Compiling Possibilistic Networks to Compute Learning Indicators

Guillaume Petiot

CERES, Catholic Institute of Toulouse, 31 rue de la Fonderie, 31068, Toulouse, France

Keywords:

Uncertain Gates, Compiling Possibilistic Networks, Possibility Theory, Education, Decision Making.

Abstract:

University teachers, who generally focus their interest on pedagogy and students, may ﬁnd it difﬁcult to

manage e-learning platforms which provide learning analytics and data. But learning indicators might help

teachers when the amount of information to process grows exponentially. The indicators can be computed by

the aggregation of data and by using teachers’ knowledge which is often imprecise and uncertain. Possibility

theory provides a solution to handle these drawbacks. Possibilistic networks allow us to represent the causal

link between the data but they require the deﬁnition of all the parameters of Conditional Possibility Tables.

Uncertain gates allow the automatic calculation of these Conditional Possibility Tables by using for example

the logical combination of information. The calculation time to propagate new evidence in possibilistic net-

works can be improved by compiling possibilistic networks. In this paper, we will present an experimentation

of compiling possibilistic networks to compute course indicators. Indeed, the LMS Moodle provides a large

scale of data about learners that can be merged to provide indicators to teachers in a decision making system.

Thus, teachers can propose differentiated instruction which, better corresponds to their student’s expectations

and their learning style.

1 INTRODUCTION

Modeling indicators based on expert knowledge are

hard to perform because human description is often

vague. Possibility theory, introduced by L. A. Zadeh

(Zadeh, 1978), is a solution to this problem of un-

certainty which appears during knowledge modeling.

Moreover, the causal link between the data can be

modeled by using the possibilistic network (Benfer-

hat et al., 1999). The latter is an adaptation of the

Bayesian Network (Pearl, 1988; Neapolitan, 1990) to

possibility theory. In the possibilisic network each

variable is attached to a Conditional Possibility Table.

The number of parameters to elicit in a CPT grows

exponentially depending proportionally on the num-

ber of parents. So a solution can be to use uncertain

logical gates between the variables in order to com-

pute automatically the CPT instead of eliciting all pa-

rameters. This time-saving solution allows us to ﬁx

the problem of unknown variables which are too dif-

ﬁcult to extract from complex systems. The addition

of a variable called leakage variable leads to a new

model. There is a large set of available connectors

from behavior severe to indulgent. The variables are

often qualitative as in (Dubois et al., 2015) but to use

uncertain gates we have to encode the modalities into

numerical values.

Another problem is the computation time of the

propagation of evidence in possibilistic networks.

There are several existing solutions with exact in-

ference or approximative inference. For example

forward-chaining, message passing in junction tree,

etc. But in our study we propose to experiment a new

approach which is more efﬁcient. Indeed, it is possi-

ble to perform the compiling of the possibilistic net-

work as for Bayesian networks (Park and Darwiche,

2002) to improve the computation time.

In this paper, we would like to perform an ex-

perimentation of indicator calculation by using uncer-

tain gates and compiling possibilistic networks. Sev-

eral studies were performed in order to improve peda-

gogy and understand students and their learning style

(Huebner, 2013; Baker and Yacef, 2009; Bousbia

et al., 2010). These researchers made use of Bayesian

networks, neural networks, support vector machines.

They often tried to detect a student at the risk of drop-

ping out or failing at the examination.

Our approach study is based on an existing dataset

built from Moodle logs for a course of spread-

sheet and some external information such as atten-

dance and results at the examination. This dataset is

anonymized. We can extract from Moodle the results

of the quiz, the sources consulted, etc. The knowl-

edge about the indicators is provided by teachers and

Petiot, G.

Compiling Possibilistic Networks to Compute Learning Indicators.

DOI: 10.5220/0010238001690176

In Proceedings of the 13th International Conference on Agents and Artiﬁcial Intelligence (ICAART 2021) - Volume 2, pages 169-176

ISBN: 978-989-758-484-8

169

extracted from the data by data mining as in (Petiot,

2018).

