Englisia MAY 2014 
VOL. 1 NO.2, 232-244 

 
 

CORRELATIVE ASPECTS OF LANGUAGE 
SPECIFIC OPERATION AND ARITHMETIC 
PROCESSING IN BILINGUALS’ BRAIN; AN 
OVERVIEW OF BEHAVIOURAL AND 
NEUROLOGICAL STUDIES 
 
 
 
Erlyna Abidasari 
Universitas Muhammadiyah Malang 
 
 
ABSTRACT 

This study talks about what aspects correlated between the language specific 
operation and arithmetic processing skills that occur in bilingual people’s brains. 
Some studies toward the behaviour and neurology’s aspects are discussed as well as 
their findings in order to answer the research questions of the study. The discussions 
reveal that both skills have a positive correlation and that both occur in the brain’s 
left hemisphere; however, the left hemisphere largely participates in automatic 
language specific operations and simple calculations, while the right hemisphere 
dominates advanced control processing operations in calculation (e.g. calculus, 
logarithm) and language information transfer. In addition, studies show that the 
bilinguals’ language dominance does not clearly determine the correlation between 
the language and arithmetic skills. Further, in order to retain better arithmetic 
concepts, comprehensive and simultaneous training should be conducted in both 
languages and in the early stage of language development, especially during 
bilinguals’ critical age of language learning. 
 
Keywords: bilingual, language specific operation, arithmetic processing, language 

development, language dominance, left hemisphere, right hemisphere  
 
 

INTRODUCTION 

There has been a heated debate as to whether the development of language in-

fluences the calculation skill in bilingual cases, as been mentioned by Tamamaki 



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Englisia Vol. I No. 2, May 2014    |    233 

(1993) that bilinguals have difficulties to solve mathematical problems in their non-

dominant language. Baldo and Dronkers (2007, p. 229) suggest the existence of 

common syntax for both language and arithmetic in which the systems influence the 

way bilinguals perceive understanding. If the bilingual person has weak syntactic 

knowledge of a language, it is assumed that the arithmetic skill is also in deficit 

state. This “common syntax” determines how language and mathematical entities be 

coded in the mental structure of human brain. However, some argue that these two 

systems are distinct in a way that each has different process as can be proven in sev-

eral aphasia acalculia cases. Aphasia is an impairment of language due to injury or 

illness in the brain, whereas acalculia is an inability to perform arithmetic calculation 

and numbering processes. 

 In the first view, if both language and arithmetic share the common syntactic 

entities, which suggest the common overlapping area in the brain to be used for 

both development, one suffering from aphasia must also have a problem with count-

ing and vice versa (Baldo & Dronkers, 2007, p. 230). The other study conducted by 

Vitali et al. (2003), in contrast, showed significantly different results when several 

aphasic patients do not lose their ability in calculation. This proof strengthens the 

second view that recommends separate operational domains. In some other studies, 

however, types of aphasia determines kinds of acalculia which means they may 

share the same lobe to some extend but not always (Semenza, Dalazer, Bertella, & 

Grana, 2006, pp. 1-2). These findings arouse questions on the localisation of lan-

guage and arithmetic skills in human brain whether they share the same section or 

placed in two distinct specific areas.  

The common finding derived from fMRI, er-gMRI, MIT, TEP, and Intra-Parietal 

Sulcus neurological tests points that calculation operation and language develop-

ment exist mostly in the left hemisphere of the brain, especially in the case of early 

bilinguals, adding the complication to observe separability of the two entities. Thus, 

this paper tries to explore some knowledge of the bilinguals’ brain processing rele-

vant to language-arithmetic correlation.  

