Description
1. (10 pts) In this problem we will check that
∞
e−x2
dx = √π. −∞
Let
� ∞ 2
I = e−x dx.
0
(i) Show that
π I2 ≥ 4
,
using the fact that the quartercircle
x2 + y2 ≤ a2 x ≥ 0 and y ≥ 0,
is a subset of the square [0, a] × [0, a].
(ii) Show that
π I2 ≤ 4
,
using the fact that the quartercircle
x2 + y2 ≤ 2a2 x ≥ 0 and y ≥ 0,
contains the square [0, a] × [0, a].
(Hint: in both cases, write down an inequality between the two integrals
and take the limit as a goes to ∞.)
2. (10 pts) (5.5.15)
3. (10 pts) (5.5.16)
4. (10 pts) (5.5.20)
5. (10 pts) (5.5.21)
6. (10 pts) (5.5.22)
7. (10 pts) (5.5.29)
8. (10 pts) (5.5.30)
9. (10 pts) (5.5.31)
10. (10 pts) (5.5.32)
Just for fun: Given a subset A of Rn, we say that a ∈ Rn is a strict
limit point if a is a limit point of A−{a} (or what comes to the same
thing, if there is a sequence a1, a2, . . . of distinct elements of A with
1
limit a). For what we are going to be interested in, we may assume
that n = 1.
By way of illustration, the set of strict limit points of
1 A = { n | n ∈ N } ∪ {0},
is {0}. Note that this is also the set of strict limit points of
1 A − {0} = { n | n ∈ N }.
Starting with any subset A ⊂ R, we are interested in how many times
we need to iterate the procedure of passing to the set of strict limit
points, until we get to the emptyset.
For example, starting with
1 A0 = { n | n ∈ N } ∪ {0},
if we replace A0 by its set of strict limit points, then we get
A1 = {0}.
The set of limit points of A1 is the emptyset,
A2 = ∅,
so that it takes two steps. Find examples of sets A ⊂ R such that
it takes n steps to get to the empty set. Find an example of a set
A which takes infinitely many steps. Now find another set A� which
takes more steps than A to get to the empty set. (It is probably not
so instructive to write down these examples, it is more interesting to
convince yourself that they exist; for this it is helpful to sketch points
the number line).
2
MIT OpenCourseWare
http://ocw.mit.edu
18.022 Calculus of Several Variables