The goal of this paper, is to compute course in-

dicators by using teachers’ knowledge. To do this,

we will ﬁrst present possibility theory and uncertain

gates. Then we will focus on the compiling of pos-

sibilistic networks and ﬁnally we will present our re-

sults.

2 UNCERTAIN GATES

Uncertain gates are an analogy of noisy gates in pos-

sibility theory, developed in 1978 by L.A. Zadeh

(Zadeh, 1978). In this theory, imprecise and uncer-

tain knowledge can be modeled by a possibility dis-

tribution π. We can deﬁne the possibility measure Π

and the necessity measure N from P(Ω) in [0,1] as the

authors in (Dubois and Prade, 1988). The possibility

measure is deﬁned as follows:

∀A ∈ P(Ω), Π(A) = sup

x∈A

π(x)

(1)

The necessity measure can be deﬁned as follows:

∀A ∈ P(Ω), N(A) = 1 − Π(¬A) = in f

x/∈A

1 − π(x)

(2)

Possibility theory is not additive but maxitive:

∀A,B ∈ P(X), Π(A ∪ B) = max(Π(A),Π(B)).

(3)

We can compute the possibility of the variable A given

the variable B by using the conditioning proposed

by E. Hisdal (Hisdal, 1978) and generalized by D.

Dubois and H. Prade (Dubois and Prade, 1988):

Π(A|B) =



Π(A,B) if Π(A,B) < Π(B),

1 if Π(A,B) = Π(B).

(4)

Possibilistic networks (Benferhat et al., 1999; Borgelt

et al., 2000) can be deﬁned by using the factoring

property. We propose the following deﬁnition:

Deﬁnition 2.1. The factoring property can be deﬁned

from the joint possibility distribution Π(V ) for a Di-

rectional Acyclic Graph (DAG) G = (V, E) where V is

the set of Variables and E the set of edges between the

variables. Π(V ) can be factorized toward the graph G:

Π(V ) =

X∈V

Π(X/Pa(X)).

(5)

The function Pa(X) returns the parents of the variable

There are two kinds of possibilistic networks: min-

based possibilistic networks that are qualitative pos-

sibilistic networks where

is the function min, and

product-based possibilistic networks that are quanti-

tative possibilistic networks where

is the product.

In this research, we will use a min-based possibilistic

network because we have chosen to compare the pos-

sibilistic values instead of using an intensity scale in

[0,1].

Uncertain logical gates were proposed for the ﬁrst

time by the authors of (Dubois et al., 2015). They are

based on the Independence of Causal Inﬂuence and

use a model to represent uncertainty. This model is

built by introducing an intermediate variable Z

be-

tween a set of causal variables X

,...,X

and an effect

variable Y . This allows us to represent two behaviors:

inhibitors and substitute. The inhibitors can be de-

ﬁned if a cause is met and the effect variable Y is not

produced. The substitute can be deﬁned if a cause is

not met and the variable Y is produced. In this model,

there is a deterministic function f which combines the

inﬂuences of the variables Z

s: Y = f (Z

,...,Z

). The

leaky model is derived from the previous model by

adding a leakage variable Z

which represents the un-

known knowledge. The possibilistic model with the

ICI is the following:

Figure 1: Possibilistic model with ICI.

This model, presented by the authors (Dubois et al.,

2015), leads to the following equation:

π(y|x

,...,x

) = max

,...,z

:y= f (z

,...,z

)

i=1

π(z

) ⊗π(z

)

(6)

The ⊗ is the minimum and ⊕ is the maximum. There

are several possible functions f , for example AND,

OR, NOT, INV, XOR, MAX, MIN, MEAN, linear

combination, etc.

In order to generate the CPT we have to compute

the above equation. We have to deﬁne π(Z

), π(Z

and the function f . In our experimentation we have

three ordered levels of intensity: low, medium and

high. We propose to encode the modality by the fol-

lowing intensity levels as in (Dubois et al., 2015): 0

for low, 1 for medium and 2 for high. The following

table illustrates an example:

ICAART 2021 - 13th International Conference on Agents and Artiﬁcial Intelligence

170

Table 1: Possibility table for 3 ordered states.

