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Showing content from https://dlmf.nist.gov/4.2 below:

§4.2 Definitions ‣ Logarithm, Exponential, Powers ‣ Chapter 4 Elementary Functions

1. §4.2(i) The Logarithm
2. §4.2(ii) Logarithms to a General Base a
3. §4.2(iii) The Exponential Function
4. §4.2(iv) Powers

The general logarithm function Ln ⁡ z is defined by

where the integration path does not intersect the origin. This is a multivalued function of z with branch point at z = 0 .

The principal value, or principal branch, is defined by

where the path does not intersect ( − ∞ , 0 ] ; see Figure 4.2.1. ln ⁡ z is a single-valued analytic function on ℂ ∖ ( − ∞ , 0 ] and real-valued when z ranges over the positive real numbers.

The real and imaginary parts of ln ⁡ z are given by

For ph ⁡ z see §1.9(i).

The only zero of ln ⁡ z is at z = 1 .

Most texts extend the definition of the principal value to include the branch cut

by replacing (4.2.3) with

With this definition the general logarithm is given by

where k is the excess of the number of times the path in (4.2.1) crosses the negative real axis in the positive sense over the number of times in the negative sense.

In the DLMF we allow a further extension by regarding the cut as representing two sets of points, one set corresponding to the “upper side” and denoted by z = x + i ⁢ 0 , the other set corresponding to the “lower side” and denoted by z = x − i ⁢ 0 . Again see Figure 4.2.1. Then

with either upper signs or lower signs taken throughout. Consequently ln ⁡ z is two-valued on the cut, and discontinuous across the cut. We regard this as the closed definition of the principal value.

In contrast to (4.2.5) the closed definition is symmetric. As a consequence, it has the advantage of extending regions of validity of properties of principal values. For example, with the definition (4.2.5) the identity (4.8.7) is valid only when | ph ⁡ z | < π , but with the closed definition the identity (4.8.7) is valid when | ph ⁡ z | ≤ π . For another example see (4.2.37).

In the DLMF it is usually clear from the context which definition of principal value is being used. However, in the absence of any indication to the contrary it is assumed that the definition is the closed one. For other examples in this chapter see §§4.23, 4.24, 4.37, and 4.38.

With a , b ≠ 0 or 1 ,

Natural logarithms have as base the unique positive number

such that

Equivalently,

Thus

log e ⁡ x = ln ⁡ x is also called the Napierian or hyperbolic logarithm. log 10 ⁡ x is the common or Briggs logarithm.

The function exp is an entire function of z , with no real or complex zeros. It has period 2 ⁢ π ⁢ i :

Also,

The general value of the phase is given by

The general ath power of z is defined by

In particular, z0 = 1 , and if a = n = 1 , 2 , 3 , … , then

In all other cases, za is a multivalued function with branch point at z = 0 . The principal value is

This is an analytic function of z on ℂ ∖ ( − ∞ , 0 ] , and is two-valued and discontinuous on the cut shown in Figure 4.2.1, unless a ∈ ℤ .

where ph ⁡ z ∈ [ − π , π ] for the principal value of za , and is unrestricted in the general case. When a is real

Unless indicated otherwise, it is assumed throughout the DLMF that a power assumes its principal value. With this convention,

but the general value of ez is

If za has its general value, with a ≠ 0 , and if w ≠ 0 , then

This result is also valid when za has its principal value, provided that the branch of Ln ⁡ w satisfies

Another example of a principal value is provided by

Again, without the closed definition the ≥ and ≤ signs would have to be replaced by > and < , respectively.

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