# Normalization - 1NF, 2NF and 3NF

i'm struggling with these normalization. I was asked to convert relational database tables into 1NF, 2NF and 3NF. Please help me! I've tried to Google around for answers and explanation and still don't really understand it. Here are the questions:

1. When is a relational database table said to be in first normal form. Study the Branch table below and convert it to 1NF.

2. Explain why the following table is not in Second Normal Form. Convert the table to 2NF.

3. The following relational table is not in Third Normal Form. Why is this so? Convert the table to 3NF.

I've read through Can someone please give an example of 1NF, 2NF and 3NF in plain english? but I still don't understand.

Can you please show the primary keys to these tables?

Here's what's i've got for Question 1 there. Don't know if this is right or not. Please do correct me.

Here is the answer the my question 2 above. Please guys, help me to correct this. This is what i've come up so far.

@Larry: can i do it this way though? is this alright?

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@Lorenzo: I assume figuring that out is part of the homework. –  casablanca Oct 25 '10 at 0:37
@casablanca: I am sorry but I did not understand what you mean. Could you please better explain? thanks :) –  Lorenzo Oct 25 '10 at 0:41
@Lorenzo: You had asked for the primary keys, and I was saying that finding out the primary keys is probably part of the homework. –  casablanca Oct 25 '10 at 0:45
@Casablanca: No this is not homework, it's just what i'm trying to prepare for up coming exams. I've came across this question and all of a sudden, i realized i had no idea how to answer this question. –  James1 Oct 25 '10 at 0:47

Normalization is all about eliminating redundant data: a quick glance at the tables will tell you that a lot of fields are repeated.

Take for example the second table: by mixing staff and branch details, we end up repeating a lot of stuff. Obviously a person always has a fixed name, and a branch has a fixed address, so put this information into a separate staff table and a separate branch table. Then the original table will have only pairs of staff no. and branch no., and any information unique to each pair, such as hours per week.

I hope you get the idea, and that you can answer the rest of the problem by yourself.

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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.

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thanks a lot for your explanations, but it's still kinda a puzzle to me though. Would you mind covert those tables into 1NF, 2NF and 3NF, maybe its easier for me to understand? Although, i think i've got question 1 answered there. the answer at the bottom there. –  James1 Oct 25 '10 at 1:19
I've read some websites about this and it says there are 3 golden rules to do this thing: 1NF: No repeating elements or groups of elements, 2NF: No partial dependencies on a concatenated key and 3NF: No dependencies on non-key attributes but i'm still not sure how to convert those tables. –  James1 Oct 25 '10 at 1:20
Yes I would mind showing you the answer. You need to do your own homework. I have, however, appended some further advice to my answer. It may be quite different to what you've read in your text books, but if you get your head around the concepts as I describe them, you'll come away with a much better understanding of what normalization theory is all about. –  Marcelo Cantos Oct 25 '10 at 1:33