Roots

This article page is a stub, please help by expanding it.

An $\scriptstyle n\,$ th complex root (root of degree $\scriptstyle n\,$ ) is one of the $\scriptstyle n\,$ complex solutions of

z^{n}=a,\quad n\in \mathbb {N} ^{+},\,a,\,z\in \mathbb {C} .\,

Real roots

An $\scriptstyle n\,$ th real root (root of degree $\scriptstyle n\,$ ) is one of the real solutions of

x^{n}=a,\quad n\in \mathbb {N} ^{+},\,a,\,x\in \mathbb {R} .\,

If $\scriptstyle n\,$ is an even positive integer, then the two real roots are

x=\pm {\sqrt[{n}]{a}},\,

while if $\scriptstyle n\,$ is an odd positive integer, then the single real root is

x={\sqrt[{n}]{a}},\,

where $n$ is the root index and a is the radicand.

Surds

A surd is an algebraic irrational root, e.g. $\scriptstyle {\sqrt[{3}]{2}}\,$ is a cubic surd. The quadratic surd $\scriptstyle {\sqrt[{2}]{27}}\,=\,3\,{\sqrt[{2}]{3}}\,$ is a mixed surd (i.e. a rational number multiplied by a surd).

Addition: 
S(S(⋯ "a times" ⋯ (S(n))))
, the sum 
n + a
, where 
n
is the augend and 
a
is the addend. (When addition is commutative both are simply called terms.)
Subtraction: 
P(P(⋯ "s times" ⋯ (P(n))))
, the difference 
n − s
, where 
n
is the minuend and 
s
is the subtrahend.

2^nd iteration

Multiplication: 
n + (n + (⋯ "k times" ⋯ (n + (n))))
, the product 
m ⋅ k
, where 
m
is the multiplicand and 
k
is the multiplier.^[3] (When multiplication is commutative both are simply called factors.)
Division: the ratio 
n / d
, where 
n
is the dividend and 
d
is the divisor.
- Quotient: (integer division).
- Remainder: (modulo and congruences).

3^rd iteration

Exponentiation ( 
d
as "degree", 
b
as "base", 
n
as "variable").
- Powers: 
  n ⋅ (n ⋅ (⋯ "d times" ⋯ (n ⋅ (n))))
  , written 
  n d
  .
- Exponentials: 
  b ⋅ (b ⋅ (⋯ "n times" ⋯ (b ⋅ (b))))
  , written 
  b n
  .
  - Exponential function: 
    e n
    , where 
    e
    is Euler's number.
Exponentiation inverses ( 
d
as "degree", 
b
as "base", 
n
as "variable").
- Roots: 
  d √ n
  .
- Logarithms: 
  logb n
  .
  - Natural logarithm function: 
    log n
    , or 
    loge n
    , where 
    e
    is Euler's number.

4^th iteration

Tetration ( 
d
as "degree", 
b
as "base", 
n
as "variable").
- Tetra-powers (super-powers): 
  n ^ (n ^ (⋯ "d times" ⋯ (n ^ (n))))
  , written 
  n ^^ d or n ↑↑ d
  .
- Tetra-exponentials (super-exponentials): 
  b ^ (b ^ (⋯ "n times" ⋯ (b ^ (b))))
  , written 
  b ^^ n or b ↑↑ n
  .
Tetration inverses ( 
d
as "degree", 
b
as "base", 
n
as "variable").
- Tetra-roots (super-roots)
- Tetra-logarithms (super-logarithms): 
  slogb n
  .
  - Iterated logarithm: 
    log ⁎b n = ⌈slogb n⌉
    .

5^th iteration

Pentation ( 
d
as "degree", 
b
as "base", 
n
as "variable").
- Penta-powers: 
  n ^^ (n ^^ (⋯ "d times" ⋯ (n ^^ (n ^^ (n)))))
  , written 
  n ^^^ d or n ↑↑↑ d
  .
- Penta-exponentials: 
  b ^^ (b ^^ (⋯ "n times" ⋯ (b ^^ (b ^^ (b)))))
  , written 
  b ^^^ n or b ↑↑↑ n
  .
Pentation inverses
- Penta-roots
- Penta-logarithms

6^th iteration

Hexation ( 
d
as "degree", 
b
as "base", 
n
as "variable").
- Hexa-powers: 
  n ^^^ (n ^^^ (⋯ "d times" ⋯ (n ^^^ (n))))
  , written 
  n ^^^^ d or n ↑↑↑↑ d
  .
- Hexa-exponentials: 
  b ^^^ (b ^^^ (⋯ "n times" ⋯ (b ^^^ (b))))
  , written 
  b ^^^^ n or b ↑↑↑↑ n
  .
Hexation inverses
- Hexa-roots
- Hexa-logarithms

7^th iteration

Heptation ( 
d
as "degree", 
b
as "base", 
n
as "variable").
- Hepta-powers: 
  n ^^^^ (n ^^^^ (⋯ "d times" ⋯ (n ^^^^ (n))))
  , written 
  n ^^^^^ d or n ↑↑↑↑↑ d
  .
- Hepta-exponentials: 
  b ^^^^ (b ^^^^ (⋯ "n times" ⋯ (b ^^^^ (b))))
  , written 
  b ^^^^^ n or b ↑↑↑↑↑ n
  .
Heptation inverses
- Hepta-roots
- Hepta-logarithms

8^th iteration

Octation ( 
d
as "degree", 
b
as "base", 
n
as "variable").
- Octa-powers: 
  n ^^^^^ (n ^^^^^ (⋯ "d times" ⋯ (n ^^^^^ (n))))
  , written 
  n ^^^^^^ d or n ↑↑↑↑↑↑ d
  .
- Octa-exponentials: 
  b ^^^^^ (b ^^^^^ (⋯ "n times" ⋯ (b ^^^^^ (b))))
  , written 
  b ^^^^^^ n or b ↑↑↑↑↑↑ n
  .
Octation inverses
- Octa-roots
- Octa-logarithms

Notes

↑ Hyperoperation—Wikipedia.org.
↑ Grzegorczyk hierarchy—Wikipedia.org.
↑ There is a lack of consensus on which comes first. Having the multiplier come second makes it consistent with the definitions for exponentiation and higher operations. This is also the convention used with transfinite ordinals: 
ω × 2 := ω + ω
.

Notes

[1] Hyperoperation—Wikipedia.org.

[2] Grzegorczyk hierarchy—Wikipedia.org.

[3] There is a lack of consensus on which comes first. Having the multiplier come second makes it consistent with the definitions for exponentiation and higher operations. This is also the convention used with transfinite ordinals: 
ω × 2 := ω + ω
.

[1]

[2]

[3]

Roots

Contents

Real roots

Surds

See also

Hierarchical list of operations pertaining to numbers ^[1] ^[2]

0^th iteration

1^st iteration

2^nd iteration

3^rd iteration

4^th iteration

5^th iteration

6^th iteration

7^th iteration

8^th iteration

Notes

Notes

Navigation menu

Views

Personal tools

Navigation

Search

Tools

Roots

Contents

Real roots

Surds

See also

Hierarchical list of operations pertaining to numbers [1] [2]

0th iteration

1st iteration

2nd iteration

3rd iteration

4th iteration

5th iteration

6th iteration

7th iteration

8th iteration

Notes

Notes

Navigation menu

Search

Hierarchical list of operations pertaining to numbers ^[1] ^[2]

0^th iteration

1^st iteration

2^nd iteration

3^rd iteration

4^th iteration

5^th iteration

6^th iteration

7^th iteration

8^th iteration