The process of thinking by prospective teachers of mathematics in making arguments

Journal of Education and Learning (EduLearn)
Vol. 13, No. 1, February 2019, pp. 17~24
ISSN: 2089-9823 DOI: 10.11591/edulearn.v13i1.6853  17
Journal homepage: http://journal.uad.ac.id/index.php/EduLearn
The process of thinking by prospective teachers of mathematics
in making arguments
Lia Budi Tristanti
Department of Education Mathematics, STKIP PGRI Jombang, Indonesia
Article Info ABSTRACT
Article history:
Received May 12, 2018
Revised Sep 24, 2018
Accepted Des 05, 2018
This study aimed to describe the process of thinking by prospective teachers
of mathematics in making arguments. It was a qualitative research involving
the mathematics students of STKIP PGRI Jombang as the subject of the
study. Test and task-based semi structural interview were conducted for data
collection. The result showed that 163 of 260 mathematics students argued
using inductive and deductive warrants. The process of thinking by the
prospective teachers of mathematics in making arguments had begun since
they constructed their very first idea by figuring out some objects to make a
conclusion. However, they also found a rebuttal from that conclusion, though
they did not further describe what such rebuttal was. Therefore, they decided
to construct the second ideas in order to verify the first ones through some
pieces of definition.
Keywords:
Argument
Deductive
Inductive
Thinking
Warrant Copyright © 2019 Institute of Advanced Engineering and Science.
All rights reserved.
Corresponding Author:
Lia Budi Tristanti,
Department of Education Mathematics,
STKIP PGRI Jombang,
Patimura Street III/20 Jombang, East Java, Indonesia.
Email: btlia@rocketmail.com
1. INTRODUCTION
Thinking is a mental activity that individuals experience while solving problems [1-6].
After interpreting the problem well, the next step to do by the problem-solver is selecting the best strategy as
solution. They (i.e., the problem solver) implement the selected stages to find the best solution
for their problems.
Solving problems started from constructing, clarifying, and evaluating ideas, respectively [7]. When
the problem-solvers solve a problem, they are trying to construct ideas as solutions for the problem by
thinking some alternatives of problem solving and figuring out those constructed ideas. Such ideas should be
explained by considering their similarities and differences, combining the similar ones, and separating the
distinctive ones. However, some of those ideas are inconsistent with the definition, theorem, and postulates,
and thus, they should be evaluated in order to make the best decision for solving the problem.
Education should provide chances for students to develop various skills and competences including
the competence of thinking, particularly the capability of having argument [8, 9]. In other word, education
should not only focus on the process of students’ thinking, but also their capability of making arguments. In
addition to learning the meaning of a concept, students should learn to choose among difference options and
explain the reason behind their choices.
Students make arguments to justify the solutions and actions they made in solving problems [10-16].
Argumentation, however, is a capability to connect particular data for a claim purpose [8]. It is an important
part of informal reasoning as the center of intellectual competences for solving problems, making judgment
and decision, as well as constructing ideas and assurance [12]. Furthermore, the competence of making
arguments is an essential component to improve the performance of problem-solving [17]. Following those
several perspectives, a problem-solver needs to have argumentations to decide, achieve, and bolster a

 ISSN: 2089-9823
J. Edu. & Learn. Vol. 13, No. 1, February 2019 : 17 – 24
18
reasonable solution for problem solving. Improving the competence of making arguments is necessary for
students to make them capable to describe some reasons of whether strengthening or refusing a perspective,
view, or idea. Having such competence, students may leave any hesitancy and vacillation behind, and thus,
solve the problem. They may also be free to choose and propose a reasonable solution.