Context and Research Problems 

Firstly, the writer needs to specify what language intended to be observed in this 

particular case. It is not the whole or general language of human communication; 



CORRELATIVE ASPECTS OF LANGUAGE SPECIFIC OPERATION AND ARITHMETIC PROCESSING IN 

BILINGUALS’ BRAIN; AN OVERVIEW OF BEHAVIOURAL AND NEUROLOGICAL STUDIES 

234    |    Englisia Vol. I No. 2, May 2014  

rather, the focus is narrowed down to the language of mathematical operation or 

referred as the language specific operation. Cohen, Dehaene, Chockon, Lehericy, 

and Naccache (2000) mentions this specific language is used for problem solving in 

calculation, to interpret numerical and symbolic data into their verbal semantic func-

tions (words). The focused operation is in both exact and approximate arithmetic 

processes involving mental semantic ability to construct calculation based on ab-

stract concepts. The exact operations comprise simple addition, subtraction, and 

some simple functions of multiplication and divisions, as for approximate operations 

include advanced structural operation such as advanced triple digits multiplication, 

division, logarithm, square cubic, square root, and calculus.  

The bilingualism degrees in this observation vary from early simultaneous, con-

secutive bilinguals into late bilinguals, to compare the different effects of the lan-

guage acquisition and learning on their arithmetic skill retention. The introduction of 

Language Arithmetic (La+) should be noted here, referring to the language in which 

bilinguals learn their first numbering process compared to Language Non-Arithmetic 

(La-) where bilinguals do not have enough experience to learn number and calcula-

tion within this language. Therefore La+ may not be their first language or their 

dominant language.  

To observe the correlation between language specific and arithmetic skills, most 

researchers use more than one test; the preferable tests are to combine both behav-

ioural psychological assessments with neurological brain test. The comparison of the 

control group (healthy bilinguals) and aphasic/acalculic patients (impaired bilin-

guals) is to be made to explain the distribution and allocation of brain stimuli re-

garding its function on language specific and arithmetic entities. Hence, the 

observation should fulfil answers to these following research problems:  

1. To what extent does language specific operation correlate with the arith-

metic skill of bilinguals? 

2. In which preferable language and in what phase does the relation domi-

nantly occur? 



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Englisia Vol. I No. 2, May 2014    |    235 

3. What strategy do bilinguals apply to preserve better arithmetic operation 

retention? 

Literature Review and Discussion 

The correlation between the language specific operation and arithmetic skill devel-
opment 

The dramatic increase of children’s arithmetic skill soon after they acquire lan-

guage is one significant interest of the linguistic-arithmetic study. Baldo and 

Dronkers (2007, pp. 229-230) portray this phenomenon as a form of numerical 

range escalation experienced by the early bilingual children learning arithmetic op-

eration in their first language. In line with this finding, Cohen et al. (2000, p. 1426) 

explains two possible expansions of arithmetic skill development regarding the lan-

guage specific skill in: 1) the acquisition of number in its verbal format and 2) the 

acknowledgement of “non-verbal number “ such as the symbolic form of numbers 

(e.g. Arabic or Latin) alongside the development of language acquisition. These two 

processes support the basic manipulation of quantity operations in bilingual children 

minds.  

The verbal recognition of numbering and its operations are described in 

Dehaene, Spelke, Pinel, Stanescu, and Tsivkin (1999)s’ tests using “picture naming, 

word reading, and lexical decision” to examine which part of the brain corresponds 

to the process. The findings show that both left and right intra-parietal cortices of the 

brain surface are activated simultaneously and functionally meaning that both share 

spatial responses as well as controlled attention on the given tasks.  

On the other hand, the different performance of the brain activity is shown by 

another test conducted by Benn, Zheng, Wilkinson, Siegal, & Varley (2012) which 

separates arithmetic operations into categories of rote-learning and advanced learn-

ing.  Rote learning consists of simple addition and single digit subtraction opera-

tions, while the latter induces more semantically complex operations such as 

multiplication and division (Benn, Zheng, Wilkinson, Siegal, & Varley, 2012, pp. 2-

5). The test shows that there is an interference of “verbal shadowing” involved in the 

complex mathematical operation. Bilinguals need to perform additional mental im-

aging retention and language mediation in solving the advanced tasks. This process 



