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Can someone help me with this equation? Reducing to linear form using logs?
T = 2π√(l/g)
Hi there. I need some math help.
I think I have it but I'm not sure I'm trying to study on my own and teach myself i worked it out but I'm not 100% and I hope someone out there can help me out so I can see what they do and how to approach these
Thanks a ton you'll save me from going into debt with tutors
@Puzzling @Alan
I really did work it out myself but I don't think I did it right because I was confused by some of it. You're both so helpful that explained it better than the videos I was trying to watch on it and anything I've seen online thank you, thank you, thank you!
Thank you all!!
5 Answers
- PuzzlingLv 71 week agoFavourite answer
If you've worked it out, I think you should have posted your work and then asked for someone to review it. Otherwise it looks like you just want someone else to do the work.
In any case, I'll do my best to help.
Original equation:
T = 2π√(l/g)
Take the log of both sides:
log(T) = log[2π√(l/g)]
Use the product rule to turn the log of a product in a sum of logs:
log(T) = log(2) + log(π) + log[√(l/g)]
Looking at the third log, we know that a square root can be rewritten as raising something to the ½ power:
log(T) = log(2) + log(π) + log[(l/g)^½]
Using the power rule, we can bring ½ to the front:
log(T) = log(2) + log(π) + ½ log(l/g)
Finally, use the quotient rule to split the last log into a subtraction of logs.
log(T) = log(2) + log(π) + ½[log(l) - log(g)]
- PinkgreenLv 71 week ago
T=(2pi)sqr(L/g)
=>
log(T)=[log(L)-log(g)]/2+log(2pi)
=>
log(T)=log(L)/2+log[2pi/sqr(g)]
This is a linear equation in "log",
where "log" are in the base of 10;
log(L) is the independent variable;
Log(T) is the dependent variable.
log[2pi/sqr(g)] is the constant term.
- la consoleLv 71 week ago
To complete:
Log[a](x) = Ln(x) / Ln(a) → where a is the base
Ln(x^a) = a.Ln(x)
Log(x^a) = a.Log(x)
Ln(ab) = Ln(a) + Ln(b)
Log(ab) = Log(a) + Log(b)
Ln(a/b) = Ln(a) - Ln(b)
Log(a/b) = Log(a) - Log(b)
Log(1) = 0
Ln(1) = 0
Ln(e) = 1 → e ≈ 2.71828182
T = 2π√(ℓ/g)
Ln(T) = Ln[2π√(ℓ/g)]
Ln(T) = Ln(2π) + Ln[√(ℓ/g)]
Ln(T) = Ln(2) + Ln(π) + Ln(√ℓ) - Ln(√g)
Ln(T) = Ln(2) + Ln(π) + Ln[ℓ^(1/2)] - Ln[g^(1/2)]
Ln(T) = Ln(2) + Ln(π) + (1/2).Ln(ℓ) - (1/2).Ln(g)
- L. E. GantLv 71 week ago
T = 2π√(l/g)
==> log(T) = log(2π(l/g)^(1/2))
==> log(T) = log(2π) + log((l/g)^(1/2))
==> log(T) = log(2π) + log(l^(1/2)) - log(g^(1/2))
==> log(T) = log(2π) + log(l)/2 - log(g)/2
2π is a constant
and I'd assume that g is a constant
so, rearranging...
==>log(T) = log(l)/2 + log(2π/g^(1/2))
- ?Lv 71 week ago
T = 2π√(l/g)
becomes
log(T) = log(2π) + (1/2)log(l) - (1/2) log(g)
if you consider g a constant , you're not
going to other planets or to really high altitudes
Then,
log(T) = (1/2)log(l) - log ( 2π/√g)
log slope = (1/2)
constant/intercept -log( 2π/√g)
