let xn be a sequence in R do lim sup xn and lim inf xn always...

Show that lim sup n→∞ (−xn) = −(lim inf n→∞ (xn).

Show that lim sup n→∞ (−xn) = −(lim inf n→∞ (xn).

Suppose that an is a sequence and lim sup an =a=lim inf an for some a...

Suppose that an is a sequence and lim sup an =a=lim inf an for some a in Real numbers. Prove that an converges to a

Prove that if (xn) is a sequence of real numbers, then lim sup|xn| = 0 as...

Prove that if (xn) is a sequence of real numbers, then lim sup|xn| = 0 as n approaches infinity. if and only if the limit of (xN) exists and xn approaches 0.

Let X = (xn) be a sequence in R^p which is convergent to x. Show that...

Let X = (xn) be a sequence in R^p which is convergent to x. Show that lim(||xn||) = ||x||. hint: use triange inequality

let A be a nonempty subset of R that is bounded below. Prove that inf A...

let A be a nonempty subset of R that is bounded below. Prove that inf A = -sup{-a: a in A}

Let f : [a,b] → R be a bounded function and let:             M = sup...

Let f : [a,b] → R be a bounded function and let:             M = sup f(x)             m = inf f(x)             M* =sup |f(x)|             m* =inf |f(x)| assuming you are taking values of x that lie in [a,b]. Is it true that M* - m* ≤ M - m ? If it is true, prove it. If it is false, find a counter example.

Prove that if E ⊂ R is bounded and sup E ∈ E or inf E...

Prove that if E ⊂ R is bounded and sup E ∈ E or inf E ∈ E, then E is not open. Analysis question (R refers to the real numbers).

Let 0 < θ < 1 and let (xn) be a sequence where |xn+1 − xn|...

Let 0 < θ < 1 and let (xn) be a sequence where |xn+1 − xn| ≤ θn  for n = 1, 2, . . .. a) Show that for any 1 ≤ n < m one has |xm − xn| ≤ (θn/ 1-θ )*(1 − θ m−n ). Conclude that (xn) is Cauchy b)If lim xn = x* , prove the following error in approximation (the "error in approximation" is the same as error estimation in Taylor Theorem) in t:...

For each of the following sets S, find sup(S) and inf(S) if they exist: (a) {x...

For each of the following sets S, find sup(S) and inf(S) if they exist: (a) {x ∈ R| x2 < 100} (b) {-3/n | n is a counting number} (c) {.9, .99, .999, .9999, .99999, …}

Let (xn) be Cauchy in (M, d) and a ∈ M. Show that the sequence d(xn,...

Let (xn) be Cauchy in (M, d) and a ∈ M. Show that the sequence d(xn, a) converges in R. (Note: It is not given that xn converges to a. Hint: Use Reverse triangle inequality.)