The process of an individual making arguments should be analyzed using a more fruitful format so
that he/she might not solely distinguish the premises and conclusions [18]. Therefore Toulmin proposed a
layout of argument known as Toulmin’s Scheme. It consists of Data (D), claim (C), Warrant (W), Backing
(B), Rebuttal ( R), and Qualifier (Q). Data refers to some facts to support the claim proposed. Claim is a
proposition with supporting data. Data and Claim derive from a condition in which “if D, then C”. Warrant is
an assurance for data to support the claim. It has Backing as its supporter. Backing provides further legal-
based evidence as the basis of warrant. Rebuttal is an exceptional condition for arguments, and Qualifier may
reveal the strength level of the data proposed for the claim by warrant. Toulmin’s Scheme to analyze
arguments is presented in Figure 1.
Figure 1. Toulmin’s scheme for analyzing arguments
Warrant types include inductive, structural-intuitive, and deductive [19, 20] and so on. Inductive
warrant is a base derived from the process of evaluating one or more specific cases. Structural-intuitive
warrant is a base derived from the result of intuition (i.e., intuitive thinking) on the structure of an
individual’s internal representation. Deductive warrant is a base derived from the process of formal
mathematics justification in order to assure the general conclusion made. Again, deductive warrant is a
formal mathematics justification to assure a general conclusion [19]. The justification is through several
ways, such as axial cuts, algebraic manipulation, or the examples of denying. Deductive was a thought
derived from general things implemented and led to more specific ones [21]. Deductive was a process of
thinking derived from an existing proposition led to the new one in the form of conclusion [22]. With such
deductive thinking, individuals may start their departure from a theory, principle or conclusion they think it is
right and general in nature. at student-level, it is expected to use deductive warrant in the process of logically
explaining, justifying, and reasoning their arguments in order to ensure, strengthen, or refuse other
arguments, perspectives, or ideas. Therefore, this study focused on the process of thinking of prospective
teachers of mathematics in making arguments with deductive warrant initiated by inductive one.
The utilization of Toulmin’s Scheme for analyzing arguments in education of mathematics was seen
in [23] study which formulated the profile of students’ arguments to solve mathematical problems. That
profile is helpful for teachers to have better understanding on students’ approaches in solving problems. [24]
described the concept of evidence by prospective teachers to justify their arguments in class. Another study
using Toulmin’s Scheme was [25] that evaluated the position of rebuttal. It shows that the previous studies
tended to focus on individuals’ arguments in class discussion (i.e., argument in dialogue) rather than
argument not-in-dialogue. Thus, this present study would specifically discuss the second one; argument not-
in-dialogue. It is important as individuals try to reveal and ensure the right perspective using arguments led to
themselves. They try to ensure themselves. With this competence (i.e., argument not-in-dialogue), they may
get ready for any argument in-dialogue.
The students of mathematics education program were selected as the subject of this study, as they
would be the prospective teachers of mathematics and might contribute to the development of students’
thinking in mathematical argumentation. Students’ arguments depended on the construction of theorem habit
in class, the characteristics of tasks, and the kinds of particular reasoning by teachers [26]. Teachers’
encouragement for students to explain, note, and justify their arguments in a class discussion aimed to
improve students’ capability on argumentation [27]. The concept of evidence by the teachers of mathematics
in junior high schools may affect their teaching practices in assisting students to make arguments [24].

J. Edu. & Learn. ISSN: 2089-9823 
The process of thinking by prospective teachers of mathematics in making arguments (Lia Budi Tristanti)
19
Following the previous theory and studies on the process of thinking and mathematical
argumentation, this present study aimed to describe the process of students’ thinking in making arguments. It
would be analyzed using the framework of Toulmin’s Scheme, that each of the components within would be
further analyzed with Swatz’s theory.
2. RESEARCH METHOD
The sixth-semester students of mathematics education program in STKIP PGRI Jombang participated as
the subject of this study. They are the prospective teachers of mathematics for junior and high school levels. They
were selected as they had learned the concept of relation, indicating that they were capable to solve the given
problems. The selected students were those making arguments with deductive and inductive warrants.