CORRELATIVE ASPECTS OF LANGUAGE SPECIFIC OPERATION AND ARITHMETIC PROCESSING IN 

BILINGUALS’ BRAIN; AN OVERVIEW OF BEHAVIOURAL AND NEUROLOGICAL STUDIES 

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is different from the rote learning type because there is no necessity in processing 

further input into semantic understanding; bilinguals only need a so-called “look-up” 

automaticity system in their mental dictionaries. The left hemisphere, especially in the 

Broca area, is proven to be more active in rote arithmetic operations, as for the ad-

vanced learning, the right hemisphere, as the expansion of the “superior parietal 

lobule”, takes a larger contribution. The test being used is a conventional versus ab-

stract shape manipulations conducted in three consecutive phases.  

In addition, Dehaene et al. (1999)’s observation on exact versus approximate 

calculation formats provides an outstanding view on the brain activation distinction. 

Bilinguals perform better whenever they are given exact problems rather than the 

approximate ones. In the exact operations, bilinguals tend to activate faster their 

trained skill in word sequences as the representation of language specific emphasis 

directly linked to automatic language specific association. In the contrary, when 

dealing with approximate problems, bilinguals store the advanced knowledge in the 

format of number magnitude making it harder for them to interpret, understand, and 

link the mathematical problem with its language representation. Dehaene’s test with 

fMRI and Event Related Potentials (ERPs) provide a clear picture of left hemispheric 

functioning during the exact problem solving; whereas the approximate case is rep-

resented by the minimum participation of the Left Hemisphere (LH) and the domi-

nance of the Right hemisphere (RH) parietal lobes.  

Language Dominance of Arithmetic Operation 

A neurological study by Baldo and Dronkers (2007) proposes the interdepend-

ence of language specific and arithmetic operation. Both are mediated by fragmen-

tal overlapping within the brain networks. This contention is also supported by Pica, 

Lemer, Izard, and Dehaene (2004, pp. 500-503) suggesting that some people com-

ing from non-numerical language cultures have difficulties in performing calculation. 

Moreover, Dahmen, Hartje, Bussing, and Sturm (1982, pp. 146-150) claim that the 

occurrence of verbal deficiency influences to some extent the arithmetic ability in 

such a way that both entities are likely to share the correlating general structure 

named as “common syntax”. The understanding of thematic role, as Baldo (2007) 



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Englisia Vol. I No. 2, May 2014    |    237 

mentions, concludes that the syntax of language specific and arithmetic operation is 

similar.  

However, surprisingly, another study brings quite an opposite argument to-

wards what kind of syntactic interdependence does affect the arithmetic ability. 

When the proposed interdependence exists, there should be an absolute condition 

where aphasic patient has to always be acalculic and vice versa. The study of several 

aphasic and/or acalculic patients then proves three possible conditions: 1) aphasic 

patient may be well performed in calculation; 2) acalculic patient might have no 

problem with language interpretation, and 3) associative deficits of both aphasia 

and acalculia which is in line with the first assertion of the shared syntactic role 

(Basso, Caporali, & Faglioni, 2005, pp. 99-103). Now, the question is in what con-

dition or requirement does the arithmetic operation be influenced by the language 

specific mode for bilinguals. 

Salillas and Wicha (2012) try to untie the above question by a thorough study 

on electrophysiological and behavioural response tests of Spanish-English for both 

healthy and aphasic bilinguals. A reaction-time experiment and the Brain Electrical 

Response test are conducted simultaneously for the participants learning arithmetic 

in one of their two languages. The Electro-encephalogram records are performed to 

check the electrical wave functioning as the participants undergo the behavioural 

tests. The findings point out positive relevance between language proficiency and 

arithmetic retrieval strategy for both groups. The “multiple mapping” of bilinguals to 

interpret the same concept for two different productions always occurs in any case.  

The other significant finding of this study is related to the language dominance 

matter. The language in which bilinguals first experience the arithmetic learning 

(La+) influence strongly to the ability to process and solve numerical operations, 

even in the case of aphasic/acalculic recovery (Salillas & Wicha, 2012, p. 745). 

