1NF means that every attribute of every tuple in a relation has exactly one value. In fact, the very definition of a relation (aka *table* in SQL land) guarantees 1NF. The "table" in the first question has multiple phone numbers per row, so it isn't 1NF, which means it isn't a relation at all.

2NF means 1NF and (loosely) that every non-key attribute depends on the whole key. The table in question 2 has a composite key, {Staff No., Branch No.}, and the {Name} attribute only depends on part of this key, {Staff No.}.

3NF means 2NF and (loosely) that there are no transitive dependencies. A transitive dependency is where you have, say, three fields {K, A, B}, where K is the key field and both A and B depend on K (K → A and K → B), *but* B also depends on A (K → A → B). The table given has the following transitive dependency (among others) Staff No. → Branch No. → Branch Address.

Note: Be careful to understand a key difference between the second and third tables. In the second table, both Staff No. and Branch No. comprise the key (neither is unique by itself) In the third table, on the other hand, Staff No. forms a candidate key all by itself.

## A hint at the solution

Here's a super-compressed summary of the general process of normalizing data. Normalization usually involves decomposing a single large relation into multiple projections (i.e., SELECT DISTINCT a subset of the columns). The trick is to find projections that, when joined back together, are guaranteed to produce the original relation. This is known as non-loss decomposition.

As a simple case, the relation `T { K, A, B }`

can be decomposed into `T1 { K, A }`

and `T2 { A, B }`

, via:

```
SELECT DISTINCT K, A INTO T1 FROM T
SELECT DISTINCT A, B INTO T2 FROM T
```

...and joining T1 and T2 back together...

```
SELECT T1.K, T1.A, T2.B
FROM T1 JOIN T2 USING (A)
```

...will always return T. This is guaranteed because of the functional dependency chain K → A → B. The big advantage of the decomposed relations T1 and T2 (and the primary reason for normalization) is that if a particular value appears multiple times in T.A, then every tuple that contains that value will also have the same value in T.B. This is what A → B means, in essence. The normalised form, OTOH, only holds that particular A/B pair once in T2. In short, you eliminate redundancy.