First, the students were given a mathematical problem to be solved by optimally expressing their thought
during the process of problem solving (i.e, think aloud). Second, a task-based semi-structural interview was
conducted. In broadly speaking, this interview aimed to see what kind of thought the subject was thinking of while
inferring something and taking a step. The question might be in the form of “How do you think of this?” or
“what are you thinking of right now?” The questions also aimed to see their reason in taking some steps to solve
the given problem.
The data collection was through test and semi-cultural interview. Thus, the instrument of this study
was a task of mathematics and interview manual. The task was aimed to describe the subject’s arguments
based on the kinds of warrant, as seen in Figure 2. It was adapted from [20]. Some information along with
statements the subject needed to investigate was provided within the instrument. Furthermore, they were
asked to express their thought aloud during the process of completing the given task. Video recording was
conducted to see the subjects’ activities during the process of problem-solving.
Figure 2. Mathematical task
3. RESULTS AND ANALYSIS
260 undergraduate students of mathematics education program of STKIP PGRI Jombang participated in
this study. The kinds of warrant they used were presented in Table 1.
Table 1. Categorization of Students’ Warrant-Based Arguments
Kind of Warrant The Quantity of Student
Inductive 56
Structural-intuitive 15
Deductive 5
Structural inductive and deductive 21
Inductive and deductive 163
Table 1 showed that 62.69% of the prospective teachers of mathematics made their arguments using
inductive and deductive warrant. The following described the process of their thinking in making arguments
with inductive and deductive warrant.
3.1. Constructing the First Idea
The process of thinking by the subject in making arguments to investigate the truth of a given statement
had already started since they mentioned the information provided, including: “P is not chain”. That information
was data for making conclusion that “P is antichain”. The following showed the subject’s think aloud.
Dedefinition 1. Given that S is a partially ordered set of binary relation R on S, and A is the subset of S.
A is called chain if each of two distinctive elements; a , b; on A meets one of either a R b or
b R a.
Definition 2. S is a partially ordered set of binary relation R on S, and B is the subset of S. B is called
antichain, if each of two distinctive elements; a, b; on B meets bot a R b and b R a.
Investigate the truth of the statement “If P is not chain, then P is antichain”!

 ISSN: 2089-9823
20
Subject: “P is not chain, then P does not meet the condition in which ‘if each of two distinctive elements;
a , b; is on A, then P would be qualified’. However, P does not meet the condition either a R b or
b R a. may it be called antichain?”
The subject’s constructed idea to investigate the mathematical statement was by making the
examples of partially ordered set S and identifying those examples using the definition of chain and
antichain. They had such idea from the previous experience with identic task.
The process of explaining the idea by the subject started from providing the example of set S ={1, 2,
3, 4, 5, 6, 7} and binary relation R = {(a, b)| a is the factor of b, a, b  S}. Subsequently, they made and
identified the subset of S using the definition of chain and antichain, respectively. The identification aimed to
show that the example successfully met one of two possibilities: (i) if P is not chain, then P is antichain; or
(ii) if P is chain, then P is antichain. Thus, the subject’s argument used inductive warrant. Figure 3 presented
the subject’s written answer showing argument with inductive warrant.
Figure 3. The subject’s written result
Following [28] perspective, the process of thinking by the subject was on basic level, in which they
used their logical reasoning through multiplication, division, or addition. Following the way of the subject’s
experiment was classified into naïve empiricism, in which they asserted the truth of their result in making
conclusion after verifying some cases [29]. However, that argument was classified into informal argument as
the warrant was based on the concrete interpretation of mathematical concepts [30]. The concrete
representation by group 1 was making specific examples.
3.2. Evaluating the Fairness of the First Idea
At the stage of evaluating the fairness of their idea, the subject expressed the legal basis (i.e.,
backing) of their idea. They claimed that the backing was in the form of a subset not classified into chain, and
thus indeed classified into antichain, as well as the vice versa.
