A Bayesian belief network (Bbn) is used to model a domain containing uncertainty in some manner. Elsewhere, the shorter terms belief network and Bayesian network are used interchangeably. In the past, the term causal probabilistic networks has been used. A Bbn is a directed acyclic graph (dag) where each node represents a random variable. Each node contains the states of the random variable it represents and a conditional probability table (cpt) (or in more general terms a conditional probability function (cpf)). The cpt of a node contains probabilities of the node being in a specific state given the states of its parents. The following example demonstrates what all this means.
In this example, the domain is a small apple plantation belonging to Jack Fletcher (let's call him Apple Jack). One day Apple Jack discovers that his finest apple tree is losing its leaves. Now, he wants to know why this is happening. He knows that if the tree is dry (caused by a drought) there is no mystery - it is very common for trees to lose their leaves during a drought. On the other hand the loosing of leaves can be an indication of disease.
The situation can be modeled by the Bbn in figure 1. The Bbn consists of three nodes: Sick, Dry, and Loses which can all be in one of two states: Sick can be either "sick" or "not" - Dry can be either "dry" or "not" - and Loses can be either "yes" or "no". The node Sick tells us that the apple tree is sick by being in state "sick". Otherwise, it will be in state "not". The nodes Dry and Loses tell us in the same way if the tree is dry and if the tree is losing its leaves, respectively.
![]() |
Figure 1: Bbn representing the domain of the Apple Jack problem. |
The Bbn in figure 1 models that there is a causal dependency from Sick to Loses and from Dry to Loses. This is represented by the two arrows.
When there is a causal dependency from one node A to another node B, we expect that when A is in a certain state this has impact on the state of B. One should be careful when modeling the causal dependencies in a Bbn. Sometimes it is not quite obvious which direction an arrow should have. E.g. in our example we say that there is a causal arrow from Sick to Loses because when a tree is sick this might cause the tree to lose its leaves. But could we not say that when the tree loses its leaves, it might be sick and turn the arrow in the other direction? No, we cannot! It is the sickness that causes the lost leaves and not the lost leaves that cause the sickness.
In figure 1, we have the graphical representation of the Bbn. However, this is only what we call the qualitative representation of the Bbn. Before we can call it a Bbn, we need to specify the quantitative representation.
The quantitative representation of a Bbn is the set of cpts of the nodes. Table 1, 2, and 3 show the cpt of the three nodes in the Bbn of figure 1.
|
||||
Table 1: P(Sick). |
|
||||
Table 2: P(Dry). |
|
|||||||||||||||||||
Table 3: P(Loses | Sick, Dry). |
Note that all three tables show the probability of a node being in a specific state depending on the states of its parent nodes but since Sick and Dry do not have any parent nodes, tables 1 and 2 are not conditioned by anything.
What we have shown in this example is a description of how a very simple Bbn is constructed. HUGIN provides you with a tool to construct such networks. When you have constructed a network, you can use it for entering evidence in some of the nodes where the state is known and then retrieve the new probabilities calculated in other nodes corresponding to this evidence. In the apple tree example, suppose you know that the tree is losing its leaves. You enter this evidence by selecting the state "yes" in the Loses node. Then you can read the probability of the tree being sick as the probability of the node Sick being in state "sick" and the probability of the tree being dry as the probability of the node Dry being in state "dry".
If you are in the process of learning more about the HUGIN System, now would be a good time to go through the first tutorial in the introduction to HUGIN Runtime. Here, the apple tree Bbn is constructed using HUGIN Runtime. You can also go on reading the introduction to influence diagrams which are Bbns extended with utility nodes and decision nodes.