π(Z

) x

= 2 x

= 1 x

= 0

= 2 1 s

2,1

2,0

= 1 κ

1,2

1 s

1,0

= 0 κ

0,2

0,1

In the above table, κ represents the possibility that an

inhibitor exists if the cause is met and s

the possibil-

ity that a substitute exists when the cause is not met.

If a cause of weak intensity cannot produce a strong

effect, then all s

= 0. So there are 6 parameters at the

most per variable and 2 parameters for π(Z

). Another

constraint is that κ

1,2

≥ κ

0,2

In our study we will use for the function f the

function MIN and MAX leading to the connectors

uncertain MIN (⊥) and uncertain MAX (>) as pro-

posed by Dubois et al. (Dubois et al., 2015). We will

also use a weighted average function (WAVG) and a

MYCIN Like connector (~) as described in (Petiot,

2018). The function f must have the same domain

as the variable Y . We can see that the connectors un-

certain MIN and uncertain MAX satisfy this property.

Nevertheless, the weighted average function can re-

turn a value outside the domain of Y . We propose to

combine the result of the weighted average function

g(z

,...,z

) = ω

+ ... + ω

with a scaling func-

tion f

which returns a value in the domain of Y . The

parameters ω

are the weights of the weighted aver-

age. Finally, we have f = f

◦ g. If (ε

,ε

,...,ε

m−1

)

are the m ordered states of Y then the function f

can

be for example:

(x) =











if x ≤ θ

if θ

< x ≤ θ

m−1

if θ

m−2

< x

(7)

The parameters θ

allow us to adjust the behaviour

of f

. The function g has n parameters which are the

weights w

of the linear combination and n arguments.

If all weights are equal to

, then we calculate the

average of the intensities. If ∀

i∈[1,n]

= 1, then we

make the sum of the intensities (connector

∑

3 COMPILING THE JUNCTION

TREE OF A POSSIBILISTIC

NETWORK

The knowledge of the indicators is represented by a

possibilistic network. The propagation of evidence in

this possibilistic network will lead to a possibility and

a certainty measure.

To perform the propagation of evidence in the pos-

sibilistic network we propose at ﬁrst to compile the

junction tree of a possibilistic network. The junc-

tion tree is composed of cliques and separators. The

cliques are extracted by using the Kruskal algorithm

(Kruskal, 1956) after the generation of the moral

graph and the triangulated graph (Kjaerulff, 1994).

The same reasoning as in compiling Bayesian net-

works (Darwiche, 2003) is used. We have adapted A.

Darwiche’s algorithm for the junction tree (Park and

Darwiche, 2002) of a Bayesian network to possibilis-

tic networks.

Indeed, possibilistic networks can be transformed

into a function with two kind of variables: evidence

indicators and network parameters. For all instantia-

tions of a variable X = x we deﬁne an evidence indi-

cator λ

. Similarly, for all network CPT parameters

of π(X |U ), we deﬁne a parameter θ

x|u

where u is an

instantiation of U , the parents of the variable X and x

an instantiation of the variable X.

The function f can be computed by combining at

ﬁrst all evidence indicators and network parameters

consistent with the instantiation by using the operator

⊗. Then, we perform a combination of all the previ-

ous results by using the operator ⊕.

Deﬁnition 3.1. If P is a possibilistic network, V = v

the instantiations of the variables of the possibilistic

networks and U = u the consistent instantiations of

the parents of a variable X with the instantiation X =

x, then the function f of P is:

f =

xu∼v

⊗ θ

x|u

(8)

In the above formula xu denotes the instantiation of

the family of X and its parents U compatible with the

instantiation v. The operator

can be the function

maximum and

the function minimum.

We can study, as an example, the following possibilis-

tic network:

Table 2: Example of the possibilistic network A → B → C.

A B

true true θ

b|a

true false θ

b|a

false true θ

b| ¯a

false false θ

b| ¯a

true θ

false θ

¯a

B C

true true θ

c|b

true false θ

¯c|b

false true θ

false false θ

¯c|

Compiling Possibilistic Networks to Compute Learning Indicators

171

In this case the function f is:

f = λ

⊗ λ

⊗ θ

b|a

⊗ θ

c|b

⊕λ

⊗ λ

¯c

⊗ θ

b|a

⊗ θ

¯c|b

...

