eqn in the form

${\displaystyle \displaystyle E_{n}^{1}=\sum _{i=1}^{m}({\frac {h}{2}})^{2i+1}P_{(2i+1)}(-1)\left[\sum _{k=0}^{n-1}[(f^{(2i)}(x_{k})+f^{(2i)}(x_{k+1})]\right]-({\frac {h}{2}})^{2m+2}\sum _{k=0}^{n-1}(\int _{x_{k}}^{x_{k+1}}P_{(2m+1)}(x)f^{(2m+1)}(x))dx)}$

(9)

The problem with this formula is evident at first sight, from this expression.The HO derivatives add up in the first term of the expression and since they will not cancel out (9) cannot be reduced to a simpler form. To see the difference in the two approaches more clearly we compare the equations from the two methods. From (1) P. 27-1 we have

${\displaystyle \displaystyle E_{n}^{1}=\sum _{r=1}^{l}h^{2r}d_{2r}[f^{(2r-1)}(b)-f^{(2r-1)}(a)]-{\frac {h^{(2l)}}{2^{(2l)}}}\sum _{k=0}^{n-1}\int _{x_{k}}^{x_{k+1}}P_{2l}(t_{k}(x))f^{(2l)}(x)dx}$

(10)

${\displaystyle \displaystyle E_{n}^{1}=\sum _{i=1}^{m}({\frac {h}{2}})^{2i+1}P_{(2i+1)}(-1)\left[\sum _{k=0}^{n-1}[(f^{(2i)}(x_{k})+f^{(2i)}(x_{k+1})]\right]-({\frac {h}{2}})^{2m+2}\sum _{k=0}^{n-1}(\int _{x_{k}}^{x_{k+1}}P_{(2m+1)}(x)f^{(2m+1)}(x))dx)}$

(9)

Comparing the eqns 9 and 10 we see that the first term on 9 has a summation of HO derivatives at different points in the square brackets as opposed to 10 which has the difference of the higher order derivative at only the end points. In this lies the difference of the two methods. 10 is general and easier to apply as we need to evaluate the differential of F(x) at only the end points while 9 is computationally cumbersome since it needs the derivative evaluated at all points.

Author[edit | edit source]

--Egm6341.s10.team2.niki 14:52, 24 March 2010 (UTC)

Problem 8: Calculating the coefficients ${\displaystyle C_{3},C_{5}\;and\;C_{7}}$ and the pairs of polynomials ${\displaystyle \left(P_{2},P_{3}\right),\;\left(P_{4},P_{5}\right),\;\left(P_{6},P_{7}\right)}$ using the Recurrence formula[edit | edit source]

Statement[edit | edit source]

P. 29-3

Use the recurrence formula on P.29-2 to obtain the coefficients and expressions of the pairs of polynomials ${\displaystyle \left(P_{2},P_{3}\right),\;\left(P_{4},P_{5}\right),\;\left(P_{6},P_{7}\right)}$

Solution[edit | edit source]

We know the recurrence formulae:

${\displaystyle P_{2i}(t)=\sum _{j=0}^{i}C_{2j+1}\;{\frac {t^{2(i-j)}}{[2(i-j)]!}}}$

${\displaystyle P_{2i+1}(t)=\int P_{2i}(t)}$

${\displaystyle P_{2i+1}(t)=\sum _{j=0}^{i}C_{2j+1}\;{\frac {t^{2(i-j)+1}}{[2(i-j)+1]!}}+C_{2i+2}}$

Since all the ${\displaystyle \;P_{2i+1}(t)}$ polynomials are odd functions and are set to zero at +1 and -1, we have:

${\displaystyle P_{2i+1}(1)=\sum _{j=0}^{i}C_{2j+1}\;{\frac {1}{[2(i-j)+1]!}}=0}$

${\displaystyle \sum _{j=0}^{1}C_{2j+1}\;{\frac {1}{[2(1-j)+1]!}}=0\Rightarrow {\frac {C_{1}}{3!}}+{\frac {C_{3}}{1!}}=0\;\Rightarrow {\frac {C_{3}}{1!}}=-{\frac {C_{1}}{3!}}=-{\frac {(-1)}{3!}}={\frac {1}{6}}}$

similarly,

${\displaystyle \sum _{j=0}^{2}C_{2j+1}\;{\frac {1}{[2(2-j)+1]!}}=0\Rightarrow {\frac {C_{1}}{5!}}+{\frac {C_{3}}{3!}}+{\frac {C_{5}}{1!}}=0\;\Rightarrow {\frac {C_{5}}{1!}}=-{\frac {C_{1}}{5!}}-{\frac {C_{3}}{3!}}=-{\frac {(-1)}{5!}}-{\frac {\frac {1}{6}}{3!}}={\frac {-7}{360}}}$

