eolas/Mathematics/Prealgebra/Whole_numbers.md

---
tags:
  - Mathematics
  - Prealgebra
---

# The set of whole numbers

We recall the set of whole numbers:

$$ \mathbb{W} = {0, 1, 2, 3, ...} $$

# The properties of $\mathbb{W}$

 > 
 > In mathematics, a **property** is any characteristic that applies to a given set.

## The commutative property

### Addition

When **adding** whole numbers, the placement of the addends does not affect the sum.

Let **a**, **b** represent whole numbers, then:

$$ a + b = b + a $$

### Multiplication

When **multiplying** whole numbers the placement of the [multiplicands](https://www.notion.so/Symbols-and-formal-conventions-80aeaf1872f94a0d97a2e8d07e3855bd) does not affect the [product](https://www.notion.so/Symbols-and-formal-conventions-80aeaf1872f94a0d97a2e8d07e3855bd).

Let **a, b** represent whole numbers, then:

$$ a \cdot b = b \cdot a $$

### Subtraction

**Subtraction** is not commutative, viz:

$$ a - b \neq b - a $$

### Division

Division is not commutative, viz:

$$ a \div b \neq b \div a $$

## The associative property

### Addition

When grouping symbols (parentheses, brackets, braces) are used with addition, the particular placement of the grouping symbols relative to each of the addends does not change the sum.

Let **a**, **b, c** represent whole numbers, then:

$$ (a + b) + c = a + (b + c) $$

### Multiplication

Let **a, b, c** represent whole numbers, then:

$$ a \cdot (b \cdot c) = (a \cdot b) \cdot c $$

### Subtraction

Subtraction is not associative, viz:

$$ (a - b) - c \neq a - (b - c) $$

### Division

Division is not associative

$$ (a \div b) \div c \neq a \div (b \div c) $$

## The property of additive identity

If **a** is any whole number, then:

$$ a + 0 = a $$

We therefore call zero the additive identity: whenever we add zero to a whole number, the sum is equal to the whole number itself.

## The property of multiplicative identity

If **a** is any whole number, then:

$$ (a \cdot 1 = a) = (1 \cdot a = a) $$

## Multiplication by zero

If **a** is any whole number, then:

$$ (a \cdot 0 = 0) = (0 \cdot a = 0) $$

## Division by zero

Division by zero is **undefined** but zero divided is zero.
Initial commit, pure MD 2022-04-23 13:26:53 +01:00			`---`
			`tags:`
			`- Mathematics`
			`- Prealgebra`
			`---`

			`# The set of whole numbers`

			`We recall the set of whole numbers:`

			`$$ \mathbb{W} = {0, 1, 2, 3, ...} $$`

			`# The properties of $\mathbb{W}$`

			`>`
			`> In mathematics, a property is any characteristic that applies to a given set.`

			`## The commutative property`

			`### Addition`

			`When adding whole numbers, the placement of the addends does not affect the sum.`

			`Let a, b represent whole numbers, then:`

			`$$ a + b = b + a $$`

			`### Multiplication`

			`When multiplying whole numbers the placement of the [multiplicands](https://www.notion.so/Symbols-and-formal-conventions-80aeaf1872f94a0d97a2e8d07e3855bd) does not affect the [product](https://www.notion.so/Symbols-and-formal-conventions-80aeaf1872f94a0d97a2e8d07e3855bd).`

			`Let a, b represent whole numbers, then:`

			`$$ a \cdot b = b \cdot a $$`

			`### Subtraction`

			`Subtraction is not commutative, viz:`

			`$$ a - b \neq b - a $$`

			`### Division`

			`Division is not commutative, viz:`

			`$$ a \div b \neq b \div a $$`

			`## The associative property`

			`### Addition`

			`When grouping symbols (parentheses, brackets, braces) are used with addition, the particular placement of the grouping symbols relative to each of the addends does not change the sum.`

			`Let a, b, c represent whole numbers, then:`

			`$$ (a + b) + c = a + (b + c) $$`

			`### Multiplication`

			`Let a, b, c represent whole numbers, then:`

			`$$ a \cdot (b \cdot c) = (a \cdot b) \cdot c $$`

			`### Subtraction`

			`Subtraction is not associative, viz:`

			`$$ (a - b) - c \neq a - (b - c) $$`

			`### Division`

			`Division is not associative`

			`$$ (a \div b) \div c \neq a \div (b \div c) $$`

			`## The property of additive identity`

			`If a is any whole number, then:`

			`$$ a + 0 = a $$`

			`We therefore call zero the additive identity: whenever we add zero to a whole number, the sum is equal to the whole number itself.`

			`## The property of multiplicative identity`

			`If a is any whole number, then:`

			`$$ (a \cdot 1 = a) = (1 \cdot a = a) $$`

			`## Multiplication by zero`

			`If a is any whole number, then:`

			`$$ (a \cdot 0 = 0) = (0 \cdot a = 0) $$`

			`## Division by zero`

			`Division by zero is undefined but zero divided is zero.`