La+ does not necessarily be their first language, instead it may be their second lan-

guage learned at school. The fast activation response of La+ brings an automatic 

answer needed in the reaction time test. In the case of La- (Language Non-

Arithmetic), participants perform a weaker and slower reaction due to an indication 

of translating the mathematical function into the La+ to be easily solved then trans-



CORRELATIVE ASPECTS OF LANGUAGE SPECIFIC OPERATION AND ARITHMETIC PROCESSING IN 

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ferring back to the La- to provide the expected answer (Dehaene et al., 1999). Defi-

nitely, the second process takes longer time. Thus, the arithmetic accuracy skill is not 

determined by language dominance nor language proficiency, instead the calcula-

tion skill is largely depends on arithmetic networks built during the first encounter 

with any language introducing the operands.  

The continuum of the bilinguals’ brain translation processes from La- to La+ 

back to La- occurs in frontal parietal regions for both hemispheres with the dominant 

process in the right hemisphere. The mental calculation is supposed to add some 

extra works for the right lobe since the increase activity is required to translate and 

transfer information twice as hard as the original version occurring only in La+. The 

more bilinguals train themselves to solve mental arithmetic problems in La-, it might 

bring more efficiency in using neural resources; thus, the status of La- is dynamic. A 

La- can be a La+ when bilinguals continuously operate in the non-arithmetic lan-

guage.   

Arithmetic Memory Networking for Bilinguals 

Salillas and Wicha (2012) and Basso et al. (2005) agree that the shaping of 

potentially strong arithmetic skill is first developed during the early stage of language 

specific learning. As mentioned earlier, the existence of La+ in the bilinguals’ brain 

is well maintained and preserved in the further production of both verbal and sym-

bolic arithmetic data as long as it is learnt and practiced persistently. As been assert-

ed by Warbuton, Price, Swiburn, and Wise (1999), the early arithmetic learning in 

the bilingual person acts as a glue towards mathematical operands, solution strate-

gies as well as a language particular so that the stored information can be accessed 

easier. More controlled process such as translation (from and/or to La-, La+) can be 

reduced to optimize intuitive self regulating problem solving.  

In the monolingual brain networking, there is only a one to one interpretation 

between an arithmetic concept and its verbal representation (Salillas & Wicha, 

2012, pp. 745-746). The case of bilingualism projects different networking designs 

since bilinguals undergo multiple mappings for one arithmetical concept, adding 

another cognitive component processing. For non-balanced bilinguals, more com-

plex process will occur when the calculation is presented in their weaker language. 



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Four operational arithmetic procedures, “identification of independent sub modules, 

recognition of quantity, operation of non-dedicated calculation, act of transla-

tion/interpretation” proposed by Semenza et al. (2006, p. 287) are the common 

calculation operations experienced by non-balanced bilinguals which may inhibit the 

information discovery. If one of these four is blocked, it is assumed that a bilingual 

will find it hard to seek the answer or even to understand the mathematical semantic 

content.  

Lin, Imada, and Kuhl (2012) as well as Ischebeck, Zamarian, Egger, Schocke, 

and Delazer (2007) through fMRI tests observe the brain activation of bilingual chil-

dren before and after receiving extensive training. The left hemispheric gyrus is likely 

to be more active and sensitive after eight repetitive tasks and the arithmetical codes 

remain stable over the experiment. The brain activation investigation indicates that 

repetition of several stimuli in the early bilinguals profoundly affects the preservation 

of arithmetic code in the bilinguals’ language specific operation format. Ischebeck, 

Zamarian, Egger, Schocke, and Delazer (2007), furthermore, suggest the balanced 

training of arithmetic repetitive problem solving in both languages to eliminate the 

activation of the fronto-parietal area which brings a controlled translation tool. In 

contrary, an extensive training for late bilinguals brings only little pattern changes in 

the fronto-parietal area of the brain which may not preserve memory for a long time.  

