§ 3.9. Other Remarkable Limits

Consider the following limits of functions often encountered in applications:

(1) , (7)

(2) for a=e, . (8)

(3) . (9)

Proof.

1. .

2. Define a^x–1=t as x0, t0, a^x=t+1 . Take the logarithm of both terms by definition of a: x=log_a(1+t), substitute in (8), and, according to (7), obtain:

.

3. Define the numerator (1+x)^–1=t, (1+x)^=1+t as x0 t0. Take the logarithm of both terms by definition of e: , multiply the numerator and the denominator of limit (9) by the obtained expression

.

Remark. Here the author uses the words of his ex-student: “The limit is like water which penetrates everywhere”, i.e., the limit penetrates into a sum, a product, a quotient of limits, an argument of functions, in powers, under the radical sign and logarithm, etc..

§ 3.10. Continuity of Functions

Define f(x) in a neighborhood of х₀ .

Definition 1. If the left and the right limits coincide and equal the value of a function at point х₀, then the function f(x) is said to be discontinuous at point х₀

. (10)

y

f (x₀)

0 x₀ x

We attach the increment х to an argument x. Then the function must also obtain the increment у:

у=f(x0+x)–f(x0).

у f(x0+x) f(x0) 0 x0 x0+x x

Definition 2. If the small increment of an argument corresponds to the small increment of x, then this function is said to be continuous at this point

. (11)

.

These two definitions are equivalent, i.e., it is possible to obtain the second definition from the first and vice versa. (Prove this on your own).

Definition. The function is said to be continuous on a domain if it is continuous at each point of this domain.

All elementary functions are continuous. Elementary functions are denoted by .

Example 1. Prove that f(x)=cosx is a continuous function on the whole x-axis.

Use the second definition of the function continuity (11). We find the limit of function increment

y=f(x+x)–f(x), f(x+x)=cos(x+x),

i.e., the condition of the second definition of continuity is satisfied.

Example 2. Prove that y=tanx is continuous on the interval . Use the second definition of continuity:

,

==

== ==0.

Consequently, the function is continuous.

3.10.1. The classification of the points discontinuities. The discontinuities can appear only if the conditions of continuity, the condition (10) are broken, i.e., , х₀ is the point, where (10) is not satisfied.

Definition. A simple discontinuity is such a point, at which there are one-sided limits and , but they are not equal:

.

y B A 0 x0 x

, , , (B–A) – is a jump.

Example 3. у

y=x² y=x+1

is a simple

discontinuity

0 1 х

Find the left limit of a point х=1:

.

Find the right limit:

.

The limits do not coincide; thus, we have the simple discontinuity at the point х=1.

Definition. A point х=х₀ is called a removable continuity if the left and right limits exist and equal, but the function is not determined at this point.

f(x₀–0)=f(x₀+0), f(x₀)-?

Remark. Such a point can be removable if we take the value of limit for f(x₀).

Example 4. Find the discontinuity of

. The value of the function does not exist, because the denominator equals zero as х=5, but the limit exists:

10,

The point х₀=5 is a removable discontinuity; we supplement the function with f(5)=10.

Definition. The discontinuity of the second kind is a point, where at least one of the one-sided limits either does not exist or equals the infinity.

у

0 х₀ х

Example 5. Test the following function for the discontinuity:

. у

Find the left limit

.

0 х

Respectively, the right limit is

.

Both limits do not exist; the function has the discontinuity of the second kind at the point х=2.

Example 6. Consider for the discontinuity at the points х₁=3, х₂=0.

We find the value of a function at the point х₀=0 ; =; thus, the function is continuous at the point х=0. At the point х₀=3, , we find

,

.

у

1

х=3 is a discontinuity

of the second kind. 0 3 х

3.10.2. Theorems on continuous functions. The first Cauchy-Bolzano theorem. If f(x) is defined and continuous on the interval [a;b] with different signs at the ends of this interval, then there is at least one point х=с, where f(c)=0. (Without proof).

This theoremcan be represented graphically as is:

у

а

0 с₁ с₂ с₃ b х

The second Cauchy-Bolzano theorem. If f(x) is defined and continuous on the interval [a;b] with different values at the ends, then any value of a number М has the point х= с between these values; thus, f(c)=M is satisfied. (Without proof).

f(a)=A; f(b)=B, AB.

у

A<M<B. B

M

A

0 a c b х

The Weierstrass theorem. If a function is defined and continuous on the interval [a;b], then it is limited from above and below on this interval, i.e., mf(x)M.

y

M

m

0 a b x

3.10.3. The comparison of infinitesimals. Suppose that there are the following infinitesimals (х) and (х), i.e.,

, .

Definition. If there is the ratio limit between these infinitesimals equal to zero

then the infinitesimal (х) is said to be of a higher order than (х).

Notation:  =0().

Definition. Two infinitesimals (х) and (х) are infinitesimals of the same order if their ratio limit equals a constant number

Definition. If the ratio limit of infinitesimals equals 1 then the infinitesimals (x) and (x) are said to be equivalent.

Notation: (х)  (х).

Definition. If limit does not exist, then these two infinitesimals are said to be nonmesuarable.

Theorem. To equal two infinitesimals (x) and (x), it is necessary and sufficient that

exists.

Examples.

(1). ,. The sine of a small-angle is equivalent to the

angle itself.

(2). , .

(3).,.

(4).

.

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