⊕λ

¯a

⊗ λ

¯c

⊗ θ

¯a

⊗ θ

b| ¯a

⊗ θ

¯c|

(9)

Deﬁnition 3.2. If the evidence e is an instantiation of

variables then we have the property f (e) = π(e).

Let us consider the following example:

Table 3: Example of the possibilistic network A → B.

A B

true true 1

true false 0.2

false true 0.1

false false 1

true 1

false 0.1

If the evidence is ¯a, then we obtain λ

= 0, λ

¯a

= 1,

= 1, λ

= 1 and the computation of f (e) is: f ( ¯a) =

f (λ

= 0,λ

¯a

= 1,λ

= 1) = θ

¯a

⊗ θ

b| ¯a

⊕ θ

¯a

⊗

b| ¯a

= 0.1 ⊗ 0.1 ⊕ 0.1 ⊗ 1.0 = 0.1. The evaluation of

f leads us to compute π(e).

We can compute the possibility of a variable X

given the evidence e:

π(x|e) =

(

π(x,e) if π(x,e) < π(e),

1 if π(x,e) = π(e).

(10)

If the variable X has n states and x is one of its

states, and if X is not in the evidence e then π(x, e) =

f (e,1

) with 1

= (λ

= 0, ...,λ

= 1, ...,λ

= 0).

For example, 1

¯a

= (λ

= 0,λ

¯a

= 1). We have an-

other case if X is in e called Evidence Retraction in

probability theory (Darwiche, 2003). In possibility

theory the Evidence Retraction leads us to compute

π(x|e − X).

If the number of variables is too high, the com-

puting of possibilities becomes too complex. So it is

interesting to compile the possibilistic network by us-

ing a MIN-MAX circuit as in (Raouia et al., 2010).

This optimization allows us to reduce memory used

and computation time. There are several approaches

for compiling the function f into a MIN-MAX circuit.

The leaves of the MIN-MAX circuit are the parame-

ters λ and θ and the nodes are the operators ⊗ and ⊕.

We present an example of a MIN-MAX circuit in the

following ﬁgure:

Figure 2: MIN-MAX circuit of the example.

We have chosen to perform the factorisation of the

function f and then to use the junction tree method.

To compile a Bayesian network under evidence, we

generate an arithmetic circuit and we differentiate the

circuit in order to obtain all posterior probabilities

p(x|e). The differentiation is very easy with the arith-

metic circuit in probability theory.

Deﬁnition 3.3. We obtain the arithmetic circuit f

a MIN-MAX circuit f by replacing the ⊗ by the mul-

tiplications and the ⊕ by additions.

We propose to encode the MIN-MAX circuit into

an arithmetic circuit. Then we will deduce the propa-

gation algorithm for the arithmetic circuit. Finally, we

will replace in the algorithm the additions by ⊕ and

the multiplications by ⊗ in order to apply the algo-

rithm to a MIN-MAX circuit. In the following ﬁgure

we present an example of our encoding:

(a) MIN-MAX circuit.

(b) Arithmetic circuit.

Figure 3: Arithmetic circuit of a MIN-MAX circuit.

ICAART 2021 - 13th International Conference on Agents and Artiﬁcial Intelligence

172

We can differentiate the polynomial

∂ f

∂λ

. In the exam-

ple of Table 3, we obtain the following function:

f = λ

⊗ θ

⊗ (λ

⊗ θ

b|a

⊕ λ

⊗ θ

b|a

)

⊕λ

¯a

⊗ θ

¯a

⊗ (λ

⊗ θ

b| ¯a

⊕ λ

⊗ θ

b| ¯a

)

(11)

After the transformation we obtain the following

polynomial:

= λ

(λ

b|a

+ λ

b|a

) + λ

¯a

(λ

b| ¯a

+ λ

b| ¯a

) (12)

For example, if we suppose that e = b then f

(e) =

(λ

= 1;λ

= 0;λ

= 1;λ

¯a

= 1). To compute π(a,e)

we must at ﬁrst compute

∂ f

(e)

∂λ

because a is not in e.