The subject concluded that if P was not chain, then P was antichain. The level of trust (i.e., qualifier)
for that conclusion was still probable, in which if P was most likely not chain, then P would be antichain. It
was because the subject still saw S as a set consisting of 7 members. Another possibility was that, for
instance, S was a set of complex and real numbers.
The conformity between qualifier and the kind of warrant in the subject’s argument was consistent
with [20] that inductive warrant aimed to alleviate the uncertainty of conclusion. The following presented the
subject’s statement on an interview.
Subject : I thought that there might be an exception as the conclusion remained likely true, Mam.
The subject’s exploration showed that there was likely a rebuttal on the conclusion. However, they
did not specifically describe what such rebuttal was.
Identifying the specific evidence 1
Qualifier Rebuttal

J. Edu. & Learn. ISSN: 2089-9823 
21
3.3. Constructing the Second Idea
The second idea constructed by the subject was to investigate the truth of formally mathematical
statement. The process of explaining this idea started since they negated the definition of chain. The negation
of the definition of chain was the definition of “non-chain”. The subject compared definitions between “non-
chain” and “antichain”. They realized that the definition of “non-chain” is not similar to the definition of
“antichain”. Hence, they argued that if P was not chain, it was still in the air that P was antichain. Therefore,
they made some examples of denying for the statement “if P was not chain, then P was antichain”. The
examples of denying by the subject was set A = {2, 3, 4} and himpunan B = {4, 9, 16} with binary relation R
= {(a, b)| a the factor of b, a, b  S}. Thus, the argument used deductive warrant. They concluded that the
statement “of P was not chain, then P was antichain” was wrong. Figure 4 presented the subject’s written
result showing the argument with deductive warrant.
Figure 4. The subject’s written result
That argument was classified into formal one as the warrant was based on the definition, axiom, and
theorem [30]. The subject used the formal argument to eliminate any hesitancy, and thus ensure the truth of
the statement.
3.4. Clarifying the Ideas
At this stage, the subject did not combine those constructed ideas to ensure the conclusion in case of
comparing the definition of non-chain and antichain as well as the counterexample. The reason not
combining those ideas was because they revealed different conclusions. Thus, the subject put aside those
which had different conclusions. Nevertheless, the ideas were used as the conclusion’s rebuttal. It was
consistent with [31] that inductive frame was constructed at the initial phase of deductive frame. In addition,
deductive frame might be useful to either support or rebut inductive warrant.
3.5. Evaluating the Fairness of the Ideas
The subject re-read their written result and adjusted each of their ideas with the given information.
Those ideas were justified based on the applied rule. The basic rule (i.e., backing) was in the form of
negation of both quantor and plural statements. The subject inferred that if P was not chain, then it was still
in the air that P was antichain. They defined that the statement was wrong as not all non-chain were
antichain. They found a rebuttal on their ideas, in which the conclusion would not be applicable if each of
the elements of A was not interrelated. The subject revealed the qualifier from their conclusion in the form of
certain. The conformity between the qualifier and the kinds of warrant in the argument did exist. It was
consistent with [20] that deductive warrant was used to alleviate any hesitancy and uncertainty on the
conclusion. The following showed the result of the subject’s think aloud. Table 2 interpreted the thinking
path of such argument, as follow.
The piece of the definition of chain
Making the definition on non-chain
Making the counter example 1
Making the counter example 2

 ISSN: 2089-9823
22
Subject : If P is not chain, then P is antichain, and thus, the inconformity disappears, oh wait,.. rather
than disappeared, it is used as a rebuttal in which each of the elements of P is not interrelated,
and thus, it would meet the statement ‘if P is not chain, then P is antichain. Thus, it is clear
that the statement ‘if P is not chain, then P is antichain is wrong.
Table 2. The Stage of Thinking and the Scheme of the Subject’s Argument
The Stage of
Thinking
The Scheme of Mathematical Argumentation Explanation
Constructing
the first idea
The subject defined the data (D) and claim (C) based on the
given information on task, and then identified some specific
cases to make a general conclusion. Therefore, they used
inductive warrant (Wi) to ensure the data for the claim.