${\displaystyle \sum _{j=0}^{3}C_{2j+1}\;{\frac {1}{[2(3-j)+1]!}}=0\Rightarrow {\frac {C_{1}}{7!}}+{\frac {C_{3}}{5!}}+{\frac {C_{5}}{3!}}+{\frac {C_{7}}{1!}}=0\;\Rightarrow {\frac {C_{7}}{1!}}=-{\frac {C_{1}}{7!}}-{\frac {C_{3}}{5!}}-{\frac {C_{5}}{3!}}=-{\frac {(-1)}{7!}}-{\frac {\frac {1}{6}}{5!}}-{\frac {\frac {-7}{360}}{3!}}={\frac {31}{15120}}}$

Now evaluating the polynomials using the coefficients:

${\displaystyle P_{2}(t)=\sum _{j=0}^{1}C_{2j+1}\;{\frac {t^{2(1-j)}}{[2(1-j)]!}}=C_{1}{\frac {t^{2}}{2!}}+C_{3}=-{\frac {t^{2}}{2}}+{\frac {1}{6}}}$

${\displaystyle P_{3}(t)=\sum _{j=0}^{1}C_{2j+1}\;{\frac {t^{[2(1-j)+1]}}{[2(1-j)+1]!}}=C_{1}{\frac {t^{3}}{3!}}+C_{3}{\frac {t^{1}}{1!}}=-{\frac {t^{3}}{6}}+{\frac {t}{6}}}$

Similarly,

${\displaystyle P_{4}(t)=\sum _{j=0}^{2}C_{2j+1}\;{\frac {t^{2(2-j)}}{[2(2-j)]!}}=C_{1}{\frac {t^{4}}{4!}}+C_{3}{\frac {t^{2}}{2!}}+C_{5}{\frac {t^{0}}{0!}}=-{\frac {t^{4}}{24}}+{\frac {t^{2}}{12}}-{\frac {7}{360}}}$

${\displaystyle P_{5}(t)=\sum _{j=0}^{2}C_{2j+1}\;{\frac {t^{[2(2-j)+1]}}{[2(2-j)+1]!}}=C_{1}{\frac {t^{5}}{5!}}+C_{3}{\frac {t^{3}}{3!}}+C_{5}{\frac {t^{1}}{1!}}=-{\frac {t^{5}}{120}}+{\frac {t^{3}}{36}}-{\frac {7t}{360}}}$

${\displaystyle P_{6}(t)=\sum _{j=0}^{3}C_{2j+1}\;{\frac {t^{2(3-j)}}{[2(3-j)]!}}=C_{1}{\frac {t^{6}}{6!}}+C_{3}{\frac {t^{4}}{4!}}+C_{5}{\frac {t^{2}}{2!}}+C_{7}=-{\frac {t^{6}}{720}}+{\frac {t^{4}}{144}}-{\frac {7t^{2}}{720}}+{\frac {31}{15120}}}$

${\displaystyle P_{7}(t)=\sum _{j=0}^{3}C_{2j+1}\;{\frac {t^{[2(3-j)+1]}}{[2(3-j)+1]!}}=C_{1}{\frac {t^{7}}{7!}}+C_{3}{\frac {t^{5}}{5!}}+C_{5}{\frac {t^{3}}{3!}}+C_{7}{\frac {t^{1}}{1!}}=-{\frac {t^{7}}{5040}}+{\frac {t^{5}}{720}}-{\frac {7t^{3}}{2160}}+{\frac {31t}{15120}}}$

Author[edit | edit source]

Srikanth Madala (SM)

Problem 9: Understanding the Matlab code on Kessler paper[edit | edit source]

Statement[edit | edit source]

To write a explanatory commentary on kessler's Matlab code for the evaluation of polynomials and their coefficients in the Trapezoidal error P. 30-2

Solution[edit | edit source]

Matlab code

function [c,p]= traperror(n)
%compute the coefficients p_2, p_4, ... , p_{2n} associated with the
%trapezoidal rule error expansion. Also compute c_1, c_3, ...

f=1; g=2; %defining variables 'f,g,cn and cd'
cn=-1; cd=1;

for k=1:n %beginning of 'for' loop with 'n' as the input value of 'traperror' function

f=f.*g.*(g+1); %reassigning the value of f by using element-wise multiplication of matrix f,g