We obtain the following result:

∂ f

(e)

∂λ

= θ

b|a

(13)

To obtain π(a,e) we must replace the additions by ⊕

and the multiplications by ⊗ in the above equation,

which gives the following result:

π(a,e) = θ

⊗ θ

b|a

(14)

We propose to build the MIN-MAX circuit of a junc-

tion tree obtained from a possibilistic network. We

must ﬁrst select a root node which is the result of f ,

then we add a ⊕ node for each instantiation of a sep-

arator and a ⊗ node for each instantiation of a cluster.

We have only one node λ

for each instantiation of a

variable X and one node θ

x|v

for each instantiation of

the nodes X and its parents V. The children of the out-

put node f are the ⊗ nodes of the root cluster. The

children of ⊕ nodes are compatible nodes generated

by the child clusters and the children of a ⊗ node are

compatible nodes generated by the child separators.

Each variable and λ are affected to only one cluster.

If we consider the example B ←− A −→ C we can

compute the MIN-MAX circuit of the junction tree as

follows:

Figure 4: MIN-MAX circuit of a junction tree.

In this ﬁgure, the function φ performs the evaluation

of the cluster compatible with the instantiation of the

separator.

We propose now to differentiate the arithmetic cir-

cuit f

of a MIN-MAX circuit f . If v is the current

node and p is the parents of v, then we can compute

∂ f

∂v

by using the chain rule:

∂ f

∂v

∑

∂ f

∂p

∂v

(15)

If the parent p has n other children v

different from

the node v, there are several cases to discuss:

• If v is the ﬁrst node then

∂ f

∂v

= 1.

• If p is an addition node then

∂p

∂v

∂(v+

∑

i=1

)

∂v

= 1

• If p is a multiplication node then

∂p

∂v

∂(v

∏

i=1

)

∂v

∏

i=1

As a result, we obtain the following recursive algo-

rithm to evaluate the MIN-MAX circuit of a junction

tree by changing the multiplication by ⊗ and addi-

tions by ⊕:

1. Upward-pass: compute the value of the node v

and store it in u(v);

2. If v is the root then set d(v) = 1 else set d(v) = 0;

3. Downward-pass: for each parent p of the node v

compute d(v) as follows:

(a) if p is a node ⊕:

d(v) = d(v)

d(p) (16)

(b) if p is a node ⊗:

d(v) = d(v)

d(p)

i=1

u(v

)

(17)

The nodes v

are the other children of p;

To evaluate the indicators, we must perform several

processing operations. The ﬁrst one is to compile the

junction tree of the possibilistic network. Then we

perform the initialization of evidence before apply-

ing the recursive algorithm. We can compute for each

state of an indicator a possibility measure and a ne-

cessity measure.

4 EXPERIMENTATION

4.1 Presentation

In our experimentation, we used an existing

anonymized dataset for a Spreadsheet course at bach-

elor level proposed in face-to-face learning enriched

by an online supplement on Moodle. This dataset was

built by gathering all data of logs in a table. Then a

process of anonymization was performed. For exam-

ple, we use the data of Moodle, such as quiz results,

Compiling Possibilistic Networks to Compute Learning Indicators

173

sources consulted, ... and external data such as atten-

dance, groups,... The quiz questions were categorized

by skills. When the data were missing, we performed

an imputation of these data by an iterative PCA (Au-

digier et al., 2015). The knowledge about the indica-

tors was provided by teachers and extracted from the

data by data mining. To represent the knowledge we

have chosen to use a DAG:

Figure 5: Modeling of knowledge by a DAG.

The qualitative variables have 3 ordered modalities

(low, medium, high) encoded with the numerical val-

ues (0,1,2). The description of the indicators by teach-

ers is often imprecise so we used a possibility distri-

bution to represent each state of a variable. Then, pos-

sibilistic networks can be used to compute the indica-

tors. To do this we need to deﬁne all CPTs. To avoid

the eliciting of all the parameters, we used uncertain

gates leading to the computation of all the CPTs.