Evaluating the
fairness of the
first idea
The subject revealed the backing (Bi) ensuring the truth of
the first idea. The qualifier (Qi) from the conclusion was
probable. They found an exceptional condition (rebuttal)
(Ri) in that conclusion. Nevertheless, they did not
specifically describe what such rebuttal was.
Constructing
the second idea
Constructing the second idea was aimed to strengthen the
conclusion of the first idea. It was to verify the conclusion
derived from a theory or principle that they considered true,
and thus, they used deductive warrant (Wd) on their
argument.
Clarifying the
first and the
second ideas
At this stage, the subject combined between inductive (Wi)
and deductive (Wd) warrants to ensure the data for the claim
(C). Those two warrants, however, might reveal different
conclusions, and thus, it made deductive warrant act against
the conclusion derived from inductive warrant.
Evaluating the
fairness of the
ideas
The subject revealed the backing (Bd) to ensure the truth of
deductive warrant (Wd). In addition to backing, the subject
also revealed a rebuttal (Rd), indicating that no exceptional
condition existed on the conclusion. The Qualifier (Qd) of
the conclusion derived from deductive warrant was certain.
Thus, the qualifier and conclusion derived from deductive
warrant may against the qualifier and conclusion derived
from inductive warrant.
4. CONCLUSION
The process of thinking by undergraduate students in making arguments started from the stage of
constructing the first idea, in which they expressed the components of arguments, including Data, Claim, and
Warrant. The idea was by taking some objects in order to make conclusion. At the stage of evaluating the
first idea, they showed the components of Qualifier, Backing, and Rebuttal. The level of trust (i.e., qualifier)
of the conclusion derived from inductive warrant was probable. Furthermore, they found an exceptional
condition (i.e., rebuttal) on the conclusion. However, they did not specifically describe what the rebuttal was.
At the stage of constructing the second idea, the students verified and formulated a conclusion using
D Ci
Wi
D Qi, Ci
Wi
Bi
Ri
D
Wd
Cd
D
Wi
Bi
Ri
Qi, Ci
Wd
Cd
Conclusion Qualifier
Rebuttal
D
Wi
Bi
Ri
Qi, Ci
Wd
Bd
Rd
Qd, Cd

J. Edu. & Learn. ISSN: 2089-9823 
23
deductive warrant. Their current argument with this second idea was derived from a theory, principle, and/or
conclusion they considered true or general in nature. The justification was from some axial cuts, algebraic
manipulation, and counterexample. At the stage of clarifying the ideas, the students connected inductive
warrant to deductive warrant. These two warrants were connected when they had similar conclusion.
Inductive warrant would be put aside when the conclusion revealed was different from deductive warrant. At
the stage of evaluating the fairness of the second idea, the students showed the components of Backing,
Qualifier, and Rebuttal. They eliminated any possible rebuttal as the qualifier of the conclusion was
certain. Thus, deductive warrant might improve the assurance of the conclusion revealed; from being
probable to certain. Overall, deductive warrant might either strengthen or weaken the conclusion derived
from inductive warrant.
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BIOGRAPHIES OF AUTHORS
Lia Budi Tristanti She graduated from elementary to junior high school in Jombang, namely MI
Raden Fattah Ngusikan Jombang (graduated in 2000), MTsN Bakalan Rayung Ngusikan
Jombang (graduated in 2003), SMKN 1 Jombang (graduated in 2006). Education Mathematics
S1 at STKIP PGRI Jombang (graduated in 2010) with degree S.Pd. The next education she took
at the State University of Surabaya with the ongoing BPPS scholarship from Dikti. In 2012, she
holds a Masters Degree in Mathematics Education. She continued her education in Mathematics
Doctoral Program at State University of Malang in 2013 with BPPDN scholarship from Dikti.
Career as a lecturer at STKIP PGRI Jombang from 2010 until now.

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