Mathematical Induction Inequality (1 Viewer)

Eazi · Jan 25, 2024

wait until you get to exercise 3

Average Boreduser · Jan 25, 2024

Eazi said:
wait until you get to exercise 3

im assuming u mean the trig one w x^2+1/x^2. Hint for anyone doing MI rn: you need to use strong induction (ie prove 2 cases) to prove by induction- and also recall triple angle formula

Average Boreduser · Jan 25, 2024

i remember some of the geometry ones (cancerous)

Eazi · Jan 25, 2024

Average Boreduser said:
im assuming u mean the trig one w x^2+1/x^2. Hint for anyone doing MI rn: you need to use strong induction (ie prove 2 cases) to prove by induction

I finished the whole book (assuming you're in a1) I just can't do the last ex3 lv3 question (independent one)

Average Boreduser · Jan 25, 2024

Eazi said:
I finished the whole book (assuming you're in a1) I just can't do the last ex3 lv3 question (independent one)

the one w T1=kjfhkj and the sequence?

Eazi · Jan 25, 2024

yeah like the one to show that Tn=(sqrroot2)^n+2 etc

Average Boreduser · Jan 25, 2024

Eazi said:
yeah like the one to show that Tn=(sqrroot2)^n+2 etc

its a strong induction. just brute force it. I think its supposed to be a trek

Average Boreduser · Jan 25, 2024

Eazi said:
yeah like the one to show that Tn=(sqrroot2)^n+2 etc

Here I'll quickly list out your steps:
1. Prove true for n=1
2. create ur assumption, to prove true for n=k+1
- use the identity you were provided in the qn i.e. tn= 2tn-1 ..... etc
take this as ur lhs of (2) and ur rhs as the original sqrtcospi/4 (k+1) wtv that you subbed as n=k+1. - To use this though, you need to prove again (ie strong induction) for another integer (i'll let u figure that out)
look at lhs of (2), use compound angle and you should get something with like sqrt(2)^smn [cos(kpi/4)-sinkpi/4]
then observe the rhs of (2), expand cmpnd angle, you get same as lhs.

liamkk112 · Jan 25, 2024

Eazi said:
I finished the whole book (assuming you're in a1) I just can't do the last ex3 lv3 question (independent one)

send the question if u want

Average Boreduser · Jan 25, 2024

liamkk112 said:
send the question if u want

liamkk112 · Jan 25, 2024

Average Boreduser said:
View attachment 42239

ill skip base cases as its pretty self explanatory

assumption:
$T_k = \sqrt{2}^{k+2} cos(\frac{k\pi}{4})$ and we are assuming for n = k, k>= 3 (we have already proved n = 1, n= 2 in the base cases so we will also assume these are true)

proving n = k + 1:
RTP $T_{k+1} = \sqrt{2}^{k+3} cos(\frac{(k+1)\pi}{4})$
LHS $= 2T_k - 2T_{k-1}$ (using the sequence definition)
$= 2 \sqrt{2}^{k+2} cos(\frac{k\pi}{4}) - 2\sqrt{2}^{k+1} cos(\frac{(k-1)\pi}{4})$
$= 2\sqrt{2}^{k+1} (\sqrt{2}cos(\frac{k\pi}{4}) - cos(\frac{(k-1)\pi}{4}))$
$= 2\sqrt{2}^{k+1} (\sqrt{2}cos(\frac{k\pi}{4}) - (cos({\frac{k\pi}{4}}) sin(\frac{\pi}{4}) + sin({\frac{k\pi}{4}}) cos(\frac{\pi}{4})))$ by the cos angle difference formula, where we are taking the difference of kpi/4 and -pi/4
$= 2\sqrt{2}^{k+1} (\frac{\sqrt{2}}{2}cos(\frac{k\pi}{4}) - \frac{\sqrt{2}}{2}sin(\frac{k\pi}{4}))$ because cos, sin evaluated at pi/4 = sqrt2 /2
$= 2\sqrt{2}^{k+1} (cos(\frac{(k+1)\pi}{4}))$ by cos angle sum of kpi/4 and pi/4
then because $2 = (\sqrt{2})^2$ we get that $T_{k+1} = \sqrt{2}^{k+3} cos(\frac{(k+1)\pi}{4})$ as required

hence by mathematical induction ...

Luukas.2 · Feb 11, 2024

Tryingtodowell said:
1. Using Mathematical induction, prove that n^2 + 1 > n for all integers n>1
For n=1
LHS= (2)^2+1= 5
RHS=2

Thus LHS>RHS, therefore true

Assume n=k,
k^2+1 >K

RTP; n=k+1
(k+1)^2 +1 > k+1

Now what do I do and how do I go about it

If you are still around, one approach with inequalities are to consider LHs > RHS in the form of LHS - RHS... So, in this case:

$\begin{align*} \text{Our induction hypothesis:} \qquad k^2 + 1 &> k \qquad \qquad \text{. . . . (*)} \\ \\ \text{We seek to prove:} \qquad (k + 1)^2 + 1 &> k + 1 \\ \\ \text{LHS} - \text{RHS} &= (k + 1)^2 + 1 - (k + 1) \\ &= \left(k^2 + 2k + 1\right) + 1 - k - 1 \\ &= k^2 + k + 1 \\ &= \left(k^2 + 1\right) + k \\ &> k + k \qquad \text{using (*)} \\ &= 2k \\ &> 0 \qquad \text{as $k$ is a positive integer} \\ \\ \text{Hence,} \qquad \text{LHS} &> \text{RHS} \qquad \text{as required} \end{align*}$

This can make it easier to see how to make use of the induction hypothesis, at times.

Mathematical Induction Inequality (1 Viewer)

Eazi

New Member

Average Boreduser

Rising Renewal

Average Boreduser

Rising Renewal

Eazi

New Member

Average Boreduser

Rising Renewal

Eazi

New Member

Average Boreduser

Rising Renewal

Average Boreduser

Rising Renewal

liamkk112

Well-Known Member

Average Boreduser

Rising Renewal

liamkk112

Well-Known Member

Luukas.2

Well-Known Member

Users Who Are Viewing This Thread (Users: 0, Guests: 1)