You must not think of types as sets of object properties in this case. We can avoid the confusion about how union and intersection types work by looking at scalar variables and their sets of permissible values (instead of objects):

```
type A = 1 | 2
type B = 2 | 3
type I = A & B
type U = A | B
let a: A
let b: B
let i: I
let u: U
a = 1
a = 2
a = 3 // <- error
b = 1 // <- error
b = 2
b = 3
i = 1 // <- error
i = 2
i = 3 // <- error
u = 1
u = 2
u = 3
```

Here the terms "union" and "intersection" correspond exactly to the set theory terms when applied to the sets of permissible values.

Applying the notion of permissible values (instances) to object types is a bit trickier (because the set theory analogy doesn't hold well):

```
type A = {
x: number
y: number
}
type B = {
y: number
z: number
}
type I = A & B
type U = A | B
```

- A variable of type
`A`

can hold object instances with properties `x`

and `y`

(and no other properties).
- A variable of type
`B`

can hold object instances with properties `y`

and `z`

(and no other properties).
- In set theory the intersection of the two sets of object intances above is empty. However, a variable of
**intersection type** `I`

can hold objects with the properties of type `A`

AND those of type `B`

(i.e. `x`

, `y`

, and `z`

; hence the `&`

symbol) which corresponds to the **union** of properties of the two types (hence the confusion).
- In set theory the union of the two sets of object intances above does not include objects with all three properties. However, a variable of
**union type** `U`

can hold objects with the properties of type `A`

OR those of type `B`

(logical OR, not XOR, i.e. `x`

and `y`

, `y`

and `z`

, or `x`

, `y`

, and `z`

; hence the `|`

symbol) which implies that the **intersection** of properties of the two types (`y`

in our example) is guaranteed to be present (hence the confusion).

```
let i: I
let u: U
i = { x: 1, y: 2 }; // <- error
i = { y: 2, z: 3 }; // <- error
i = { x: 1, y: 2, z: 3 };
u = { x: 1, y: 2 };
u = { y: 2, z: 3 };
u = { x: 1, y: 2, z: 3 };
```

`T | U`

is`members(T) | members(U)`

and similarly members of`T & U`

are members of both`T`

and`U`

so are in the intersection of`members(T)`

and`members(U)`

. – Lee Aug 9 '16 at 16:30`members(T)`

I meant the set of values of type`T`

, not the set of members defined by`T`

. – Lee Jan 13 at 20:30