 

SOLUTIONS, RECOMMENDATIONS, AND CONCLUSION 

To answer the first question on the correlation of language specific operation 

with arithmetic skill of bilinguals, there are three points worth considering. Firstly, 

bilingual children develop their arithmetic skill drastically soon after they acquire 

language. The implication is that there must be a positive correlation between the 

two cognitive aspects.  

Secondly, behavioural and neurological tests prove that both language and 

number processing occur in the same brain region, which is in the LH. There is a 

factual overlapping activity in Broca area in most cases of arithmetic operation 

and/or within language specific modules. However, different patterns of brain acti-



CORRELATIVE ASPECTS OF LANGUAGE SPECIFIC OPERATION AND ARITHMETIC PROCESSING IN 

BILINGUALS’ BRAIN; AN OVERVIEW OF BEHAVIOURAL AND NEUROLOGICAL STUDIES 

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vation appeared by the occurrence of advanced arithmetic functions requiring more 

control of language specific to interpret and transfer semantic content of the func-

tion. In this case, the fronto-parietal RH region is highly activated for additional men-

tal imaging and translation. 

Furthermore, the LH largely participates in an automatic language specific op-

eration and in simple calculation; whereas the RH dominates advanced control pro-

cessing operations in calculation (e.g. calculus, logarithm) and language 

information transfer.  

The second research problem concerns the language preference and domi-

nance regarding the correlative aspects of numerical and verbal accesses. The Lan-

guage Arithmetic (La+) is the absolute requisition for the language and arithmetic 

function to correlate each other. It is difficult for bilinguals to solve arithmetic prob-

lem in the Language non-Arithmetic (La-) as they need to transfer/re-transfer infor-

mation for comprehension matter. The language dominance of bilinguals does not 

determine correlation between the two skills of language and arithmetic because the 

La+ can be acquired during the acquisition or learning of the later language.  

The case of movement of La- into La+ is always possible along the learning and 

extensive training for both early and late bilinguals. However, the pattern will be dif-

ferent; the former will activate the long term memory retention in the LH, while the 

later induces the activation of the frontal-lobe of RH which may not hold a long term 

memorisation.  

Finally, the researchers’ attempt to find effective strategies or treatment to pre-

serve arithmetic skill within the language specific operation comes to a deduction 

that teaching arithmetic skill in both languages starting from early development of 

language is seen to be a positive idea. Simultaneous training in both languages is 

expected to provide better atmosphere to create La+ so that bilinguals can perform 

automatically as well as develop auto-sensitivity towards symbolic and verbal calcu-

lations.  

Late bilinguals can also modify their brain activation by intensive regular train-

ing. However, if both early and late groups undergo the same process then being 



Erlyna Abidasari 

Englisia Vol. I No. 2, May 2014    |    241 

compared, the result of the training is likely to be different. The late bilinguals are 

apt to stimulate the frontal-parietal lobe of the RH compared to the early bilinguals 

training that triggers the LH performance. The positive point of the training for the 

late bilinguals is that the simultaneous conduct of arithmetic problem solving may 

increase their La- status into partial La+ and to prevent the lost of the arithmetic and 

language particular skills in their RH.  

 To conclude, overlapping brain activation in the LH does occur in the case 

of simple exact mathematical operation with its language specific interpretation. A 

complementary distribution (distinct RH shift) will present when it comes to advanced 

approximate calculation applying controlled transfer of information in the interpreta-

tion of more sophisticated mathematical problems. In addition, the La+ is the lan-

guage in which bilinguals encounter their first experience in learning numbering 

system, thus, they are likely to perform more efficient and automatic compared to 

the La-. In order to retain better arithmetic concepts, comprehensive and simultane-

ous training should be conducted in both languages and in the early stage of lan-

guage development; especially it is best regulated during bilinguals’ critical age of 

language learning. In the aphasia/acalculia recovery pattern for late bilinguals, re-

petitive training on mathematical problem solving will help them regain better 

memory of numerical functioning although the process is different from the early bi-

linguals. 

  



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