barbernator
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I have seen quite a few different methods, what do u guys think is the easiest?
What is the easiest mathematical induction inequality prof method? (1 Viewer)
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if you look at 4d of http://www.boardofstudies.nsw.edu.au/hsc_exams/hsc2005exams/pdf_doc/maths_ext1_05.pdf
we have to prove:
for
now step 1 is easy so i'll skip it and go to step 2.
Step 2 Assume true for n=k
Step 3 To prove true for n = k + 1 (Now this is the step that gets hard and there are many ways to do it)
Prove:
 > 0)
Now what you should also do is use the assume n=k to prove this, so that means we will need the above inequality, however first i will rearrange it as follows:
So now we know this is true so we will need this somewhere. Now what you do is you take the LHS of the n=k+1 and try and manipulate it to prove the inequality as follows:
)
what i'll do now is change this as follows
)
i do this because we already know something about 
from above so now i sub in what knowledge i know as follows:
 - 1 - 7(k+1))
we must here change it to LHS> because remember 
so subbing this in makes the LHS greater than that.
Now we expand and simply this to:
and we know this is true for all
so we have now proved true for n=k+1, and step 4 well yeah you know how to do it.
Hope this helps
we have to prove:
for
now step 1 is easy so i'll skip it and go to step 2.
Step 2 Assume true for n=k
Step 3 To prove true for n = k + 1 (Now this is the step that gets hard and there are many ways to do it)
Prove:
Now what you should also do is use the assume n=k to prove this, so that means we will need the above inequality, however first i will rearrange it as follows:
So now we know this is true so we will need this somewhere. Now what you do is you take the LHS of the n=k+1 and try and manipulate it to prove the inequality as follows:
Now we expand and simply this to:
and we know this is true for all
Hope this helps
if you look at 4d of http://www.boardofstudies.nsw.edu.au/hsc_exams/hsc2005exams/pdf_doc/maths_ext1_05.pdf
we have to prove:
for
now step 1 is easy so i'll skip it and go to step 2.
Step 2 Assume true for n=k
Step 3 To prove true for n = k + 1 (Now this is the step that gets hard and there are many ways to do it)
Prove:
Now what you should also do is use the assume n=k to prove this, so that means we will need the above inequality, however first i will rearrange it as follows:
So now we know this is true so we will need this somewhere. Now what you do is you take the LHS of the n=k+1 and try and manipulate it to prove the inequality as follows:
Now we expand and simply this to:
and we know this is true for all
Hope this helps
assume
then you have to prove for n = k+1 that
so use the assumption
then you try and make everything look like what you are trying to prove
now you know
so
so for inequality inductions you should write down what you have to prove then usually you'll have a double inequality using the conditions for n/k which proves it
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D94
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Because it's "induction", you shouldn't be subbing in values as the proof. I think it should be done like this:
 \\= 4*4^{k} - 1 - 7k - 7 \\= 4*4^{k} - 1 - 28k + 14k - 7 \\= 4*4^{k} - 28k + 14k - 8 \\= 4*4^{k} - 4 - 28k + 14k - 4 \\= 4*(4^{k} - 1 - 7k) + 14k - 4 \\= 4*(>0\ from\ assumption) + (14k - 4)\ where\ (14k - 4) is\ > 0\ when\ k\geq 2 \\\therefore Step\ 4)
In the second last line, we can show by induction again that 14k - 4 is > 0, but within the domain, 14k - 4 is always > 0 from inspection.
In the second last line, we can show by induction again that 14k - 4 is > 0, but within the domain, 14k - 4 is always > 0 from inspection.