# Difference between 3NF and BCNF in simple terms (must be able to explain to an 8-year old)

I have read the quote : data depends on the key [1NF], the whole key [2NF] and nothing but the key [3NF].

However, I am having trouble understanding 3.5NF or BCNF as it's called. Here is what I understand :

• BCNF is stricter than 3NF
• left side of any FD in the table must be a superkey (or atleast a candidate key)

So why is it then, that some 3NF tables are not in BCNF? I mean, the 3NF quote explicitly says "nothing but the key" meaning that all attributes depend solely on the primary key. The primary key is after all a candidate key until it is chosen to be our primary key.

If anything is amiss regarding my understand so far, please correct me and thanks for any help you can provide.

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Your pizza can have exactly three topping types:

• one type of cheese
• one type of meat
• one type of vegetable

So we order two pizzas and choose the following toppings:

``````Pizza    Topping    Topping Type
-------- ---------- -------------
1        mozarella  cheese
1        pepperoni  meat
1        olives     vegetable
2        mozarella  meat
2        sausage    cheese
2        peppers    vegetable
``````

Wait a second, mozarella can't be both a cheese and a meat! And sausage isn't a cheese!

We need to prevent these sorts of mistakes, to make mozarella always be cheese. We should use a separate table for this, so we write down that fact in only one place.

``````Pizza    Topping
-------- ----------
1        mozarella
1        pepperoni
1        olives
2        mozarella
2        sausage
2        peppers

Topping    Topping Type
---------- -------------
mozarella  cheese
pepperoni  meat
olives     vegetable
sausage    meat
peppers    vegetable
``````

Your question required that an 8-year-old could understand the explanation. :-)

BCNF acts differently from 3NF only when there are multiple overlapping candidate keys.

The reason is that the functional dependency `X -> Y` is of course true if `Y` is a subset of `X`. So in any table that has only one candidate key and is in 3NF, it is already in BCNF because there is no column (either key or non-key) that is functionally dependent on anything besides that key.

Because each pizza must have exactly one of each topping type, we know that (Pizza, Topping Type) is a candidate key. We also know intuitively that a given topping cannot belong to different types simultaneously. So (Pizza, Topping) must be unique and therefore is also a candidate key. So we have two overlapping candidate keys.

I showed an anomaly where we marked mozarella as the wrong topping type. We know this is wrong, but the rule that makes it wrong is a dependency `Topping -> Topping Type` which is not a valid dependency for BCNF for this table. It's a dependency on something other than a whole candidate key.

So to solve this, we take Topping Type out of the Pizzas table and make it a non-key attribute in a Toppings table.

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I might need to rephrase my question. I didn't ask why we use BCNF, but was asking for the specific property in a table that makes it break BCNF while still being 3NF. I'm not sure that this answer gives me the answer to my question. –  Arnab Datta Dec 9 '11 at 12:25

The subtle difference is that 3NF makes a distinction between key and non-key attributes (also called non-prime attributes) whereas BCNF does not.

This is best explained using Zaniolo's definition of 3NF, which is equivalent to Codd's:

A relation, R, is in 3NF iff for every nontrivial FD (X->A) satisfied by R at least ONE of the following conditions is true:

(a) X is a superkey for R, or

(b) A is a key attribute for R

BCNF requires (a) but doesn't treat (b) as a special case of its own. In other words BCNF requires that every nontrivial determinant is a superkey even its dependent attributes happen to be part of a key.

A relation, R, is in BCNF iff for every nontrivial FD (X->A) satisfied by R the following condition is true:

(a) X is a superkey for R

BCNF is therefore more strict.

The difference is so subtle that what many people informally describe as 3NF is actually BCNF. For example, you stated here that 3NF means "data depends on the key[s]... and nothing but the key[s]", but that is really an informal description of BCNF and not 3NF. 3NF could more accurately be described as "non-key data depends on the keys... and nothing but the keys".

You also stated:

the 3NF quote explicitly says "nothing but the key" meaning that all attributes depend solely on the primary key.

That's an oversimplification. 3NF and BCNF and all the Normal Forms are concerned with all candidate keys and/or superkeys, not just one "primary" key.

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Wow. Prof. Zaniolo actually teaches my class (CS 143, UCLA), and I stumbled upon this answer while preparing for the final exam. Great to see my prof's name, and thanks for the detailed answer! –  DV. Dec 10 '12 at 6:31
could you give an example of a relation which is in 3NF but not in BCNF? its hard for me to imagine... –  Kuba Polaczek Jun 9 at 18:42
R{A,B,C} where {A,B} is a key. Given the dependency C->B, R satisfies the requirements of 3NF but not BCNF. –  sqlvogel Jun 9 at 19:32
This is better than the accepted answear –  Ran Eldan Jul 18 at 13:17