[newcn,newcd]=fracsum(-1*cn,cd.*f); %calling the function 'fracsum' and passing the arguments n=-1*cn and d=cd.*f to the function fracsum(n,d).
%The function fracsum returns the values [nsum,dsum] which are stored in [newcn,newcd]

cn=[cn;newcn]; cd=[cd;newcd]; % the 'cn' (numerator of the coefficient)  and 'cd' (denominator of the coefficient) values are reassigned in
%the execution of the For loop. In each iteration of the for loop, the new values of 'cn' and 'cd' matrices are incremented by one additional
%column element 'newcn' and 'newcd' respectively

f=[f;1]; %the 'f' matrix is incremented by an additional column element=1, in each iteration of the for loop

g=[2+g(1);g]; % the 'g' matrix is incremented by an additional column element=even number, in each iteration of the for loop

[newpn,newpd]=fracsum((g-1).*cn,f.*cd);%calling the function 'fracsum' and passing the arguments n=(g-1).*cn and d=f.*cd to the function fracsum(n,d).
%The function fracsum returns the values [nsum,dsum] which are stored in [newpn,newpd]

pn(k,1)=newpn; % each numerator element of the polynomial function is stored in a column matrix with 'k' rows

pd(k,1)=newpd;  % each denominator element of the polynomial function is stored in a column matrix with 'k' rows

end % end of for loop to check and see if k=n?

c=int64([cn cd]); % converts the numerator and denominator of the coefficient to signed 64-bit integers

p=int64([pn pd]); % converts the numerator and denominator of the polynomial function to signed 64-bit integers

%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

function [nsum,dsum]= fracsum(n,d) %the arguments 'n' and 'd' are passed to this function and the output of this function are 'nsum' and 'dsum'

div=gcd(round(n),round(d)); %'round' is a matlab function to rounding off the fraction to the nearest integer and 'gcd' is a matlab function that
%returns the greatest common divisor of round(n) and round(d). This value of gcd is stored in a variable 'div'

n=round(n./div); % 'n' matrix is reassigned by carrying out element wise division with 'div' and then rounding off

d=round(d./div); % 'd' matrix is reassigned by carrying out element wise division with 'div' and then rounding off

dsum=1; % a new variable 'dsum' is initially assigned a value of 1

for k=1:length(d) % a new 'for' loop is started

dsum=lcm(dsum,d(k)); %'lcm' is a matlab function that returns the lowest common multiple of the values in the parentheses and in this case dsum and d(k)

end % end of for loop to check and see if k=length(d)?

nsum=dsum*sum(n./d); %'nsum' variable is defined by carrying out the arithemetic operation between 'dsum' and sum(n./d)

div=gcd(round(nsum),round(dsum)); %'div' is reassigned a different value which is the GCD of rounded values of 'nsum' and 'dsum'

nsum=nsum/div; %'nsum' is redefined

Author[edit | edit source]

Srikanth Madala (SM)

Problem 10: Calculating the Circumference of an ellipse[edit | edit source]

Statement[edit | edit source]

P. 30-4

An Ellipse as given:

${\displaystyle r(\theta )={\frac {a(1-e^{2})}{1-e\cos(\theta )}}}$

where:

${\displaystyle eccentricity=e=\sin({\frac {\pi }{12}})}$

${\displaystyle a=1}$

Calculate the Circumference of the elipse as follows:

Method 1:

${\displaystyle C=\int _{0}^{2\pi }\left[r^{2}+({\frac {dr}{d\theta }})^{2}\right]^{\frac {1}{2}}}$

Method 2:

${\displaystyle C=4aE(e^{2})}$

${\displaystyle E(e^{2})=\int _{0}^{\frac {\pi }{2}}\left[1-e^{2}\sin(\theta )\right]^{\frac {1}{2}}d\theta }$

Method 1[edit | edit source]

The Circumference will be calculated by using the following:

${\displaystyle C=\int _{0}^{2\pi }\left[r^{2}+({\frac {dr}{d\theta }})^{2}\right]^{\frac {1}{2}}}$

And then integrated numerically using 3 methods:

- Composite Trapezoidal
- Clencurt
- Romberg Table

The approximation for the exact integral was calculated using the "quad" Matlab command. It was approximated to be 6.176517851674653

Composite Trapezoidal[edit | edit source]

Matlab code for composite Trapezoidal calculation

%Calculates the Integral using the Composite Trapezoidal Rule
function [I,E]=circompos(a,b,n)

h=(b-a)/n;
pi2=2*pi();
i=0;
Itot=0;
It=0;
It2=0;
%Function elarc calculates the value of the function of the integral as seen in the code below
while i<=n
    if i==0
        Itot1=(1/2)*elarc(a);
    else if i<n
            u=h*i;
            It(i)= elarc(u);
        else
            It2=(1/2)*elarc(b);
        end
    end
Itot=Itot1+sum(It)+It2;
i=i+1;
end

I=Itot*(h);

%Error Calculation compared to built in 'quad' matlab command
Ir=quad(@elarc,0,pi2);
E=Ir-I;