same doubt buddy

You are right, I saw that too, may be we can say the quantity becomes greater than 3 after a certain value of n.

@@CM63_France the actual difference is an increasing positive sequence that goes to infinity plus an increasing negative term that approaches 0. So, since the first difference is 1, all differences are greater than 1.

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I think, to be continuous it might follow for all sequences, if fails in any sequence if is not continuous. Maybe that's why this sequence was set.

n^2 = 4lm ... (1) m^2 = 4ln ... (2) l^2 = 4mn ... (3) Subtract 2 and 3 (m+l)(m-l) = 4n(l-m) m+l = -4n (m+l)/n = -4

@@sahilbaori9052 How did you arrive at the first step that is n^2=4lm?

@@utsav8981 they are perfect squares so b^2 = 4ac.

@@sahilbaori9052 Thnks for the solution though, but i still didn't understood b^2=4ac. Shouldn't the discriminant equal to a perfect square other than 0? So b^2-4ac=k^2

@@utsav8981 discriminant will be equal to k^2 when the solution is real and distinct. But in this case it is real and identical (perfect square) so it has to be 0.

> So, is there a connection between the derivative and uniform continuity? Yes. Let f: A -> R be differentiable on the interior of A, with f' bounded and A connected. Then f is uniformly continuous. Intuition: If f is not uniformly continuous there exists a rate of change (epsilon_0) such that no matter how near we force points to be, there's a pair of points x, y such that the rate of change between them is at least epsilon_0. The derivative is the rate of change. If it is bounded then f can only grow so fast, i.e. the x and y must be far enough apart for f to grow by the epsilon_0 amount. Proof: We want to show that for all epsilon > 0 there exists a delta such that when |y - x| < delta then |f(y) - f(x)| < epsilon. So let epsilon be given. Since f' is bounded there exists an M such that -M < f'(x) < M for all x. For every x and y with x < y we have [f(y) - f(x)] / (y - x) = f'(c) for some c, but f' is bounded. Thus -M < [f(y) - f(x)] / (y-x) < M for all x < y. But then -M*(y-x) < f(y) - f(x) < M*(y-x). "Let" M * (y-x) < epsilon, i.e. let delta = epsilon/M. If y - x < delta then M*(y-x) < M*delta = M*epsilon/M = epsilon. But then f(y) - f(x) < epsilon. Likewise -M*(y - x) < f(y) - f(x); negating both sides gives f(x) - f(y) < M*(y-x) < epsilon. Note that |f(x) - f(y)| is either f(y) - f(x) or f(x) - f(y), both of which are less than epsilon, so |f(y) - f(x)| < epsilon. But that's exactly what we wanted to show. Note that the x < y assumption is WLOG: if x = y then |f(x) - f(y)| = |f(x) - f(x)| = 0 < epsilon, and if y < x we can swap the names of x and y-they are used symmetrically. We need A to be connected for [x, y] to be contained in A for all x and y. We need interior differentiability for the proper f'(c) to exist with c in the [x, y] interval. See also math.stackexchange.com/questions/291166/prove-bounded-derivative-if-and-only-if-uniform-continuity and math.stackexchange.com/questions/118665/why-if-f-is-unbounded-then-f-isnt-uniformly-continuous. I guess this is a good place to stop this comment.