We merged information about the sources con-

sulted in Moodle to build an indicator of participation

which takes into account their importance. We used

the WAVG connector. The weights were provided by

teachers. We also computed an indicator of acquired

skills by using the WAVG connector. The name of this

connector is connector

∑

. We present in the following

ﬁgure the weights of the WAVG connectors:

(a) Indicator of participation.

(b) Indicator of acquired skills.

Figure 6: Weights of the WAVG connectors.

We used the uncertain MIN connector (⊥) for con-

junctive behavior and the uncertain hybrid connector

(~) for indicators which need a compromise in case of

conﬂict and a reinforcement if the values are concor-

dant. As a result we obtain the following model:

Figure 7: Knowledge modeling with uncertain connectors.

Before the propagation of the new information, we

have to build the CPTs of all the uncertain gates.

Then, we apply the algorithm for compiling the junc-

ICAART 2021 - 13th International Conference on Agents and Artiﬁcial Intelligence

174

tion tree of a possibilistic network. We have com-

pared this approach to a previous study that used the

message passing algorithm (Petiot, 2018). Indeed, we

can adapt the junction tree message passing algorithm

(Lauritzen and Spiegelhalter, 1988) of Bayesian Net-

works to Possibilistic Networks. The propagation al-

gorithm can be resumed in three steps. The initializa-

tion with the injection of evidence, then, the collect

with the propagation of evidence from leaf to root and

the distribution with the propagation of evidence from

root to leaf.

4.2 Results

We have compared the compiling of possibilistic net-

work and the message passing algorithm. As ex-

pected, the results of the indicators in both approaches

are identical. For example, the indicator of success

deals with the prediction of student success at the

exam. We have computed the percentage of success

for each state of the indicator of success. We obtain

the following results by using the compiling of possi-

bilistic networks:

(a) Without the estimation of miss-

ing data.

(b) With the estimation of missing

data.

Figure 8: Indicator of success with and without the estima-

tion of missing data.

We can see in ﬁgure a) a lot of equipossible results

(with all possibilities equal to 1) due to missing data.

To reduce the equipossible variables, we have per-

formed an imputation of missing data using an it-

erative PCA algorithm (Audigier et al., 2015). We

present the results in ﬁgure b). Another advantage of

our approach is the use of uncertain gates in order to

avoid the eliciting of all parameters of the CPTs. We

have compared the result of the indicator of success

with and without uncertain gates by using the com-

piling of the possibilistic network. The results are the

following:

(a) Indicator of success.

(b) The number of parameters.

Figure 9: Comparison of the results with and without un-

certain gates by using the compiling of the possibilistic net-

work.

In ﬁgure a) the results are very close but uncertain

gates require fewer parameters than CPTs elicited by

a human expert. Figure b) shows that the number

of parameters is highly decreased by using uncertain

gates. We have also compared the performance of the

computation of the indicators by using the compiling

of possibilistic networks and the message passing al-

gorithm. The results are the following:

Figure 10: The mean computation time.

Compiling Possibilistic Networks to Compute Learning Indicators

175

We can see that the computation time is improved by

compiling the junction tree of the possibilistic net-

work. The compiling approach is three times faster

than the message passing algorithm.

5 CONCLUSION

In this paper, we have presented a new approach of ex-

act inference based on the compiling of the junction

tree of a possibilistic network. We applied this ap-

proach to computing learning indicators for a course

of spreadsheet that can be presented in a decision

making system for teachers. To do this we have rep-

resented teachers’ knowledge by using a possibilis-

tic network. As the number of parameters of the

CPT grows exponentially when the number of parents

grows, we have proposed to use uncertain gates be-

cause they allows us to avoid eliciting all CPT param-

eters. The CPTs are computed automatically. Then,

we have computed the junction tree and generated the

MIN-MAX circuit. To compute the possibilities of

the indicators we have applied our algorithm which

begins by an upward pass followed by a downward

pass. We have shown that the computation time is im-

proved compared to our previous inference approach

based on the message passing algorithm. The results

of our approach and message passing algorithm were

the same as expected. In future, we would like to per-

form further experimentations in order to better eval-

uate our junction tree compiling approach for possi-

bilistic networks. We would like to perform further

experimentation concerning the computation of learn-

ing indicators.

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